A huge transparent wall permanently separates two civilisations - what can it be made of?
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I'd like two medieval societies to be separated from one another by a huge vertical wall.
The wall is so high that no-one has succeeded in shooting an arrow (or anything else) over it. It disappears up into perpetual mist. This wall bridges a pass in the middle of a mountain range that no-one has managed to scale because of the continual blizzards that rage and indeed the traditional stories about fearsome beasts that live there.
This wall is solid. There is no magic involved - it was built by an ancient civilisation.
The present-day civilisations can see each other through the wall but can only communicate in sign language. In fact the only people really interested are the children who spent a lot of time making faces and throwing stones at each other, all to no effect. Also of course there are medieval tourists who come to gape at this marvel.
The problem is that I want it to be smooth, unbreakable, unclimbable but most of all transparent.
What can this wall be made of? Could it be glass, diamond, some other real transparent material? How thick would it be?
A huge wall of ice would not be transparent, and would constantly need to be replaced at the top because of melting at the base. So I exclude that unless someone can prove me wrong.
To sum up: The wall must have survived for thousands of years, still be transparent (at least if given a wipe) and strong enough not to have been substantially damaged.
Question
Without the use of magic and using science that could really be done by an advanced civilisation with enough resources, can the wall be self-supporting and what should it be made of?
EDIT - I should have provided some idea of the shape and scale of the mountain pass. I won't change anything here because I don't want to invalidate any answers. However if you look at my own answer (vertical conveyor belt) to my question below, I've added some links to pictures giving an idea of what I was imagining.
science-based reality-check engineering
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I'd like two medieval societies to be separated from one another by a huge vertical wall.
The wall is so high that no-one has succeeded in shooting an arrow (or anything else) over it. It disappears up into perpetual mist. This wall bridges a pass in the middle of a mountain range that no-one has managed to scale because of the continual blizzards that rage and indeed the traditional stories about fearsome beasts that live there.
This wall is solid. There is no magic involved - it was built by an ancient civilisation.
The present-day civilisations can see each other through the wall but can only communicate in sign language. In fact the only people really interested are the children who spent a lot of time making faces and throwing stones at each other, all to no effect. Also of course there are medieval tourists who come to gape at this marvel.
The problem is that I want it to be smooth, unbreakable, unclimbable but most of all transparent.
What can this wall be made of? Could it be glass, diamond, some other real transparent material? How thick would it be?
A huge wall of ice would not be transparent, and would constantly need to be replaced at the top because of melting at the base. So I exclude that unless someone can prove me wrong.
To sum up: The wall must have survived for thousands of years, still be transparent (at least if given a wipe) and strong enough not to have been substantially damaged.
Question
Without the use of magic and using science that could really be done by an advanced civilisation with enough resources, can the wall be self-supporting and what should it be made of?
EDIT - I should have provided some idea of the shape and scale of the mountain pass. I won't change anything here because I don't want to invalidate any answers. However if you look at my own answer (vertical conveyor belt) to my question below, I've added some links to pictures giving an idea of what I was imagining.
science-based reality-check engineering
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You want the wall to be not just unbreakable - its surface should be non-degradable and unstainable?
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– Alexander
Dec 3 '18 at 21:53
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Keep in mind that over thousands of years the landscape can dramatically change, so building such a wall would be folly. For example Doggerland. Anyone who could build such a wall would know what could happen.
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– StephenG
Dec 4 '18 at 0:49
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If sound can't get through the wall, then I'm guessing air can't either? That could have some very interesting effects on wind and weather patterns near the wall, depending on how tall it was.
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– David K
Dec 4 '18 at 13:36
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This question can't be answered using science.
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– Geronimo
Dec 4 '18 at 13:38
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"smooth" : what stops someone from making some suction cups and just climbing up the wall? unless the wall has active defenses even 100 meters wouldn't be enough to stop someone climbing it.
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– Murphy
Dec 4 '18 at 13:47
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show 2 more comments
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I'd like two medieval societies to be separated from one another by a huge vertical wall.
The wall is so high that no-one has succeeded in shooting an arrow (or anything else) over it. It disappears up into perpetual mist. This wall bridges a pass in the middle of a mountain range that no-one has managed to scale because of the continual blizzards that rage and indeed the traditional stories about fearsome beasts that live there.
This wall is solid. There is no magic involved - it was built by an ancient civilisation.
The present-day civilisations can see each other through the wall but can only communicate in sign language. In fact the only people really interested are the children who spent a lot of time making faces and throwing stones at each other, all to no effect. Also of course there are medieval tourists who come to gape at this marvel.
The problem is that I want it to be smooth, unbreakable, unclimbable but most of all transparent.
What can this wall be made of? Could it be glass, diamond, some other real transparent material? How thick would it be?
A huge wall of ice would not be transparent, and would constantly need to be replaced at the top because of melting at the base. So I exclude that unless someone can prove me wrong.
To sum up: The wall must have survived for thousands of years, still be transparent (at least if given a wipe) and strong enough not to have been substantially damaged.
Question
Without the use of magic and using science that could really be done by an advanced civilisation with enough resources, can the wall be self-supporting and what should it be made of?
EDIT - I should have provided some idea of the shape and scale of the mountain pass. I won't change anything here because I don't want to invalidate any answers. However if you look at my own answer (vertical conveyor belt) to my question below, I've added some links to pictures giving an idea of what I was imagining.
science-based reality-check engineering
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I'd like two medieval societies to be separated from one another by a huge vertical wall.
The wall is so high that no-one has succeeded in shooting an arrow (or anything else) over it. It disappears up into perpetual mist. This wall bridges a pass in the middle of a mountain range that no-one has managed to scale because of the continual blizzards that rage and indeed the traditional stories about fearsome beasts that live there.
This wall is solid. There is no magic involved - it was built by an ancient civilisation.
The present-day civilisations can see each other through the wall but can only communicate in sign language. In fact the only people really interested are the children who spent a lot of time making faces and throwing stones at each other, all to no effect. Also of course there are medieval tourists who come to gape at this marvel.
The problem is that I want it to be smooth, unbreakable, unclimbable but most of all transparent.
What can this wall be made of? Could it be glass, diamond, some other real transparent material? How thick would it be?
A huge wall of ice would not be transparent, and would constantly need to be replaced at the top because of melting at the base. So I exclude that unless someone can prove me wrong.
To sum up: The wall must have survived for thousands of years, still be transparent (at least if given a wipe) and strong enough not to have been substantially damaged.
Question
Without the use of magic and using science that could really be done by an advanced civilisation with enough resources, can the wall be self-supporting and what should it be made of?
EDIT - I should have provided some idea of the shape and scale of the mountain pass. I won't change anything here because I don't want to invalidate any answers. However if you look at my own answer (vertical conveyor belt) to my question below, I've added some links to pictures giving an idea of what I was imagining.
science-based reality-check engineering
science-based reality-check engineering
edited Dec 6 '18 at 12:22
chasly from UK
asked Dec 3 '18 at 21:46
chasly from UKchasly from UK
14k465133
14k465133
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You want the wall to be not just unbreakable - its surface should be non-degradable and unstainable?
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– Alexander
Dec 3 '18 at 21:53
1
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Keep in mind that over thousands of years the landscape can dramatically change, so building such a wall would be folly. For example Doggerland. Anyone who could build such a wall would know what could happen.
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– StephenG
Dec 4 '18 at 0:49
3
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If sound can't get through the wall, then I'm guessing air can't either? That could have some very interesting effects on wind and weather patterns near the wall, depending on how tall it was.
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– David K
Dec 4 '18 at 13:36
3
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This question can't be answered using science.
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– Geronimo
Dec 4 '18 at 13:38
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"smooth" : what stops someone from making some suction cups and just climbing up the wall? unless the wall has active defenses even 100 meters wouldn't be enough to stop someone climbing it.
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– Murphy
Dec 4 '18 at 13:47
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show 2 more comments
2
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You want the wall to be not just unbreakable - its surface should be non-degradable and unstainable?
$endgroup$
– Alexander
Dec 3 '18 at 21:53
1
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Keep in mind that over thousands of years the landscape can dramatically change, so building such a wall would be folly. For example Doggerland. Anyone who could build such a wall would know what could happen.
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– StephenG
Dec 4 '18 at 0:49
3
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If sound can't get through the wall, then I'm guessing air can't either? That could have some very interesting effects on wind and weather patterns near the wall, depending on how tall it was.
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– David K
Dec 4 '18 at 13:36
3
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This question can't be answered using science.
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– Geronimo
Dec 4 '18 at 13:38
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"smooth" : what stops someone from making some suction cups and just climbing up the wall? unless the wall has active defenses even 100 meters wouldn't be enough to stop someone climbing it.
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– Murphy
Dec 4 '18 at 13:47
2
2
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You want the wall to be not just unbreakable - its surface should be non-degradable and unstainable?
$endgroup$
– Alexander
Dec 3 '18 at 21:53
$begingroup$
You want the wall to be not just unbreakable - its surface should be non-degradable and unstainable?
$endgroup$
– Alexander
Dec 3 '18 at 21:53
1
1
$begingroup$
Keep in mind that over thousands of years the landscape can dramatically change, so building such a wall would be folly. For example Doggerland. Anyone who could build such a wall would know what could happen.
$endgroup$
– StephenG
Dec 4 '18 at 0:49
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Keep in mind that over thousands of years the landscape can dramatically change, so building such a wall would be folly. For example Doggerland. Anyone who could build such a wall would know what could happen.
$endgroup$
– StephenG
Dec 4 '18 at 0:49
3
3
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If sound can't get through the wall, then I'm guessing air can't either? That could have some very interesting effects on wind and weather patterns near the wall, depending on how tall it was.
$endgroup$
– David K
Dec 4 '18 at 13:36
$begingroup$
If sound can't get through the wall, then I'm guessing air can't either? That could have some very interesting effects on wind and weather patterns near the wall, depending on how tall it was.
$endgroup$
– David K
Dec 4 '18 at 13:36
3
3
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This question can't be answered using science.
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– Geronimo
Dec 4 '18 at 13:38
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This question can't be answered using science.
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– Geronimo
Dec 4 '18 at 13:38
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"smooth" : what stops someone from making some suction cups and just climbing up the wall? unless the wall has active defenses even 100 meters wouldn't be enough to stop someone climbing it.
$endgroup$
– Murphy
Dec 4 '18 at 13:47
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"smooth" : what stops someone from making some suction cups and just climbing up the wall? unless the wall has active defenses even 100 meters wouldn't be enough to stop someone climbing it.
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– Murphy
Dec 4 '18 at 13:47
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18 Answers
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Quick answer:
Some sort of indistinguishable-from-magic force field.
There's no material of which modern materials science is aware that would have the structural and optical properties you're seeking. Diamond, even if it could be made large enough, has terrible shear strength, so being able to resist wind for thousands of years would be insufficient - plus, of course, a suitably determined effort with other diamonds would get through it.
(For that matter, even leaving aside the optical properties, the wall as described is likely to be almost impossible to build - even hypothetical building materials need structural supports and buttressing lest they simply be blown over.)
So the ancients built a force field projector powered by geothermal energy that creates a solid, inch-thick "wall" which leverages physics properties of which we're not aware to create a solid barrier through which only electromagnetic radiation can pass.
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of course, a suitably determined effort with other diamonds would get through it
or someone w/ a blowtorch ... carbon burns
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– CaffeineAddiction
Dec 4 '18 at 8:08
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@CaffeineAddiction Diamond has ridiculously good thermal conductivity. You'd most likely need a torch big enough to warm up considerable swath of the wall at once. Also, there is not enough oxygen in our atmosphere to make a diamond burn, all the demonstrations blow pure O2 to get them burning.
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– Agent_L
Dec 4 '18 at 11:44
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@CaffeineAddiction no, Agent_L is right. The reason diamonds can perish in a house fire is that they're completely within the hot environment, so there's nowhere the heat can be conducted away to. With this wall, that would be very much different.
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– leftaroundabout
Dec 4 '18 at 13:49
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Sci-show did a recent episode on force fields that might also be helpful to watch: youtube.com/watch?v=Zeb-nMITuTg Short answer is we actually do know how to make force fields that can block matter, but sustained delivery would be difficult.
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– jkeuhlen
Dec 4 '18 at 19:20
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Don't think you'd need any kind of flame or other diamonds to get through a wall of diamond. Just some pick axes would do just fine. It maybe be hard, but it's very brittle. Smashing into it would break chunks off.
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– Shufflepants
Dec 4 '18 at 21:54
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There is no material that meets the requirements of being transparent and completely unweatherable, unscratchable etc... over thousands of years. Even diamond isn't that impervious, if you take grandma's ring to a jewellers they will often find a slight chip from daily wear.
Therefore, we need some sci-fi handwaving here. This wall is either made of unobtantium or can self-repair. Each of these stretches physics in uncomfortable ways
Unobtainium
- Go nuts, perhaps define it as an ultra-hard ceramic or a metal of unusual properties.
Self-Repairing
- Automated nanites? How about a diamond wall with Nanites that can recover carbon from the air and insert those atoms into the diamond to maintain a perfect lattice of great optical clarity. Although this suggests an active tech facility that maintains the nanites and, perhaps, atmospheric processing to obtain the carbon.
PS. Not hearing anything through the wall is hard (conduction of sound through a solid is excellent -- cup-on-the-wall type methods would work pretty well). You might need the wall to hum or something to drown out these sounds. Or have an air-gap in the wall that somehow doesn't get filled with snow.
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A diamond wall can be simply burnt. And no nanites will help this.
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– Gangnus
Dec 3 '18 at 22:49
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Transparent metals are very real. And having nanites maintain the wall would help it keep all the properties you want it to have.
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– Arvex
Dec 3 '18 at 23:00
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@Arvex not in pure form they are not. The closest Ifound was Aluminium oxynitride, ceramic that is marketed as transparent aluminum. And nanites to repair ceramics or aluminum are not even close to being real... Sadly.
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– Mołot
Dec 3 '18 at 23:12
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you could break down a diamond wall with sledgehammer, hard is not the same thing as strong.
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– John
Dec 4 '18 at 20:31
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The closest idea I can come up with is sapphire (or other transparent ceramics. It can be clear if made that way, it is a 9 on the hardness scale so unless you scratch a diamond across it it would be very hard to leave marks on, and when properly mixed with other substances during creation things like it can be used in bullet proof windows for armored vehicles (see Aluminum oxynitride which is like sapphire with extra bits).
This coupled with an absurdly high melting point should make it more or less indestructible to medeval civilizations. If you make it thick enough to support being tall enough that nothing goes over it (say ballpark 10m thick at the base with a gentle taper up to 100m) at ground level you may be able to mar it but it is naturally resistant enough that it is doubtful people would be able to seriously damage it without a lot of time, effort, and explosives
though I'll be honest I am not sure the compression strength of sapphire is high enough to support such a tall and dense structure. Maybe have hollow portions higher up to get rid of some of the weight or have opaque materials at regular intervals for supports
To ease the completely unbreakable portion of your description since you are talking about a relic of an advanced civilization it could be that the wall has a method of self repair like a gene tailored bacteria or nanobots that refill any cracks, scratches, etc that might occur.
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surmet.com/pdfs/news-and-media/…, of course the wall doesn't need to be monolithic, compressed ions, epj-pv.org/articles/epjpv/pdf/2015/01/pv140017.pdf & other materials may be included to enhance structural properties. Traditional transparency may not be optimal, but rather a mesh or 'active camoflage' system outfacing on otherwise more structurally reliable material.
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– Giu Piete
Dec 4 '18 at 5:33
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Also rather than repairing damaged surfaces it might be better to have them decompose and be replaced internally to a (macro)mechanical structure in films with pressure applied to expand the outer layers to maintain dimensions.
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– Giu Piete
Dec 4 '18 at 5:35
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Compression strength is intimately tied to hardness. Sapphire has a compressive strength of 2000 MPa (cf concrete 20-40 MPa).
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– Martin Bonner
Dec 4 '18 at 9:41
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You'd want a wall higher than 100m. The Great Pyramid was originally about 150m tall. The Romans built a siege ramp about 60m up the side of Masada - and that was under fire, only a 1:10 slope, and wide enough to push a siege engine up.
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– Martin Bonner
Dec 4 '18 at 9:48
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Sapphire crystal watches still get scratches. Not easily, but it is a problem noticeable in one lifetime, so over thousands of years it will get opaque. Plus, it chips. Relatively low impact resistance.
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– Mołot
Dec 4 '18 at 12:09
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Time/Space Sheer field
This section of reality is sheered in such a way that the time/space location on the other side is completely different. Even if the two medieval civilisations circumnavigated those mountains, they would only perceive the field from the opposite direction.
The sheering permits photons (massless objects) through but seriously twists, deforms, and even repels mass that reaches a certain point. It would also explain why sound cannot penetrate. The internals of this wall are effectively a vacuum.
As for the power requirements, a civilisation that has time/space sheering knowledge to the ability of this wall, could easily transmit power through a much smaller time/space shear from some astronomical power source such as a neutron star/black hole/etc...
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You need a secondary structure, a primary one, and transparent cladding
Modern day skyscrapers are often clad in glass, to form full height glass 'walls'.
This is achieved with what is called a 'curtain walling system'. It is essentially a primary structure, with a secondary structure attached that supports smaller glazed panels. This enables the following advantages:
- The wall is not supported by glass, but instead a protected robust structure behind it.
- The wall is partially flexible, wind loads could slightly bend the wall as the glass is segmented. The secondary structure under could cater for deflection, while the primary structure caters for the main static load.
- The glass could be as thick, strong or rigid as needed, just being accommodated with a thick structure as needed behind it.
- The structure behind can be a truss-like structure, using lightweight steel elements (much like high voltage towers), in particular if you do not require the wall to be habitable. The interior structure has the added advantage that it is protected from weather.
- The primary structure being protected could be large concrete columns, or thick steel columns, as large as is necessary
- The glass could be replaced individually from behind if any damage occurs, some systems have internal fixing frames intended for interior access in case exterior access is not possible.
An example architectural detail of a framed curtain wall:
An example of an alternate frameless, spider joint supported detail, with a secondary structure (primary not shown):
There is theoretically no limit to the height of these structures (as is exemplified in our tall buildings today), with greater size only requiring greater structure behind depending on wind load. Thickness can be increased for longevity if needed, and if there are no economic considerations, increased at whim to last centuries (a lot of existing curtain walling systems have been in existence for a long time with little to no maintenance).
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Glass isn't durable enough. A few thousand years of wind-blown sand, and you'll get a cloudy surface that barely passes light. There are also little problems like boulders and battering rams.
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– Mark
Dec 5 '18 at 2:42
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Wind, so the material is air. Natural wind is funneled by a gargantouesque ravine reaching far away and creating the effect you describe. If ever the wind decreases to much (after some extraodinary event) the walls heat and natural fournaces below come into action in contact with water projecting streams of vapor. Water below might also be a carved system of water streams and tanks.
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Ingenious. It could even be part of the ancient civilisation's air-conditioning system!
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– chasly from UK
Dec 4 '18 at 17:12
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Rock crystal
(Quartz) has the lowest potential for weathering and consequently it is very common as a residual mineral found in veins within sandstone which could have weathered each side , at the head of a mountain pass the rain would wash the sandstone down each side of this cleft between phenomenally steep valley sides thus there are no holes through or around it..
Could be top heavy crystalline the higher it gets since the ancients were mining in from each side, but for whatever reason the hardest transparent core had not been finished and past attempts to climb or dig at it have resulted in shards falling from above, keeping later attempts at bay due to the gods displeasure ?
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There's a different problem here.
You have the wall being impossibly high, ridiculously long, impervious to damage, impervious to sound, and perfectly clear. Okay. Let's just take that as given for now.
You say that it's a place where people come for tourism, to communicate via sign language, and (for smallish children) to throw rocks at it. Fine. Then you say that it's across a pass in a mountain range, where the storms are bad enough that no one has ever managed to get over the thing (and also there are terrible beasts). That's a problem. In particular, no one would go there. A pass that's that treacherous is the sort of thing that people only climb to with strong reason, and "gawk at the folks who can be seen but not heard and not touched" isn't a strong reason - especially not since they'll have the same sort of pass on their side, so most days they won't be showing up either.
If you want people to actually interact with this thing more than about once a generation, and if you want them to have any contact with one another through the wall at all, you need to make it reasonably accessible.
If you do that, one of the things you will see, I suspect, is architecture. Having an impossibly tall, smooth wall that won't fall over no matter how much weight you put against it is potentially really useful from an architectural standpoint. The opportunity to leave the glass wall side of your building open, and thus to do socially shocking things where you know that people can see, but they can't possibly inform anyone you care about is just bonus. (Walking about without a hat? Scandalous!)
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Good points - I'm beginning to realise I should have attempted some kind of diagram. In my imagination the pass was artificially cut through the mountains and reaches down to the plain. The heights have the blizzards and the terrible beasts. That explains why no-one tries to bypass the barrier by climbing up and around it. I'll make a diagram at some point but I'll put it in my own answer so as not to invalidate anyone else's. At some point the hero may discover the secret and be able to open the barrier which may slide back.
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– chasly from UK
Dec 6 '18 at 11:22
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I see a few comments related to "aluminum" and I recall from Star Trek, the concept of Transparent Aluminum and turns out, has been created. Further reading per the link suggests Iron can also be made transparent - see below:
https://en.wikipedia.org/wiki/List_of_Star_Trek_materials#Transparent_aluminum
Pure transparent aluminum was created as a new state of matter by a team of scientists in 2009. A laser pulse removed an electron from every atom without disrupting the crystalline structure. However, the transparent state lasted for only 40 femtoseconds, until electrons returned to the material.
A group of scientists led by Ralf Röhlsberger at Deutsches Elektronen-Synchrotron (DESY), Hamburg, Germany, succeeded in turning iron transparent during research in 2012 to create quantum computers.
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Hello and welvome. Please, do not post purely fictional materials as an answer to science-based questions.
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– Mołot
Dec 4 '18 at 19:36
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Yes the idea for my post was inspired by fiction, but the link reference actual experiments where both Aluminum and Iron were made transparent!
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– flaZer
Dec 4 '18 at 19:38
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Vertical conveyor belt
I've been thinking about some of the objections and have come up with answer to my own question that might work.
Maybe it could even be made of thick glass. The wall could be blocking a tall narrow rectangular cut through the mountains - an artificial pass. The wall could be quite narrow (say enough for ten-abreast to pass through) and thus supported all the way up by a frame.
EDIT - Apologies - I should have made something clear when posing the question. In my imagination the pass is cut through the mountains by the aliens. It looks something like the following only much more smooth-sided and rectangular. The pictures are from the ancient site of Petra. https://en.wikipedia.org/wiki/Siq
https://upload.wikimedia.org/wikipedia/commons/thumb/e/e3/PS-Petra_6148.JPG/1200px-PS-Petra_6148.JPG
https://upload.wikimedia.org/wikipedia/commons/thumb/3/32/V%C3%A4gen_in.jpg/800px-V%C3%A4gen_in.jpg
The wall consists of sheet of material that slowly emerges from a slot at one side of the pass and eventually disappears into a slot on the other side. Behind the scenes, the material is melted and reformed after which it goes through another slot and back to the starting point where the same thing happens. Thus the wall is a kind of continuous vertical conveyor belt whose surface is always being renewed.
Problems
There would have to be a substantial cache (of sand in the case of glass) or other renewable source of wall-material to make up any losses from natural wear-and-tear.
An enormous power source would be required but I suppose it could be nuclear.
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This may not be exactly what you described, but one idea could be to use screens/projections on each side.
The "wall" could be built out of regular material, at least on the inside, with some form of ultra-hard glass (or transparent-steel) coating the outside. Each screen then projects a live feed of the other side. To a medieval civilization this would more or less look like a transparent wall, with each side seeing a projection of the other. The display itself could even use some advanced form of e-paper tech in order to avoid backlight issues.
While this can maybe solve some of the issues of material and structure of a solid wall, it does of course pose questions about power supply and wear/tear on the hardware itself. This could be ignored by claiming it uses futuristic self-repairing tech, but it really depends on the setting.
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Based on the height and thickness of the wall, power could come from solar panels on the top of the wall. Or wind could be harnessed similar to that of Ocean Current Energy where subtle gusts of wind pushing against the wall cause minute points of pressure that can be converted into energy. Or of course, energy production could be generated underground (geothermal / nuclear / etc.)
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– flaZer
Dec 4 '18 at 21:56
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Wind turbines with sharp blades would add to the unscaleability. As would big photoenergetic setups with focussing mirrors that bundle at human height.
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– bukwyrm
Dec 5 '18 at 6:11
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Magnetic Barrier
A very, very, very strong magnetic field would be both entirely transparent and impervious to all materials*. Because it's not a static surface it will always remain perfectly clear as it won't collect dirt or debris.
How does it work? Unlike ferromagnetism, which is a property only exhibited by a few materials, diamagnetism is a property of all materials. Given a strong enough magnetic field everything would be repelled*.
To anyone experimenting with this "wall" it might appear to be soft. As they begin to press against it they would feel increasing push back as the repulsion force builds until they can't press further (which may become painful). Objects thrown again this "wall" would have a slight bounce back.
Sound can also be controlled by magnetism. The "wall" could be deliberately engineered to reflect sound back to its source. However the very nature of such a strong field may perturb the phonons of sound enough to make the "wall" naturally acoustically impermeable.
* Strictly speaking a field strong enough to repel solid objects would only have a weak interaction with sparse substances such as the oxygen and nitrogen in the atmosphere. Perhaps producing a slight wind and/or higher levels of oxygen at the wall. Additionally, photon lensing would be imperceivable at this level.
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What would be a ballpark figure on the strength of a magnetic field like that? Is it in any way realistic to generate with technology we could imagine, even if just in theory? I'm not a physicist, but my guesses to the answers would be "go fetch me a neutron star" and "LOL no", respectively, but it would be interesting to consider the practical ramifications rather than just postulate the field is there somehow.
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– Jeroen Mostert
Dec 4 '18 at 19:10
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@JeroenMostert this site goes into more detail behind the physics. It requires ~10 teslas to levitate a small diamagnetic object. 1000 tesla magnets have already been built. Surprisingly magnetic fields aren't very resource expensive. For example the power requirements to levitate a maglev train car are approximately equivalent to the that of a room air conditioner. The energy costs would be high, but not impossible so.
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– Skek Tek
Dec 4 '18 at 20:48
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@SkekTek, thing is, magnetic field strength falls off as the inverse cube of distance. Those frog-levitating magnets are only that strong in a roughly frog-sized volume. If you're trying to block off an entire mountain pass, you're going to need an insanely strong magnet. (And I suspect the pass will very quickly get blocked off by stray bits of iron and other ferromagnetic materials.)
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– Mark
Dec 5 '18 at 2:51
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What @Mark said: a 16T field may levitate a 20g frog, but you're talking about a field capable of (at least) repelling a fully grown adult and speeding projectiles pushing against it with forces much greater than gravity, and that field has to span a far bigger area. Those 1000T magnets (and the few with even higher strengths) are destroyed in the experiments, so not exactly suitable for a permanent wall. I'm not saying it's impossible, but it sounds like the kind of thing that could immediately fall apart when you actually run the numbers.
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– Jeroen Mostert
Dec 5 '18 at 5:14
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@Mark This is a solvable engineering problem. The falloff is quick but the range is effectively unlimited. They would simply need to meter the strength of the field for the applicable area. In this case the area is confined to a pass and presumably the field can be generated from 3 sides. Height has only been measured by the deflection of a low mass projectile at a steep angle (the ionic wind generated by the field might even be enough to deflect the arrow into a tumble).
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– Skek Tek
Dec 5 '18 at 13:44
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show 2 more comments
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Relax the definition of "Transparent"
As several other answers have discussed, building a massive, impenetrable wall out of transparent material is impossible. But if the ancients had advanced technology, the same effect can be achieved without the wall actually being transparent in the sense that light passes through unobstructed. Simply cover the wall on all sides with a cloaking device.
In essence, make the whole thing a screen that shows the viewer the light hitting the wall on the opposite side, captured by nanotech cameras or similar. Rudimentary versions of this technology already exist (with varying degrees of success). For fictional ancients with advanced technology, a perfected version that shows the correct image from any viewing angle should be trivial. Cover the screen with a layer of diamond to protect its "transparency" from attack, and then build the wall out of whatever you want. The bigger and more sturdy the better, so there's room on the inside for the massive computers required to make the thing run.
Since you've already got sophisticated computers powering the thing, adding a noise cancellation module seems straightforward.
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The Wall is an surreal absurdity.
https://www.nytimes.com/1978/05/07/archives/surreal-and-absurd-surreal.html
The paradox of this kind of literature is that if the symbols are too
easily comprehensible they tend to appear monotonous and‐ trite, while
if they are totally opaque, they offer no purchase for the mind and
merely replace the Absurdist face of the world by an impenetrable
surface of apparently random verbal signs. The ideal solution, not
easy to achieve, is a convincingly pregnant mystery.
With a wall like this, your fiction should be absurdist and surreal. A clear wall separating 2 societies is going to be a metaphor. If you establish that it is clear aluminum oxide that falls under trite. Leaving it up in the air will be frustrating. Best: you can have various characters explain it in detail and have it be different each time. In the absurdist tradition, each citizen can have his or her own persuasion about how the wall works and what it is made of - glass, or wind, or force, or living creatures, or an erotic dream. I can envision the same character who put forth one explanation then putting forth a different one later in the story. If challenged, the character may or may not recall his original explanation, and will good-naturedly try to change the subject.
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The eventual aim is that a heroic character will climb the cliffs and defeat the monsters. They will then find a secret entrance and discover the ancient mechanism (which they don't understand but the reader might from a description of what everything looks like). Then they press the right button and the barrier slides back.
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– chasly from UK
Dec 6 '18 at 13:11
add a comment |
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A dense packing of optical fibres, endlessly rising from the ground. This would give observers the impression of people being inches away that in reality are meters distant. An underground source let's it rise up, taking any damage with it (making it impermeable) and slowly disintegrating in lofty heights (keeping its secret). The height is what makes it unsurpassable. If the world otherwise has never seen a TV-stone no one would figure it https://en.m.wikipedia.org/wiki/Ulexite.
The see- through would be quite limited, but the weird 'right below the surface' vibe of anything that IS seen might make up for it.
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add a comment |
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You want transparent, AND immune to surface degradation by thousands of years of wind and weather? In a mountain range, thus 100% guaranteed to be an earthquake zone at least in the very long term?
That is a very tall order!
Even a diamond surface would fail the test, you would have to resort to some mumble-fumble-handwaving forcefield or outright magic.
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It can't be done in a science-based way.
Diamond might come close, but it's a brittle material. Hit it hard with a sharp point (hardened steel, or rock) and it will crack. Toughened glass is more resistant to cracking, but shatters very spectacularly if you apply enough force (or grind your way through the outer toughened shell). You might try "toughened diamond", with no further explanation. Metals are resistant to cracking, but the physics which makes this so is the same physics that makes them opaque and reflective.
I'm tempted to add that it's obviously a General Products hull derivative, and so Puppeteers must be involved. "One giant molecule with its atomic bonds artificially strengthened using the output of a small nuclear reactor ..." Good handwavium, but impossible given science as we know it.
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The materials of the neutron star or white dwarf can be extremely thin, transparent and cannot be influenced by any chemical way and their mechanical hardness is absolute for a medieval civilization.
Our contemporary science cannot create or keep such walls (same as superstrong walls of usual materials), but we are talking about some hypothetical super-civilization.
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I don't know where you got part about being thin and transparent. It also cannot exist in conditions that allows for civilization next to it, so even if you're right, it id still useless.
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– Mołot
Dec 3 '18 at 23:08
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Conditions needed what happens inside neutron star are extreme. It's too big to post in comment, useful basic article here en.wikipedia.org/wiki/Neutron_star#Properties
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– Mołot
Dec 3 '18 at 23:22
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A sheet of neutron star material would weigh much, much more than a planet. Any engineering effort to make a neutron-star structure with non-destructive mass would remove the gravitational potential that holds the quarks in such an extremely compressed state, and would release an explosion somewhere between planet-killer and solar-system-killer on the explosion scale
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– Mark_Anderson
Dec 3 '18 at 23:23
6
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Rock samples taken from deep underground explode when the pressure they are subjected is released. And they are far from experiencing the pressures found in a neutron star...
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– L.Dutch♦
Dec 4 '18 at 0:14
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Just use a thin huge indestructible transparent wall to hold the neutron star material in place, aka. the ancient spellrecursion
.
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– nwp
Dec 4 '18 at 12:41
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show 2 more comments
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18 Answers
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Quick answer:
Some sort of indistinguishable-from-magic force field.
There's no material of which modern materials science is aware that would have the structural and optical properties you're seeking. Diamond, even if it could be made large enough, has terrible shear strength, so being able to resist wind for thousands of years would be insufficient - plus, of course, a suitably determined effort with other diamonds would get through it.
(For that matter, even leaving aside the optical properties, the wall as described is likely to be almost impossible to build - even hypothetical building materials need structural supports and buttressing lest they simply be blown over.)
So the ancients built a force field projector powered by geothermal energy that creates a solid, inch-thick "wall" which leverages physics properties of which we're not aware to create a solid barrier through which only electromagnetic radiation can pass.
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of course, a suitably determined effort with other diamonds would get through it
or someone w/ a blowtorch ... carbon burns
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– CaffeineAddiction
Dec 4 '18 at 8:08
2
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@CaffeineAddiction Diamond has ridiculously good thermal conductivity. You'd most likely need a torch big enough to warm up considerable swath of the wall at once. Also, there is not enough oxygen in our atmosphere to make a diamond burn, all the demonstrations blow pure O2 to get them burning.
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– Agent_L
Dec 4 '18 at 11:44
2
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@CaffeineAddiction no, Agent_L is right. The reason diamonds can perish in a house fire is that they're completely within the hot environment, so there's nowhere the heat can be conducted away to. With this wall, that would be very much different.
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– leftaroundabout
Dec 4 '18 at 13:49
1
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Sci-show did a recent episode on force fields that might also be helpful to watch: youtube.com/watch?v=Zeb-nMITuTg Short answer is we actually do know how to make force fields that can block matter, but sustained delivery would be difficult.
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– jkeuhlen
Dec 4 '18 at 19:20
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Don't think you'd need any kind of flame or other diamonds to get through a wall of diamond. Just some pick axes would do just fine. It maybe be hard, but it's very brittle. Smashing into it would break chunks off.
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– Shufflepants
Dec 4 '18 at 21:54
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show 8 more comments
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Quick answer:
Some sort of indistinguishable-from-magic force field.
There's no material of which modern materials science is aware that would have the structural and optical properties you're seeking. Diamond, even if it could be made large enough, has terrible shear strength, so being able to resist wind for thousands of years would be insufficient - plus, of course, a suitably determined effort with other diamonds would get through it.
(For that matter, even leaving aside the optical properties, the wall as described is likely to be almost impossible to build - even hypothetical building materials need structural supports and buttressing lest they simply be blown over.)
So the ancients built a force field projector powered by geothermal energy that creates a solid, inch-thick "wall" which leverages physics properties of which we're not aware to create a solid barrier through which only electromagnetic radiation can pass.
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4
$begingroup$
of course, a suitably determined effort with other diamonds would get through it
or someone w/ a blowtorch ... carbon burns
$endgroup$
– CaffeineAddiction
Dec 4 '18 at 8:08
2
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@CaffeineAddiction Diamond has ridiculously good thermal conductivity. You'd most likely need a torch big enough to warm up considerable swath of the wall at once. Also, there is not enough oxygen in our atmosphere to make a diamond burn, all the demonstrations blow pure O2 to get them burning.
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– Agent_L
Dec 4 '18 at 11:44
2
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@CaffeineAddiction no, Agent_L is right. The reason diamonds can perish in a house fire is that they're completely within the hot environment, so there's nowhere the heat can be conducted away to. With this wall, that would be very much different.
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– leftaroundabout
Dec 4 '18 at 13:49
1
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Sci-show did a recent episode on force fields that might also be helpful to watch: youtube.com/watch?v=Zeb-nMITuTg Short answer is we actually do know how to make force fields that can block matter, but sustained delivery would be difficult.
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– jkeuhlen
Dec 4 '18 at 19:20
1
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Don't think you'd need any kind of flame or other diamonds to get through a wall of diamond. Just some pick axes would do just fine. It maybe be hard, but it's very brittle. Smashing into it would break chunks off.
$endgroup$
– Shufflepants
Dec 4 '18 at 21:54
|
show 8 more comments
$begingroup$
Quick answer:
Some sort of indistinguishable-from-magic force field.
There's no material of which modern materials science is aware that would have the structural and optical properties you're seeking. Diamond, even if it could be made large enough, has terrible shear strength, so being able to resist wind for thousands of years would be insufficient - plus, of course, a suitably determined effort with other diamonds would get through it.
(For that matter, even leaving aside the optical properties, the wall as described is likely to be almost impossible to build - even hypothetical building materials need structural supports and buttressing lest they simply be blown over.)
So the ancients built a force field projector powered by geothermal energy that creates a solid, inch-thick "wall" which leverages physics properties of which we're not aware to create a solid barrier through which only electromagnetic radiation can pass.
$endgroup$
Quick answer:
Some sort of indistinguishable-from-magic force field.
There's no material of which modern materials science is aware that would have the structural and optical properties you're seeking. Diamond, even if it could be made large enough, has terrible shear strength, so being able to resist wind for thousands of years would be insufficient - plus, of course, a suitably determined effort with other diamonds would get through it.
(For that matter, even leaving aside the optical properties, the wall as described is likely to be almost impossible to build - even hypothetical building materials need structural supports and buttressing lest they simply be blown over.)
So the ancients built a force field projector powered by geothermal energy that creates a solid, inch-thick "wall" which leverages physics properties of which we're not aware to create a solid barrier through which only electromagnetic radiation can pass.
answered Dec 3 '18 at 22:18
jdunlopjdunlop
7,53211643
7,53211643
4
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of course, a suitably determined effort with other diamonds would get through it
or someone w/ a blowtorch ... carbon burns
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– CaffeineAddiction
Dec 4 '18 at 8:08
2
$begingroup$
@CaffeineAddiction Diamond has ridiculously good thermal conductivity. You'd most likely need a torch big enough to warm up considerable swath of the wall at once. Also, there is not enough oxygen in our atmosphere to make a diamond burn, all the demonstrations blow pure O2 to get them burning.
$endgroup$
– Agent_L
Dec 4 '18 at 11:44
2
$begingroup$
@CaffeineAddiction no, Agent_L is right. The reason diamonds can perish in a house fire is that they're completely within the hot environment, so there's nowhere the heat can be conducted away to. With this wall, that would be very much different.
$endgroup$
– leftaroundabout
Dec 4 '18 at 13:49
1
$begingroup$
Sci-show did a recent episode on force fields that might also be helpful to watch: youtube.com/watch?v=Zeb-nMITuTg Short answer is we actually do know how to make force fields that can block matter, but sustained delivery would be difficult.
$endgroup$
– jkeuhlen
Dec 4 '18 at 19:20
1
$begingroup$
Don't think you'd need any kind of flame or other diamonds to get through a wall of diamond. Just some pick axes would do just fine. It maybe be hard, but it's very brittle. Smashing into it would break chunks off.
$endgroup$
– Shufflepants
Dec 4 '18 at 21:54
|
show 8 more comments
4
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of course, a suitably determined effort with other diamonds would get through it
or someone w/ a blowtorch ... carbon burns
$endgroup$
– CaffeineAddiction
Dec 4 '18 at 8:08
2
$begingroup$
@CaffeineAddiction Diamond has ridiculously good thermal conductivity. You'd most likely need a torch big enough to warm up considerable swath of the wall at once. Also, there is not enough oxygen in our atmosphere to make a diamond burn, all the demonstrations blow pure O2 to get them burning.
$endgroup$
– Agent_L
Dec 4 '18 at 11:44
2
$begingroup$
@CaffeineAddiction no, Agent_L is right. The reason diamonds can perish in a house fire is that they're completely within the hot environment, so there's nowhere the heat can be conducted away to. With this wall, that would be very much different.
$endgroup$
– leftaroundabout
Dec 4 '18 at 13:49
1
$begingroup$
Sci-show did a recent episode on force fields that might also be helpful to watch: youtube.com/watch?v=Zeb-nMITuTg Short answer is we actually do know how to make force fields that can block matter, but sustained delivery would be difficult.
$endgroup$
– jkeuhlen
Dec 4 '18 at 19:20
1
$begingroup$
Don't think you'd need any kind of flame or other diamonds to get through a wall of diamond. Just some pick axes would do just fine. It maybe be hard, but it's very brittle. Smashing into it would break chunks off.
$endgroup$
– Shufflepants
Dec 4 '18 at 21:54
4
4
$begingroup$
of course, a suitably determined effort with other diamonds would get through it
or someone w/ a blowtorch ... carbon burns$endgroup$
– CaffeineAddiction
Dec 4 '18 at 8:08
$begingroup$
of course, a suitably determined effort with other diamonds would get through it
or someone w/ a blowtorch ... carbon burns$endgroup$
– CaffeineAddiction
Dec 4 '18 at 8:08
2
2
$begingroup$
@CaffeineAddiction Diamond has ridiculously good thermal conductivity. You'd most likely need a torch big enough to warm up considerable swath of the wall at once. Also, there is not enough oxygen in our atmosphere to make a diamond burn, all the demonstrations blow pure O2 to get them burning.
$endgroup$
– Agent_L
Dec 4 '18 at 11:44
$begingroup$
@CaffeineAddiction Diamond has ridiculously good thermal conductivity. You'd most likely need a torch big enough to warm up considerable swath of the wall at once. Also, there is not enough oxygen in our atmosphere to make a diamond burn, all the demonstrations blow pure O2 to get them burning.
$endgroup$
– Agent_L
Dec 4 '18 at 11:44
2
2
$begingroup$
@CaffeineAddiction no, Agent_L is right. The reason diamonds can perish in a house fire is that they're completely within the hot environment, so there's nowhere the heat can be conducted away to. With this wall, that would be very much different.
$endgroup$
– leftaroundabout
Dec 4 '18 at 13:49
$begingroup$
@CaffeineAddiction no, Agent_L is right. The reason diamonds can perish in a house fire is that they're completely within the hot environment, so there's nowhere the heat can be conducted away to. With this wall, that would be very much different.
$endgroup$
– leftaroundabout
Dec 4 '18 at 13:49
1
1
$begingroup$
Sci-show did a recent episode on force fields that might also be helpful to watch: youtube.com/watch?v=Zeb-nMITuTg Short answer is we actually do know how to make force fields that can block matter, but sustained delivery would be difficult.
$endgroup$
– jkeuhlen
Dec 4 '18 at 19:20
$begingroup$
Sci-show did a recent episode on force fields that might also be helpful to watch: youtube.com/watch?v=Zeb-nMITuTg Short answer is we actually do know how to make force fields that can block matter, but sustained delivery would be difficult.
$endgroup$
– jkeuhlen
Dec 4 '18 at 19:20
1
1
$begingroup$
Don't think you'd need any kind of flame or other diamonds to get through a wall of diamond. Just some pick axes would do just fine. It maybe be hard, but it's very brittle. Smashing into it would break chunks off.
$endgroup$
– Shufflepants
Dec 4 '18 at 21:54
$begingroup$
Don't think you'd need any kind of flame or other diamonds to get through a wall of diamond. Just some pick axes would do just fine. It maybe be hard, but it's very brittle. Smashing into it would break chunks off.
$endgroup$
– Shufflepants
Dec 4 '18 at 21:54
|
show 8 more comments
$begingroup$
There is no material that meets the requirements of being transparent and completely unweatherable, unscratchable etc... over thousands of years. Even diamond isn't that impervious, if you take grandma's ring to a jewellers they will often find a slight chip from daily wear.
Therefore, we need some sci-fi handwaving here. This wall is either made of unobtantium or can self-repair. Each of these stretches physics in uncomfortable ways
Unobtainium
- Go nuts, perhaps define it as an ultra-hard ceramic or a metal of unusual properties.
Self-Repairing
- Automated nanites? How about a diamond wall with Nanites that can recover carbon from the air and insert those atoms into the diamond to maintain a perfect lattice of great optical clarity. Although this suggests an active tech facility that maintains the nanites and, perhaps, atmospheric processing to obtain the carbon.
PS. Not hearing anything through the wall is hard (conduction of sound through a solid is excellent -- cup-on-the-wall type methods would work pretty well). You might need the wall to hum or something to drown out these sounds. Or have an air-gap in the wall that somehow doesn't get filled with snow.
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A diamond wall can be simply burnt. And no nanites will help this.
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– Gangnus
Dec 3 '18 at 22:49
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Transparent metals are very real. And having nanites maintain the wall would help it keep all the properties you want it to have.
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– Arvex
Dec 3 '18 at 23:00
1
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@Arvex not in pure form they are not. The closest Ifound was Aluminium oxynitride, ceramic that is marketed as transparent aluminum. And nanites to repair ceramics or aluminum are not even close to being real... Sadly.
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– Mołot
Dec 3 '18 at 23:12
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you could break down a diamond wall with sledgehammer, hard is not the same thing as strong.
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– John
Dec 4 '18 at 20:31
add a comment |
$begingroup$
There is no material that meets the requirements of being transparent and completely unweatherable, unscratchable etc... over thousands of years. Even diamond isn't that impervious, if you take grandma's ring to a jewellers they will often find a slight chip from daily wear.
Therefore, we need some sci-fi handwaving here. This wall is either made of unobtantium or can self-repair. Each of these stretches physics in uncomfortable ways
Unobtainium
- Go nuts, perhaps define it as an ultra-hard ceramic or a metal of unusual properties.
Self-Repairing
- Automated nanites? How about a diamond wall with Nanites that can recover carbon from the air and insert those atoms into the diamond to maintain a perfect lattice of great optical clarity. Although this suggests an active tech facility that maintains the nanites and, perhaps, atmospheric processing to obtain the carbon.
PS. Not hearing anything through the wall is hard (conduction of sound through a solid is excellent -- cup-on-the-wall type methods would work pretty well). You might need the wall to hum or something to drown out these sounds. Or have an air-gap in the wall that somehow doesn't get filled with snow.
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1
$begingroup$
A diamond wall can be simply burnt. And no nanites will help this.
$endgroup$
– Gangnus
Dec 3 '18 at 22:49
$begingroup$
Transparent metals are very real. And having nanites maintain the wall would help it keep all the properties you want it to have.
$endgroup$
– Arvex
Dec 3 '18 at 23:00
1
$begingroup$
@Arvex not in pure form they are not. The closest Ifound was Aluminium oxynitride, ceramic that is marketed as transparent aluminum. And nanites to repair ceramics or aluminum are not even close to being real... Sadly.
$endgroup$
– Mołot
Dec 3 '18 at 23:12
$begingroup$
you could break down a diamond wall with sledgehammer, hard is not the same thing as strong.
$endgroup$
– John
Dec 4 '18 at 20:31
add a comment |
$begingroup$
There is no material that meets the requirements of being transparent and completely unweatherable, unscratchable etc... over thousands of years. Even diamond isn't that impervious, if you take grandma's ring to a jewellers they will often find a slight chip from daily wear.
Therefore, we need some sci-fi handwaving here. This wall is either made of unobtantium or can self-repair. Each of these stretches physics in uncomfortable ways
Unobtainium
- Go nuts, perhaps define it as an ultra-hard ceramic or a metal of unusual properties.
Self-Repairing
- Automated nanites? How about a diamond wall with Nanites that can recover carbon from the air and insert those atoms into the diamond to maintain a perfect lattice of great optical clarity. Although this suggests an active tech facility that maintains the nanites and, perhaps, atmospheric processing to obtain the carbon.
PS. Not hearing anything through the wall is hard (conduction of sound through a solid is excellent -- cup-on-the-wall type methods would work pretty well). You might need the wall to hum or something to drown out these sounds. Or have an air-gap in the wall that somehow doesn't get filled with snow.
$endgroup$
There is no material that meets the requirements of being transparent and completely unweatherable, unscratchable etc... over thousands of years. Even diamond isn't that impervious, if you take grandma's ring to a jewellers they will often find a slight chip from daily wear.
Therefore, we need some sci-fi handwaving here. This wall is either made of unobtantium or can self-repair. Each of these stretches physics in uncomfortable ways
Unobtainium
- Go nuts, perhaps define it as an ultra-hard ceramic or a metal of unusual properties.
Self-Repairing
- Automated nanites? How about a diamond wall with Nanites that can recover carbon from the air and insert those atoms into the diamond to maintain a perfect lattice of great optical clarity. Although this suggests an active tech facility that maintains the nanites and, perhaps, atmospheric processing to obtain the carbon.
PS. Not hearing anything through the wall is hard (conduction of sound through a solid is excellent -- cup-on-the-wall type methods would work pretty well). You might need the wall to hum or something to drown out these sounds. Or have an air-gap in the wall that somehow doesn't get filled with snow.
answered Dec 3 '18 at 22:16
Mark_AndersonMark_Anderson
1,505511
1,505511
1
$begingroup$
A diamond wall can be simply burnt. And no nanites will help this.
$endgroup$
– Gangnus
Dec 3 '18 at 22:49
$begingroup$
Transparent metals are very real. And having nanites maintain the wall would help it keep all the properties you want it to have.
$endgroup$
– Arvex
Dec 3 '18 at 23:00
1
$begingroup$
@Arvex not in pure form they are not. The closest Ifound was Aluminium oxynitride, ceramic that is marketed as transparent aluminum. And nanites to repair ceramics or aluminum are not even close to being real... Sadly.
$endgroup$
– Mołot
Dec 3 '18 at 23:12
$begingroup$
you could break down a diamond wall with sledgehammer, hard is not the same thing as strong.
$endgroup$
– John
Dec 4 '18 at 20:31
add a comment |
1
$begingroup$
A diamond wall can be simply burnt. And no nanites will help this.
$endgroup$
– Gangnus
Dec 3 '18 at 22:49
$begingroup$
Transparent metals are very real. And having nanites maintain the wall would help it keep all the properties you want it to have.
$endgroup$
– Arvex
Dec 3 '18 at 23:00
1
$begingroup$
@Arvex not in pure form they are not. The closest Ifound was Aluminium oxynitride, ceramic that is marketed as transparent aluminum. And nanites to repair ceramics or aluminum are not even close to being real... Sadly.
$endgroup$
– Mołot
Dec 3 '18 at 23:12
$begingroup$
you could break down a diamond wall with sledgehammer, hard is not the same thing as strong.
$endgroup$
– John
Dec 4 '18 at 20:31
1
1
$begingroup$
A diamond wall can be simply burnt. And no nanites will help this.
$endgroup$
– Gangnus
Dec 3 '18 at 22:49
$begingroup$
A diamond wall can be simply burnt. And no nanites will help this.
$endgroup$
– Gangnus
Dec 3 '18 at 22:49
$begingroup$
Transparent metals are very real. And having nanites maintain the wall would help it keep all the properties you want it to have.
$endgroup$
– Arvex
Dec 3 '18 at 23:00
$begingroup$
Transparent metals are very real. And having nanites maintain the wall would help it keep all the properties you want it to have.
$endgroup$
– Arvex
Dec 3 '18 at 23:00
1
1
$begingroup$
@Arvex not in pure form they are not. The closest Ifound was Aluminium oxynitride, ceramic that is marketed as transparent aluminum. And nanites to repair ceramics or aluminum are not even close to being real... Sadly.
$endgroup$
– Mołot
Dec 3 '18 at 23:12
$begingroup$
@Arvex not in pure form they are not. The closest Ifound was Aluminium oxynitride, ceramic that is marketed as transparent aluminum. And nanites to repair ceramics or aluminum are not even close to being real... Sadly.
$endgroup$
– Mołot
Dec 3 '18 at 23:12
$begingroup$
you could break down a diamond wall with sledgehammer, hard is not the same thing as strong.
$endgroup$
– John
Dec 4 '18 at 20:31
$begingroup$
you could break down a diamond wall with sledgehammer, hard is not the same thing as strong.
$endgroup$
– John
Dec 4 '18 at 20:31
add a comment |
$begingroup$
The closest idea I can come up with is sapphire (or other transparent ceramics. It can be clear if made that way, it is a 9 on the hardness scale so unless you scratch a diamond across it it would be very hard to leave marks on, and when properly mixed with other substances during creation things like it can be used in bullet proof windows for armored vehicles (see Aluminum oxynitride which is like sapphire with extra bits).
This coupled with an absurdly high melting point should make it more or less indestructible to medeval civilizations. If you make it thick enough to support being tall enough that nothing goes over it (say ballpark 10m thick at the base with a gentle taper up to 100m) at ground level you may be able to mar it but it is naturally resistant enough that it is doubtful people would be able to seriously damage it without a lot of time, effort, and explosives
though I'll be honest I am not sure the compression strength of sapphire is high enough to support such a tall and dense structure. Maybe have hollow portions higher up to get rid of some of the weight or have opaque materials at regular intervals for supports
To ease the completely unbreakable portion of your description since you are talking about a relic of an advanced civilization it could be that the wall has a method of self repair like a gene tailored bacteria or nanobots that refill any cracks, scratches, etc that might occur.
$endgroup$
$begingroup$
surmet.com/pdfs/news-and-media/…, of course the wall doesn't need to be monolithic, compressed ions, epj-pv.org/articles/epjpv/pdf/2015/01/pv140017.pdf & other materials may be included to enhance structural properties. Traditional transparency may not be optimal, but rather a mesh or 'active camoflage' system outfacing on otherwise more structurally reliable material.
$endgroup$
– Giu Piete
Dec 4 '18 at 5:33
$begingroup$
Also rather than repairing damaged surfaces it might be better to have them decompose and be replaced internally to a (macro)mechanical structure in films with pressure applied to expand the outer layers to maintain dimensions.
$endgroup$
– Giu Piete
Dec 4 '18 at 5:35
1
$begingroup$
Compression strength is intimately tied to hardness. Sapphire has a compressive strength of 2000 MPa (cf concrete 20-40 MPa).
$endgroup$
– Martin Bonner
Dec 4 '18 at 9:41
3
$begingroup$
You'd want a wall higher than 100m. The Great Pyramid was originally about 150m tall. The Romans built a siege ramp about 60m up the side of Masada - and that was under fire, only a 1:10 slope, and wide enough to push a siege engine up.
$endgroup$
– Martin Bonner
Dec 4 '18 at 9:48
$begingroup$
Sapphire crystal watches still get scratches. Not easily, but it is a problem noticeable in one lifetime, so over thousands of years it will get opaque. Plus, it chips. Relatively low impact resistance.
$endgroup$
– Mołot
Dec 4 '18 at 12:09
|
show 2 more comments
$begingroup$
The closest idea I can come up with is sapphire (or other transparent ceramics. It can be clear if made that way, it is a 9 on the hardness scale so unless you scratch a diamond across it it would be very hard to leave marks on, and when properly mixed with other substances during creation things like it can be used in bullet proof windows for armored vehicles (see Aluminum oxynitride which is like sapphire with extra bits).
This coupled with an absurdly high melting point should make it more or less indestructible to medeval civilizations. If you make it thick enough to support being tall enough that nothing goes over it (say ballpark 10m thick at the base with a gentle taper up to 100m) at ground level you may be able to mar it but it is naturally resistant enough that it is doubtful people would be able to seriously damage it without a lot of time, effort, and explosives
though I'll be honest I am not sure the compression strength of sapphire is high enough to support such a tall and dense structure. Maybe have hollow portions higher up to get rid of some of the weight or have opaque materials at regular intervals for supports
To ease the completely unbreakable portion of your description since you are talking about a relic of an advanced civilization it could be that the wall has a method of self repair like a gene tailored bacteria or nanobots that refill any cracks, scratches, etc that might occur.
$endgroup$
$begingroup$
surmet.com/pdfs/news-and-media/…, of course the wall doesn't need to be monolithic, compressed ions, epj-pv.org/articles/epjpv/pdf/2015/01/pv140017.pdf & other materials may be included to enhance structural properties. Traditional transparency may not be optimal, but rather a mesh or 'active camoflage' system outfacing on otherwise more structurally reliable material.
$endgroup$
– Giu Piete
Dec 4 '18 at 5:33
$begingroup$
Also rather than repairing damaged surfaces it might be better to have them decompose and be replaced internally to a (macro)mechanical structure in films with pressure applied to expand the outer layers to maintain dimensions.
$endgroup$
– Giu Piete
Dec 4 '18 at 5:35
1
$begingroup$
Compression strength is intimately tied to hardness. Sapphire has a compressive strength of 2000 MPa (cf concrete 20-40 MPa).
$endgroup$
– Martin Bonner
Dec 4 '18 at 9:41
3
$begingroup$
You'd want a wall higher than 100m. The Great Pyramid was originally about 150m tall. The Romans built a siege ramp about 60m up the side of Masada - and that was under fire, only a 1:10 slope, and wide enough to push a siege engine up.
$endgroup$
– Martin Bonner
Dec 4 '18 at 9:48
$begingroup$
Sapphire crystal watches still get scratches. Not easily, but it is a problem noticeable in one lifetime, so over thousands of years it will get opaque. Plus, it chips. Relatively low impact resistance.
$endgroup$
– Mołot
Dec 4 '18 at 12:09
|
show 2 more comments
$begingroup$
The closest idea I can come up with is sapphire (or other transparent ceramics. It can be clear if made that way, it is a 9 on the hardness scale so unless you scratch a diamond across it it would be very hard to leave marks on, and when properly mixed with other substances during creation things like it can be used in bullet proof windows for armored vehicles (see Aluminum oxynitride which is like sapphire with extra bits).
This coupled with an absurdly high melting point should make it more or less indestructible to medeval civilizations. If you make it thick enough to support being tall enough that nothing goes over it (say ballpark 10m thick at the base with a gentle taper up to 100m) at ground level you may be able to mar it but it is naturally resistant enough that it is doubtful people would be able to seriously damage it without a lot of time, effort, and explosives
though I'll be honest I am not sure the compression strength of sapphire is high enough to support such a tall and dense structure. Maybe have hollow portions higher up to get rid of some of the weight or have opaque materials at regular intervals for supports
To ease the completely unbreakable portion of your description since you are talking about a relic of an advanced civilization it could be that the wall has a method of self repair like a gene tailored bacteria or nanobots that refill any cracks, scratches, etc that might occur.
$endgroup$
The closest idea I can come up with is sapphire (or other transparent ceramics. It can be clear if made that way, it is a 9 on the hardness scale so unless you scratch a diamond across it it would be very hard to leave marks on, and when properly mixed with other substances during creation things like it can be used in bullet proof windows for armored vehicles (see Aluminum oxynitride which is like sapphire with extra bits).
This coupled with an absurdly high melting point should make it more or less indestructible to medeval civilizations. If you make it thick enough to support being tall enough that nothing goes over it (say ballpark 10m thick at the base with a gentle taper up to 100m) at ground level you may be able to mar it but it is naturally resistant enough that it is doubtful people would be able to seriously damage it without a lot of time, effort, and explosives
though I'll be honest I am not sure the compression strength of sapphire is high enough to support such a tall and dense structure. Maybe have hollow portions higher up to get rid of some of the weight or have opaque materials at regular intervals for supports
To ease the completely unbreakable portion of your description since you are talking about a relic of an advanced civilization it could be that the wall has a method of self repair like a gene tailored bacteria or nanobots that refill any cracks, scratches, etc that might occur.
answered Dec 4 '18 at 4:02
SilverShadowSilverShadow
751211
751211
$begingroup$
surmet.com/pdfs/news-and-media/…, of course the wall doesn't need to be monolithic, compressed ions, epj-pv.org/articles/epjpv/pdf/2015/01/pv140017.pdf & other materials may be included to enhance structural properties. Traditional transparency may not be optimal, but rather a mesh or 'active camoflage' system outfacing on otherwise more structurally reliable material.
$endgroup$
– Giu Piete
Dec 4 '18 at 5:33
$begingroup$
Also rather than repairing damaged surfaces it might be better to have them decompose and be replaced internally to a (macro)mechanical structure in films with pressure applied to expand the outer layers to maintain dimensions.
$endgroup$
– Giu Piete
Dec 4 '18 at 5:35
1
$begingroup$
Compression strength is intimately tied to hardness. Sapphire has a compressive strength of 2000 MPa (cf concrete 20-40 MPa).
$endgroup$
– Martin Bonner
Dec 4 '18 at 9:41
3
$begingroup$
You'd want a wall higher than 100m. The Great Pyramid was originally about 150m tall. The Romans built a siege ramp about 60m up the side of Masada - and that was under fire, only a 1:10 slope, and wide enough to push a siege engine up.
$endgroup$
– Martin Bonner
Dec 4 '18 at 9:48
$begingroup$
Sapphire crystal watches still get scratches. Not easily, but it is a problem noticeable in one lifetime, so over thousands of years it will get opaque. Plus, it chips. Relatively low impact resistance.
$endgroup$
– Mołot
Dec 4 '18 at 12:09
|
show 2 more comments
$begingroup$
surmet.com/pdfs/news-and-media/…, of course the wall doesn't need to be monolithic, compressed ions, epj-pv.org/articles/epjpv/pdf/2015/01/pv140017.pdf & other materials may be included to enhance structural properties. Traditional transparency may not be optimal, but rather a mesh or 'active camoflage' system outfacing on otherwise more structurally reliable material.
$endgroup$
– Giu Piete
Dec 4 '18 at 5:33
$begingroup$
Also rather than repairing damaged surfaces it might be better to have them decompose and be replaced internally to a (macro)mechanical structure in films with pressure applied to expand the outer layers to maintain dimensions.
$endgroup$
– Giu Piete
Dec 4 '18 at 5:35
1
$begingroup$
Compression strength is intimately tied to hardness. Sapphire has a compressive strength of 2000 MPa (cf concrete 20-40 MPa).
$endgroup$
– Martin Bonner
Dec 4 '18 at 9:41
3
$begingroup$
You'd want a wall higher than 100m. The Great Pyramid was originally about 150m tall. The Romans built a siege ramp about 60m up the side of Masada - and that was under fire, only a 1:10 slope, and wide enough to push a siege engine up.
$endgroup$
– Martin Bonner
Dec 4 '18 at 9:48
$begingroup$
Sapphire crystal watches still get scratches. Not easily, but it is a problem noticeable in one lifetime, so over thousands of years it will get opaque. Plus, it chips. Relatively low impact resistance.
$endgroup$
– Mołot
Dec 4 '18 at 12:09
$begingroup$
surmet.com/pdfs/news-and-media/…, of course the wall doesn't need to be monolithic, compressed ions, epj-pv.org/articles/epjpv/pdf/2015/01/pv140017.pdf & other materials may be included to enhance structural properties. Traditional transparency may not be optimal, but rather a mesh or 'active camoflage' system outfacing on otherwise more structurally reliable material.
$endgroup$
– Giu Piete
Dec 4 '18 at 5:33
$begingroup$
surmet.com/pdfs/news-and-media/…, of course the wall doesn't need to be monolithic, compressed ions, epj-pv.org/articles/epjpv/pdf/2015/01/pv140017.pdf & other materials may be included to enhance structural properties. Traditional transparency may not be optimal, but rather a mesh or 'active camoflage' system outfacing on otherwise more structurally reliable material.
$endgroup$
– Giu Piete
Dec 4 '18 at 5:33
$begingroup$
Also rather than repairing damaged surfaces it might be better to have them decompose and be replaced internally to a (macro)mechanical structure in films with pressure applied to expand the outer layers to maintain dimensions.
$endgroup$
– Giu Piete
Dec 4 '18 at 5:35
$begingroup$
Also rather than repairing damaged surfaces it might be better to have them decompose and be replaced internally to a (macro)mechanical structure in films with pressure applied to expand the outer layers to maintain dimensions.
$endgroup$
– Giu Piete
Dec 4 '18 at 5:35
1
1
$begingroup$
Compression strength is intimately tied to hardness. Sapphire has a compressive strength of 2000 MPa (cf concrete 20-40 MPa).
$endgroup$
– Martin Bonner
Dec 4 '18 at 9:41
$begingroup$
Compression strength is intimately tied to hardness. Sapphire has a compressive strength of 2000 MPa (cf concrete 20-40 MPa).
$endgroup$
– Martin Bonner
Dec 4 '18 at 9:41
3
3
$begingroup$
You'd want a wall higher than 100m. The Great Pyramid was originally about 150m tall. The Romans built a siege ramp about 60m up the side of Masada - and that was under fire, only a 1:10 slope, and wide enough to push a siege engine up.
$endgroup$
– Martin Bonner
Dec 4 '18 at 9:48
$begingroup$
You'd want a wall higher than 100m. The Great Pyramid was originally about 150m tall. The Romans built a siege ramp about 60m up the side of Masada - and that was under fire, only a 1:10 slope, and wide enough to push a siege engine up.
$endgroup$
– Martin Bonner
Dec 4 '18 at 9:48
$begingroup$
Sapphire crystal watches still get scratches. Not easily, but it is a problem noticeable in one lifetime, so over thousands of years it will get opaque. Plus, it chips. Relatively low impact resistance.
$endgroup$
– Mołot
Dec 4 '18 at 12:09
$begingroup$
Sapphire crystal watches still get scratches. Not easily, but it is a problem noticeable in one lifetime, so over thousands of years it will get opaque. Plus, it chips. Relatively low impact resistance.
$endgroup$
– Mołot
Dec 4 '18 at 12:09
|
show 2 more comments
$begingroup$
Time/Space Sheer field
This section of reality is sheered in such a way that the time/space location on the other side is completely different. Even if the two medieval civilisations circumnavigated those mountains, they would only perceive the field from the opposite direction.
The sheering permits photons (massless objects) through but seriously twists, deforms, and even repels mass that reaches a certain point. It would also explain why sound cannot penetrate. The internals of this wall are effectively a vacuum.
As for the power requirements, a civilisation that has time/space sheering knowledge to the ability of this wall, could easily transmit power through a much smaller time/space shear from some astronomical power source such as a neutron star/black hole/etc...
$endgroup$
add a comment |
$begingroup$
Time/Space Sheer field
This section of reality is sheered in such a way that the time/space location on the other side is completely different. Even if the two medieval civilisations circumnavigated those mountains, they would only perceive the field from the opposite direction.
The sheering permits photons (massless objects) through but seriously twists, deforms, and even repels mass that reaches a certain point. It would also explain why sound cannot penetrate. The internals of this wall are effectively a vacuum.
As for the power requirements, a civilisation that has time/space sheering knowledge to the ability of this wall, could easily transmit power through a much smaller time/space shear from some astronomical power source such as a neutron star/black hole/etc...
$endgroup$
add a comment |
$begingroup$
Time/Space Sheer field
This section of reality is sheered in such a way that the time/space location on the other side is completely different. Even if the two medieval civilisations circumnavigated those mountains, they would only perceive the field from the opposite direction.
The sheering permits photons (massless objects) through but seriously twists, deforms, and even repels mass that reaches a certain point. It would also explain why sound cannot penetrate. The internals of this wall are effectively a vacuum.
As for the power requirements, a civilisation that has time/space sheering knowledge to the ability of this wall, could easily transmit power through a much smaller time/space shear from some astronomical power source such as a neutron star/black hole/etc...
$endgroup$
Time/Space Sheer field
This section of reality is sheered in such a way that the time/space location on the other side is completely different. Even if the two medieval civilisations circumnavigated those mountains, they would only perceive the field from the opposite direction.
The sheering permits photons (massless objects) through but seriously twists, deforms, and even repels mass that reaches a certain point. It would also explain why sound cannot penetrate. The internals of this wall are effectively a vacuum.
As for the power requirements, a civilisation that has time/space sheering knowledge to the ability of this wall, could easily transmit power through a much smaller time/space shear from some astronomical power source such as a neutron star/black hole/etc...
edited Dec 4 '18 at 17:21
Necreaux
1054
1054
answered Dec 4 '18 at 5:04
Kain0_0Kain0_0
1,3606
1,3606
add a comment |
add a comment |
$begingroup$
You need a secondary structure, a primary one, and transparent cladding
Modern day skyscrapers are often clad in glass, to form full height glass 'walls'.
This is achieved with what is called a 'curtain walling system'. It is essentially a primary structure, with a secondary structure attached that supports smaller glazed panels. This enables the following advantages:
- The wall is not supported by glass, but instead a protected robust structure behind it.
- The wall is partially flexible, wind loads could slightly bend the wall as the glass is segmented. The secondary structure under could cater for deflection, while the primary structure caters for the main static load.
- The glass could be as thick, strong or rigid as needed, just being accommodated with a thick structure as needed behind it.
- The structure behind can be a truss-like structure, using lightweight steel elements (much like high voltage towers), in particular if you do not require the wall to be habitable. The interior structure has the added advantage that it is protected from weather.
- The primary structure being protected could be large concrete columns, or thick steel columns, as large as is necessary
- The glass could be replaced individually from behind if any damage occurs, some systems have internal fixing frames intended for interior access in case exterior access is not possible.
An example architectural detail of a framed curtain wall:
An example of an alternate frameless, spider joint supported detail, with a secondary structure (primary not shown):
There is theoretically no limit to the height of these structures (as is exemplified in our tall buildings today), with greater size only requiring greater structure behind depending on wind load. Thickness can be increased for longevity if needed, and if there are no economic considerations, increased at whim to last centuries (a lot of existing curtain walling systems have been in existence for a long time with little to no maintenance).
$endgroup$
$begingroup$
Glass isn't durable enough. A few thousand years of wind-blown sand, and you'll get a cloudy surface that barely passes light. There are also little problems like boulders and battering rams.
$endgroup$
– Mark
Dec 5 '18 at 2:42
add a comment |
$begingroup$
You need a secondary structure, a primary one, and transparent cladding
Modern day skyscrapers are often clad in glass, to form full height glass 'walls'.
This is achieved with what is called a 'curtain walling system'. It is essentially a primary structure, with a secondary structure attached that supports smaller glazed panels. This enables the following advantages:
- The wall is not supported by glass, but instead a protected robust structure behind it.
- The wall is partially flexible, wind loads could slightly bend the wall as the glass is segmented. The secondary structure under could cater for deflection, while the primary structure caters for the main static load.
- The glass could be as thick, strong or rigid as needed, just being accommodated with a thick structure as needed behind it.
- The structure behind can be a truss-like structure, using lightweight steel elements (much like high voltage towers), in particular if you do not require the wall to be habitable. The interior structure has the added advantage that it is protected from weather.
- The primary structure being protected could be large concrete columns, or thick steel columns, as large as is necessary
- The glass could be replaced individually from behind if any damage occurs, some systems have internal fixing frames intended for interior access in case exterior access is not possible.
An example architectural detail of a framed curtain wall:
An example of an alternate frameless, spider joint supported detail, with a secondary structure (primary not shown):
There is theoretically no limit to the height of these structures (as is exemplified in our tall buildings today), with greater size only requiring greater structure behind depending on wind load. Thickness can be increased for longevity if needed, and if there are no economic considerations, increased at whim to last centuries (a lot of existing curtain walling systems have been in existence for a long time with little to no maintenance).
$endgroup$
$begingroup$
Glass isn't durable enough. A few thousand years of wind-blown sand, and you'll get a cloudy surface that barely passes light. There are also little problems like boulders and battering rams.
$endgroup$
– Mark
Dec 5 '18 at 2:42
add a comment |
$begingroup$
You need a secondary structure, a primary one, and transparent cladding
Modern day skyscrapers are often clad in glass, to form full height glass 'walls'.
This is achieved with what is called a 'curtain walling system'. It is essentially a primary structure, with a secondary structure attached that supports smaller glazed panels. This enables the following advantages:
- The wall is not supported by glass, but instead a protected robust structure behind it.
- The wall is partially flexible, wind loads could slightly bend the wall as the glass is segmented. The secondary structure under could cater for deflection, while the primary structure caters for the main static load.
- The glass could be as thick, strong or rigid as needed, just being accommodated with a thick structure as needed behind it.
- The structure behind can be a truss-like structure, using lightweight steel elements (much like high voltage towers), in particular if you do not require the wall to be habitable. The interior structure has the added advantage that it is protected from weather.
- The primary structure being protected could be large concrete columns, or thick steel columns, as large as is necessary
- The glass could be replaced individually from behind if any damage occurs, some systems have internal fixing frames intended for interior access in case exterior access is not possible.
An example architectural detail of a framed curtain wall:
An example of an alternate frameless, spider joint supported detail, with a secondary structure (primary not shown):
There is theoretically no limit to the height of these structures (as is exemplified in our tall buildings today), with greater size only requiring greater structure behind depending on wind load. Thickness can be increased for longevity if needed, and if there are no economic considerations, increased at whim to last centuries (a lot of existing curtain walling systems have been in existence for a long time with little to no maintenance).
$endgroup$
You need a secondary structure, a primary one, and transparent cladding
Modern day skyscrapers are often clad in glass, to form full height glass 'walls'.
This is achieved with what is called a 'curtain walling system'. It is essentially a primary structure, with a secondary structure attached that supports smaller glazed panels. This enables the following advantages:
- The wall is not supported by glass, but instead a protected robust structure behind it.
- The wall is partially flexible, wind loads could slightly bend the wall as the glass is segmented. The secondary structure under could cater for deflection, while the primary structure caters for the main static load.
- The glass could be as thick, strong or rigid as needed, just being accommodated with a thick structure as needed behind it.
- The structure behind can be a truss-like structure, using lightweight steel elements (much like high voltage towers), in particular if you do not require the wall to be habitable. The interior structure has the added advantage that it is protected from weather.
- The primary structure being protected could be large concrete columns, or thick steel columns, as large as is necessary
- The glass could be replaced individually from behind if any damage occurs, some systems have internal fixing frames intended for interior access in case exterior access is not possible.
An example architectural detail of a framed curtain wall:
An example of an alternate frameless, spider joint supported detail, with a secondary structure (primary not shown):
There is theoretically no limit to the height of these structures (as is exemplified in our tall buildings today), with greater size only requiring greater structure behind depending on wind load. Thickness can be increased for longevity if needed, and if there are no economic considerations, increased at whim to last centuries (a lot of existing curtain walling systems have been in existence for a long time with little to no maintenance).
answered Dec 4 '18 at 15:30
floxflox
7,689726
7,689726
$begingroup$
Glass isn't durable enough. A few thousand years of wind-blown sand, and you'll get a cloudy surface that barely passes light. There are also little problems like boulders and battering rams.
$endgroup$
– Mark
Dec 5 '18 at 2:42
add a comment |
$begingroup$
Glass isn't durable enough. A few thousand years of wind-blown sand, and you'll get a cloudy surface that barely passes light. There are also little problems like boulders and battering rams.
$endgroup$
– Mark
Dec 5 '18 at 2:42
$begingroup$
Glass isn't durable enough. A few thousand years of wind-blown sand, and you'll get a cloudy surface that barely passes light. There are also little problems like boulders and battering rams.
$endgroup$
– Mark
Dec 5 '18 at 2:42
$begingroup$
Glass isn't durable enough. A few thousand years of wind-blown sand, and you'll get a cloudy surface that barely passes light. There are also little problems like boulders and battering rams.
$endgroup$
– Mark
Dec 5 '18 at 2:42
add a comment |
$begingroup$
Wind, so the material is air. Natural wind is funneled by a gargantouesque ravine reaching far away and creating the effect you describe. If ever the wind decreases to much (after some extraodinary event) the walls heat and natural fournaces below come into action in contact with water projecting streams of vapor. Water below might also be a carved system of water streams and tanks.
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Ingenious. It could even be part of the ancient civilisation's air-conditioning system!
$endgroup$
– chasly from UK
Dec 4 '18 at 17:12
add a comment |
$begingroup$
Wind, so the material is air. Natural wind is funneled by a gargantouesque ravine reaching far away and creating the effect you describe. If ever the wind decreases to much (after some extraodinary event) the walls heat and natural fournaces below come into action in contact with water projecting streams of vapor. Water below might also be a carved system of water streams and tanks.
$endgroup$
$begingroup$
Ingenious. It could even be part of the ancient civilisation's air-conditioning system!
$endgroup$
– chasly from UK
Dec 4 '18 at 17:12
add a comment |
$begingroup$
Wind, so the material is air. Natural wind is funneled by a gargantouesque ravine reaching far away and creating the effect you describe. If ever the wind decreases to much (after some extraodinary event) the walls heat and natural fournaces below come into action in contact with water projecting streams of vapor. Water below might also be a carved system of water streams and tanks.
$endgroup$
Wind, so the material is air. Natural wind is funneled by a gargantouesque ravine reaching far away and creating the effect you describe. If ever the wind decreases to much (after some extraodinary event) the walls heat and natural fournaces below come into action in contact with water projecting streams of vapor. Water below might also be a carved system of water streams and tanks.
answered Dec 4 '18 at 17:07
TomásTomás
3179
3179
$begingroup$
Ingenious. It could even be part of the ancient civilisation's air-conditioning system!
$endgroup$
– chasly from UK
Dec 4 '18 at 17:12
add a comment |
$begingroup$
Ingenious. It could even be part of the ancient civilisation's air-conditioning system!
$endgroup$
– chasly from UK
Dec 4 '18 at 17:12
$begingroup$
Ingenious. It could even be part of the ancient civilisation's air-conditioning system!
$endgroup$
– chasly from UK
Dec 4 '18 at 17:12
$begingroup$
Ingenious. It could even be part of the ancient civilisation's air-conditioning system!
$endgroup$
– chasly from UK
Dec 4 '18 at 17:12
add a comment |
$begingroup$
Rock crystal
(Quartz) has the lowest potential for weathering and consequently it is very common as a residual mineral found in veins within sandstone which could have weathered each side , at the head of a mountain pass the rain would wash the sandstone down each side of this cleft between phenomenally steep valley sides thus there are no holes through or around it..
Could be top heavy crystalline the higher it gets since the ancients were mining in from each side, but for whatever reason the hardest transparent core had not been finished and past attempts to climb or dig at it have resulted in shards falling from above, keeping later attempts at bay due to the gods displeasure ?
$endgroup$
add a comment |
$begingroup$
Rock crystal
(Quartz) has the lowest potential for weathering and consequently it is very common as a residual mineral found in veins within sandstone which could have weathered each side , at the head of a mountain pass the rain would wash the sandstone down each side of this cleft between phenomenally steep valley sides thus there are no holes through or around it..
Could be top heavy crystalline the higher it gets since the ancients were mining in from each side, but for whatever reason the hardest transparent core had not been finished and past attempts to climb or dig at it have resulted in shards falling from above, keeping later attempts at bay due to the gods displeasure ?
$endgroup$
add a comment |
$begingroup$
Rock crystal
(Quartz) has the lowest potential for weathering and consequently it is very common as a residual mineral found in veins within sandstone which could have weathered each side , at the head of a mountain pass the rain would wash the sandstone down each side of this cleft between phenomenally steep valley sides thus there are no holes through or around it..
Could be top heavy crystalline the higher it gets since the ancients were mining in from each side, but for whatever reason the hardest transparent core had not been finished and past attempts to climb or dig at it have resulted in shards falling from above, keeping later attempts at bay due to the gods displeasure ?
$endgroup$
Rock crystal
(Quartz) has the lowest potential for weathering and consequently it is very common as a residual mineral found in veins within sandstone which could have weathered each side , at the head of a mountain pass the rain would wash the sandstone down each side of this cleft between phenomenally steep valley sides thus there are no holes through or around it..
Could be top heavy crystalline the higher it gets since the ancients were mining in from each side, but for whatever reason the hardest transparent core had not been finished and past attempts to climb or dig at it have resulted in shards falling from above, keeping later attempts at bay due to the gods displeasure ?
edited Dec 4 '18 at 17:21
answered Dec 4 '18 at 14:45
KJOKJO
2313
2313
add a comment |
add a comment |
$begingroup$
There's a different problem here.
You have the wall being impossibly high, ridiculously long, impervious to damage, impervious to sound, and perfectly clear. Okay. Let's just take that as given for now.
You say that it's a place where people come for tourism, to communicate via sign language, and (for smallish children) to throw rocks at it. Fine. Then you say that it's across a pass in a mountain range, where the storms are bad enough that no one has ever managed to get over the thing (and also there are terrible beasts). That's a problem. In particular, no one would go there. A pass that's that treacherous is the sort of thing that people only climb to with strong reason, and "gawk at the folks who can be seen but not heard and not touched" isn't a strong reason - especially not since they'll have the same sort of pass on their side, so most days they won't be showing up either.
If you want people to actually interact with this thing more than about once a generation, and if you want them to have any contact with one another through the wall at all, you need to make it reasonably accessible.
If you do that, one of the things you will see, I suspect, is architecture. Having an impossibly tall, smooth wall that won't fall over no matter how much weight you put against it is potentially really useful from an architectural standpoint. The opportunity to leave the glass wall side of your building open, and thus to do socially shocking things where you know that people can see, but they can't possibly inform anyone you care about is just bonus. (Walking about without a hat? Scandalous!)
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$begingroup$
Good points - I'm beginning to realise I should have attempted some kind of diagram. In my imagination the pass was artificially cut through the mountains and reaches down to the plain. The heights have the blizzards and the terrible beasts. That explains why no-one tries to bypass the barrier by climbing up and around it. I'll make a diagram at some point but I'll put it in my own answer so as not to invalidate anyone else's. At some point the hero may discover the secret and be able to open the barrier which may slide back.
$endgroup$
– chasly from UK
Dec 6 '18 at 11:22
add a comment |
$begingroup$
There's a different problem here.
You have the wall being impossibly high, ridiculously long, impervious to damage, impervious to sound, and perfectly clear. Okay. Let's just take that as given for now.
You say that it's a place where people come for tourism, to communicate via sign language, and (for smallish children) to throw rocks at it. Fine. Then you say that it's across a pass in a mountain range, where the storms are bad enough that no one has ever managed to get over the thing (and also there are terrible beasts). That's a problem. In particular, no one would go there. A pass that's that treacherous is the sort of thing that people only climb to with strong reason, and "gawk at the folks who can be seen but not heard and not touched" isn't a strong reason - especially not since they'll have the same sort of pass on their side, so most days they won't be showing up either.
If you want people to actually interact with this thing more than about once a generation, and if you want them to have any contact with one another through the wall at all, you need to make it reasonably accessible.
If you do that, one of the things you will see, I suspect, is architecture. Having an impossibly tall, smooth wall that won't fall over no matter how much weight you put against it is potentially really useful from an architectural standpoint. The opportunity to leave the glass wall side of your building open, and thus to do socially shocking things where you know that people can see, but they can't possibly inform anyone you care about is just bonus. (Walking about without a hat? Scandalous!)
$endgroup$
$begingroup$
Good points - I'm beginning to realise I should have attempted some kind of diagram. In my imagination the pass was artificially cut through the mountains and reaches down to the plain. The heights have the blizzards and the terrible beasts. That explains why no-one tries to bypass the barrier by climbing up and around it. I'll make a diagram at some point but I'll put it in my own answer so as not to invalidate anyone else's. At some point the hero may discover the secret and be able to open the barrier which may slide back.
$endgroup$
– chasly from UK
Dec 6 '18 at 11:22
add a comment |
$begingroup$
There's a different problem here.
You have the wall being impossibly high, ridiculously long, impervious to damage, impervious to sound, and perfectly clear. Okay. Let's just take that as given for now.
You say that it's a place where people come for tourism, to communicate via sign language, and (for smallish children) to throw rocks at it. Fine. Then you say that it's across a pass in a mountain range, where the storms are bad enough that no one has ever managed to get over the thing (and also there are terrible beasts). That's a problem. In particular, no one would go there. A pass that's that treacherous is the sort of thing that people only climb to with strong reason, and "gawk at the folks who can be seen but not heard and not touched" isn't a strong reason - especially not since they'll have the same sort of pass on their side, so most days they won't be showing up either.
If you want people to actually interact with this thing more than about once a generation, and if you want them to have any contact with one another through the wall at all, you need to make it reasonably accessible.
If you do that, one of the things you will see, I suspect, is architecture. Having an impossibly tall, smooth wall that won't fall over no matter how much weight you put against it is potentially really useful from an architectural standpoint. The opportunity to leave the glass wall side of your building open, and thus to do socially shocking things where you know that people can see, but they can't possibly inform anyone you care about is just bonus. (Walking about without a hat? Scandalous!)
$endgroup$
There's a different problem here.
You have the wall being impossibly high, ridiculously long, impervious to damage, impervious to sound, and perfectly clear. Okay. Let's just take that as given for now.
You say that it's a place where people come for tourism, to communicate via sign language, and (for smallish children) to throw rocks at it. Fine. Then you say that it's across a pass in a mountain range, where the storms are bad enough that no one has ever managed to get over the thing (and also there are terrible beasts). That's a problem. In particular, no one would go there. A pass that's that treacherous is the sort of thing that people only climb to with strong reason, and "gawk at the folks who can be seen but not heard and not touched" isn't a strong reason - especially not since they'll have the same sort of pass on their side, so most days they won't be showing up either.
If you want people to actually interact with this thing more than about once a generation, and if you want them to have any contact with one another through the wall at all, you need to make it reasonably accessible.
If you do that, one of the things you will see, I suspect, is architecture. Having an impossibly tall, smooth wall that won't fall over no matter how much weight you put against it is potentially really useful from an architectural standpoint. The opportunity to leave the glass wall side of your building open, and thus to do socially shocking things where you know that people can see, but they can't possibly inform anyone you care about is just bonus. (Walking about without a hat? Scandalous!)
answered Dec 4 '18 at 17:39
Ben BardenBen Barden
1,01047
1,01047
$begingroup$
Good points - I'm beginning to realise I should have attempted some kind of diagram. In my imagination the pass was artificially cut through the mountains and reaches down to the plain. The heights have the blizzards and the terrible beasts. That explains why no-one tries to bypass the barrier by climbing up and around it. I'll make a diagram at some point but I'll put it in my own answer so as not to invalidate anyone else's. At some point the hero may discover the secret and be able to open the barrier which may slide back.
$endgroup$
– chasly from UK
Dec 6 '18 at 11:22
add a comment |
$begingroup$
Good points - I'm beginning to realise I should have attempted some kind of diagram. In my imagination the pass was artificially cut through the mountains and reaches down to the plain. The heights have the blizzards and the terrible beasts. That explains why no-one tries to bypass the barrier by climbing up and around it. I'll make a diagram at some point but I'll put it in my own answer so as not to invalidate anyone else's. At some point the hero may discover the secret and be able to open the barrier which may slide back.
$endgroup$
– chasly from UK
Dec 6 '18 at 11:22
$begingroup$
Good points - I'm beginning to realise I should have attempted some kind of diagram. In my imagination the pass was artificially cut through the mountains and reaches down to the plain. The heights have the blizzards and the terrible beasts. That explains why no-one tries to bypass the barrier by climbing up and around it. I'll make a diagram at some point but I'll put it in my own answer so as not to invalidate anyone else's. At some point the hero may discover the secret and be able to open the barrier which may slide back.
$endgroup$
– chasly from UK
Dec 6 '18 at 11:22
$begingroup$
Good points - I'm beginning to realise I should have attempted some kind of diagram. In my imagination the pass was artificially cut through the mountains and reaches down to the plain. The heights have the blizzards and the terrible beasts. That explains why no-one tries to bypass the barrier by climbing up and around it. I'll make a diagram at some point but I'll put it in my own answer so as not to invalidate anyone else's. At some point the hero may discover the secret and be able to open the barrier which may slide back.
$endgroup$
– chasly from UK
Dec 6 '18 at 11:22
add a comment |
$begingroup$
I see a few comments related to "aluminum" and I recall from Star Trek, the concept of Transparent Aluminum and turns out, has been created. Further reading per the link suggests Iron can also be made transparent - see below:
https://en.wikipedia.org/wiki/List_of_Star_Trek_materials#Transparent_aluminum
Pure transparent aluminum was created as a new state of matter by a team of scientists in 2009. A laser pulse removed an electron from every atom without disrupting the crystalline structure. However, the transparent state lasted for only 40 femtoseconds, until electrons returned to the material.
A group of scientists led by Ralf Röhlsberger at Deutsches Elektronen-Synchrotron (DESY), Hamburg, Germany, succeeded in turning iron transparent during research in 2012 to create quantum computers.
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1
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Hello and welvome. Please, do not post purely fictional materials as an answer to science-based questions.
$endgroup$
– Mołot
Dec 4 '18 at 19:36
1
$begingroup$
Yes the idea for my post was inspired by fiction, but the link reference actual experiments where both Aluminum and Iron were made transparent!
$endgroup$
– flaZer
Dec 4 '18 at 19:38
add a comment |
$begingroup$
I see a few comments related to "aluminum" and I recall from Star Trek, the concept of Transparent Aluminum and turns out, has been created. Further reading per the link suggests Iron can also be made transparent - see below:
https://en.wikipedia.org/wiki/List_of_Star_Trek_materials#Transparent_aluminum
Pure transparent aluminum was created as a new state of matter by a team of scientists in 2009. A laser pulse removed an electron from every atom without disrupting the crystalline structure. However, the transparent state lasted for only 40 femtoseconds, until electrons returned to the material.
A group of scientists led by Ralf Röhlsberger at Deutsches Elektronen-Synchrotron (DESY), Hamburg, Germany, succeeded in turning iron transparent during research in 2012 to create quantum computers.
$endgroup$
1
$begingroup$
Hello and welvome. Please, do not post purely fictional materials as an answer to science-based questions.
$endgroup$
– Mołot
Dec 4 '18 at 19:36
1
$begingroup$
Yes the idea for my post was inspired by fiction, but the link reference actual experiments where both Aluminum and Iron were made transparent!
$endgroup$
– flaZer
Dec 4 '18 at 19:38
add a comment |
$begingroup$
I see a few comments related to "aluminum" and I recall from Star Trek, the concept of Transparent Aluminum and turns out, has been created. Further reading per the link suggests Iron can also be made transparent - see below:
https://en.wikipedia.org/wiki/List_of_Star_Trek_materials#Transparent_aluminum
Pure transparent aluminum was created as a new state of matter by a team of scientists in 2009. A laser pulse removed an electron from every atom without disrupting the crystalline structure. However, the transparent state lasted for only 40 femtoseconds, until electrons returned to the material.
A group of scientists led by Ralf Röhlsberger at Deutsches Elektronen-Synchrotron (DESY), Hamburg, Germany, succeeded in turning iron transparent during research in 2012 to create quantum computers.
$endgroup$
I see a few comments related to "aluminum" and I recall from Star Trek, the concept of Transparent Aluminum and turns out, has been created. Further reading per the link suggests Iron can also be made transparent - see below:
https://en.wikipedia.org/wiki/List_of_Star_Trek_materials#Transparent_aluminum
Pure transparent aluminum was created as a new state of matter by a team of scientists in 2009. A laser pulse removed an electron from every atom without disrupting the crystalline structure. However, the transparent state lasted for only 40 femtoseconds, until electrons returned to the material.
A group of scientists led by Ralf Röhlsberger at Deutsches Elektronen-Synchrotron (DESY), Hamburg, Germany, succeeded in turning iron transparent during research in 2012 to create quantum computers.
edited Dec 4 '18 at 19:36
answered Dec 4 '18 at 19:27
flaZerflaZer
3475
3475
1
$begingroup$
Hello and welvome. Please, do not post purely fictional materials as an answer to science-based questions.
$endgroup$
– Mołot
Dec 4 '18 at 19:36
1
$begingroup$
Yes the idea for my post was inspired by fiction, but the link reference actual experiments where both Aluminum and Iron were made transparent!
$endgroup$
– flaZer
Dec 4 '18 at 19:38
add a comment |
1
$begingroup$
Hello and welvome. Please, do not post purely fictional materials as an answer to science-based questions.
$endgroup$
– Mołot
Dec 4 '18 at 19:36
1
$begingroup$
Yes the idea for my post was inspired by fiction, but the link reference actual experiments where both Aluminum and Iron were made transparent!
$endgroup$
– flaZer
Dec 4 '18 at 19:38
1
1
$begingroup$
Hello and welvome. Please, do not post purely fictional materials as an answer to science-based questions.
$endgroup$
– Mołot
Dec 4 '18 at 19:36
$begingroup$
Hello and welvome. Please, do not post purely fictional materials as an answer to science-based questions.
$endgroup$
– Mołot
Dec 4 '18 at 19:36
1
1
$begingroup$
Yes the idea for my post was inspired by fiction, but the link reference actual experiments where both Aluminum and Iron were made transparent!
$endgroup$
– flaZer
Dec 4 '18 at 19:38
$begingroup$
Yes the idea for my post was inspired by fiction, but the link reference actual experiments where both Aluminum and Iron were made transparent!
$endgroup$
– flaZer
Dec 4 '18 at 19:38
add a comment |
$begingroup$
Vertical conveyor belt
I've been thinking about some of the objections and have come up with answer to my own question that might work.
Maybe it could even be made of thick glass. The wall could be blocking a tall narrow rectangular cut through the mountains - an artificial pass. The wall could be quite narrow (say enough for ten-abreast to pass through) and thus supported all the way up by a frame.
EDIT - Apologies - I should have made something clear when posing the question. In my imagination the pass is cut through the mountains by the aliens. It looks something like the following only much more smooth-sided and rectangular. The pictures are from the ancient site of Petra. https://en.wikipedia.org/wiki/Siq
https://upload.wikimedia.org/wikipedia/commons/thumb/e/e3/PS-Petra_6148.JPG/1200px-PS-Petra_6148.JPG
https://upload.wikimedia.org/wikipedia/commons/thumb/3/32/V%C3%A4gen_in.jpg/800px-V%C3%A4gen_in.jpg
The wall consists of sheet of material that slowly emerges from a slot at one side of the pass and eventually disappears into a slot on the other side. Behind the scenes, the material is melted and reformed after which it goes through another slot and back to the starting point where the same thing happens. Thus the wall is a kind of continuous vertical conveyor belt whose surface is always being renewed.
Problems
There would have to be a substantial cache (of sand in the case of glass) or other renewable source of wall-material to make up any losses from natural wear-and-tear.
An enormous power source would be required but I suppose it could be nuclear.
$endgroup$
add a comment |
$begingroup$
Vertical conveyor belt
I've been thinking about some of the objections and have come up with answer to my own question that might work.
Maybe it could even be made of thick glass. The wall could be blocking a tall narrow rectangular cut through the mountains - an artificial pass. The wall could be quite narrow (say enough for ten-abreast to pass through) and thus supported all the way up by a frame.
EDIT - Apologies - I should have made something clear when posing the question. In my imagination the pass is cut through the mountains by the aliens. It looks something like the following only much more smooth-sided and rectangular. The pictures are from the ancient site of Petra. https://en.wikipedia.org/wiki/Siq
https://upload.wikimedia.org/wikipedia/commons/thumb/e/e3/PS-Petra_6148.JPG/1200px-PS-Petra_6148.JPG
https://upload.wikimedia.org/wikipedia/commons/thumb/3/32/V%C3%A4gen_in.jpg/800px-V%C3%A4gen_in.jpg
The wall consists of sheet of material that slowly emerges from a slot at one side of the pass and eventually disappears into a slot on the other side. Behind the scenes, the material is melted and reformed after which it goes through another slot and back to the starting point where the same thing happens. Thus the wall is a kind of continuous vertical conveyor belt whose surface is always being renewed.
Problems
There would have to be a substantial cache (of sand in the case of glass) or other renewable source of wall-material to make up any losses from natural wear-and-tear.
An enormous power source would be required but I suppose it could be nuclear.
$endgroup$
add a comment |
$begingroup$
Vertical conveyor belt
I've been thinking about some of the objections and have come up with answer to my own question that might work.
Maybe it could even be made of thick glass. The wall could be blocking a tall narrow rectangular cut through the mountains - an artificial pass. The wall could be quite narrow (say enough for ten-abreast to pass through) and thus supported all the way up by a frame.
EDIT - Apologies - I should have made something clear when posing the question. In my imagination the pass is cut through the mountains by the aliens. It looks something like the following only much more smooth-sided and rectangular. The pictures are from the ancient site of Petra. https://en.wikipedia.org/wiki/Siq
https://upload.wikimedia.org/wikipedia/commons/thumb/e/e3/PS-Petra_6148.JPG/1200px-PS-Petra_6148.JPG
https://upload.wikimedia.org/wikipedia/commons/thumb/3/32/V%C3%A4gen_in.jpg/800px-V%C3%A4gen_in.jpg
The wall consists of sheet of material that slowly emerges from a slot at one side of the pass and eventually disappears into a slot on the other side. Behind the scenes, the material is melted and reformed after which it goes through another slot and back to the starting point where the same thing happens. Thus the wall is a kind of continuous vertical conveyor belt whose surface is always being renewed.
Problems
There would have to be a substantial cache (of sand in the case of glass) or other renewable source of wall-material to make up any losses from natural wear-and-tear.
An enormous power source would be required but I suppose it could be nuclear.
$endgroup$
Vertical conveyor belt
I've been thinking about some of the objections and have come up with answer to my own question that might work.
Maybe it could even be made of thick glass. The wall could be blocking a tall narrow rectangular cut through the mountains - an artificial pass. The wall could be quite narrow (say enough for ten-abreast to pass through) and thus supported all the way up by a frame.
EDIT - Apologies - I should have made something clear when posing the question. In my imagination the pass is cut through the mountains by the aliens. It looks something like the following only much more smooth-sided and rectangular. The pictures are from the ancient site of Petra. https://en.wikipedia.org/wiki/Siq
https://upload.wikimedia.org/wikipedia/commons/thumb/e/e3/PS-Petra_6148.JPG/1200px-PS-Petra_6148.JPG
https://upload.wikimedia.org/wikipedia/commons/thumb/3/32/V%C3%A4gen_in.jpg/800px-V%C3%A4gen_in.jpg
The wall consists of sheet of material that slowly emerges from a slot at one side of the pass and eventually disappears into a slot on the other side. Behind the scenes, the material is melted and reformed after which it goes through another slot and back to the starting point where the same thing happens. Thus the wall is a kind of continuous vertical conveyor belt whose surface is always being renewed.
Problems
There would have to be a substantial cache (of sand in the case of glass) or other renewable source of wall-material to make up any losses from natural wear-and-tear.
An enormous power source would be required but I suppose it could be nuclear.
edited Dec 6 '18 at 11:39
answered Dec 4 '18 at 13:03
chasly from UKchasly from UK
14k465133
14k465133
add a comment |
add a comment |
$begingroup$
This may not be exactly what you described, but one idea could be to use screens/projections on each side.
The "wall" could be built out of regular material, at least on the inside, with some form of ultra-hard glass (or transparent-steel) coating the outside. Each screen then projects a live feed of the other side. To a medieval civilization this would more or less look like a transparent wall, with each side seeing a projection of the other. The display itself could even use some advanced form of e-paper tech in order to avoid backlight issues.
While this can maybe solve some of the issues of material and structure of a solid wall, it does of course pose questions about power supply and wear/tear on the hardware itself. This could be ignored by claiming it uses futuristic self-repairing tech, but it really depends on the setting.
$endgroup$
$begingroup$
Based on the height and thickness of the wall, power could come from solar panels on the top of the wall. Or wind could be harnessed similar to that of Ocean Current Energy where subtle gusts of wind pushing against the wall cause minute points of pressure that can be converted into energy. Or of course, energy production could be generated underground (geothermal / nuclear / etc.)
$endgroup$
– flaZer
Dec 4 '18 at 21:56
$begingroup$
Wind turbines with sharp blades would add to the unscaleability. As would big photoenergetic setups with focussing mirrors that bundle at human height.
$endgroup$
– bukwyrm
Dec 5 '18 at 6:11
add a comment |
$begingroup$
This may not be exactly what you described, but one idea could be to use screens/projections on each side.
The "wall" could be built out of regular material, at least on the inside, with some form of ultra-hard glass (or transparent-steel) coating the outside. Each screen then projects a live feed of the other side. To a medieval civilization this would more or less look like a transparent wall, with each side seeing a projection of the other. The display itself could even use some advanced form of e-paper tech in order to avoid backlight issues.
While this can maybe solve some of the issues of material and structure of a solid wall, it does of course pose questions about power supply and wear/tear on the hardware itself. This could be ignored by claiming it uses futuristic self-repairing tech, but it really depends on the setting.
$endgroup$
$begingroup$
Based on the height and thickness of the wall, power could come from solar panels on the top of the wall. Or wind could be harnessed similar to that of Ocean Current Energy where subtle gusts of wind pushing against the wall cause minute points of pressure that can be converted into energy. Or of course, energy production could be generated underground (geothermal / nuclear / etc.)
$endgroup$
– flaZer
Dec 4 '18 at 21:56
$begingroup$
Wind turbines with sharp blades would add to the unscaleability. As would big photoenergetic setups with focussing mirrors that bundle at human height.
$endgroup$
– bukwyrm
Dec 5 '18 at 6:11
add a comment |
$begingroup$
This may not be exactly what you described, but one idea could be to use screens/projections on each side.
The "wall" could be built out of regular material, at least on the inside, with some form of ultra-hard glass (or transparent-steel) coating the outside. Each screen then projects a live feed of the other side. To a medieval civilization this would more or less look like a transparent wall, with each side seeing a projection of the other. The display itself could even use some advanced form of e-paper tech in order to avoid backlight issues.
While this can maybe solve some of the issues of material and structure of a solid wall, it does of course pose questions about power supply and wear/tear on the hardware itself. This could be ignored by claiming it uses futuristic self-repairing tech, but it really depends on the setting.
$endgroup$
This may not be exactly what you described, but one idea could be to use screens/projections on each side.
The "wall" could be built out of regular material, at least on the inside, with some form of ultra-hard glass (or transparent-steel) coating the outside. Each screen then projects a live feed of the other side. To a medieval civilization this would more or less look like a transparent wall, with each side seeing a projection of the other. The display itself could even use some advanced form of e-paper tech in order to avoid backlight issues.
While this can maybe solve some of the issues of material and structure of a solid wall, it does of course pose questions about power supply and wear/tear on the hardware itself. This could be ignored by claiming it uses futuristic self-repairing tech, but it really depends on the setting.
answered Dec 4 '18 at 13:53
Steven MillsSteven Mills
1914
1914
$begingroup$
Based on the height and thickness of the wall, power could come from solar panels on the top of the wall. Or wind could be harnessed similar to that of Ocean Current Energy where subtle gusts of wind pushing against the wall cause minute points of pressure that can be converted into energy. Or of course, energy production could be generated underground (geothermal / nuclear / etc.)
$endgroup$
– flaZer
Dec 4 '18 at 21:56
$begingroup$
Wind turbines with sharp blades would add to the unscaleability. As would big photoenergetic setups with focussing mirrors that bundle at human height.
$endgroup$
– bukwyrm
Dec 5 '18 at 6:11
add a comment |
$begingroup$
Based on the height and thickness of the wall, power could come from solar panels on the top of the wall. Or wind could be harnessed similar to that of Ocean Current Energy where subtle gusts of wind pushing against the wall cause minute points of pressure that can be converted into energy. Or of course, energy production could be generated underground (geothermal / nuclear / etc.)
$endgroup$
– flaZer
Dec 4 '18 at 21:56
$begingroup$
Wind turbines with sharp blades would add to the unscaleability. As would big photoenergetic setups with focussing mirrors that bundle at human height.
$endgroup$
– bukwyrm
Dec 5 '18 at 6:11
$begingroup$
Based on the height and thickness of the wall, power could come from solar panels on the top of the wall. Or wind could be harnessed similar to that of Ocean Current Energy where subtle gusts of wind pushing against the wall cause minute points of pressure that can be converted into energy. Or of course, energy production could be generated underground (geothermal / nuclear / etc.)
$endgroup$
– flaZer
Dec 4 '18 at 21:56
$begingroup$
Based on the height and thickness of the wall, power could come from solar panels on the top of the wall. Or wind could be harnessed similar to that of Ocean Current Energy where subtle gusts of wind pushing against the wall cause minute points of pressure that can be converted into energy. Or of course, energy production could be generated underground (geothermal / nuclear / etc.)
$endgroup$
– flaZer
Dec 4 '18 at 21:56
$begingroup$
Wind turbines with sharp blades would add to the unscaleability. As would big photoenergetic setups with focussing mirrors that bundle at human height.
$endgroup$
– bukwyrm
Dec 5 '18 at 6:11
$begingroup$
Wind turbines with sharp blades would add to the unscaleability. As would big photoenergetic setups with focussing mirrors that bundle at human height.
$endgroup$
– bukwyrm
Dec 5 '18 at 6:11
add a comment |
$begingroup$
Magnetic Barrier
A very, very, very strong magnetic field would be both entirely transparent and impervious to all materials*. Because it's not a static surface it will always remain perfectly clear as it won't collect dirt or debris.
How does it work? Unlike ferromagnetism, which is a property only exhibited by a few materials, diamagnetism is a property of all materials. Given a strong enough magnetic field everything would be repelled*.
To anyone experimenting with this "wall" it might appear to be soft. As they begin to press against it they would feel increasing push back as the repulsion force builds until they can't press further (which may become painful). Objects thrown again this "wall" would have a slight bounce back.
Sound can also be controlled by magnetism. The "wall" could be deliberately engineered to reflect sound back to its source. However the very nature of such a strong field may perturb the phonons of sound enough to make the "wall" naturally acoustically impermeable.
* Strictly speaking a field strong enough to repel solid objects would only have a weak interaction with sparse substances such as the oxygen and nitrogen in the atmosphere. Perhaps producing a slight wind and/or higher levels of oxygen at the wall. Additionally, photon lensing would be imperceivable at this level.
$endgroup$
1
$begingroup$
What would be a ballpark figure on the strength of a magnetic field like that? Is it in any way realistic to generate with technology we could imagine, even if just in theory? I'm not a physicist, but my guesses to the answers would be "go fetch me a neutron star" and "LOL no", respectively, but it would be interesting to consider the practical ramifications rather than just postulate the field is there somehow.
$endgroup$
– Jeroen Mostert
Dec 4 '18 at 19:10
$begingroup$
@JeroenMostert this site goes into more detail behind the physics. It requires ~10 teslas to levitate a small diamagnetic object. 1000 tesla magnets have already been built. Surprisingly magnetic fields aren't very resource expensive. For example the power requirements to levitate a maglev train car are approximately equivalent to the that of a room air conditioner. The energy costs would be high, but not impossible so.
$endgroup$
– Skek Tek
Dec 4 '18 at 20:48
$begingroup$
@SkekTek, thing is, magnetic field strength falls off as the inverse cube of distance. Those frog-levitating magnets are only that strong in a roughly frog-sized volume. If you're trying to block off an entire mountain pass, you're going to need an insanely strong magnet. (And I suspect the pass will very quickly get blocked off by stray bits of iron and other ferromagnetic materials.)
$endgroup$
– Mark
Dec 5 '18 at 2:51
$begingroup$
What @Mark said: a 16T field may levitate a 20g frog, but you're talking about a field capable of (at least) repelling a fully grown adult and speeding projectiles pushing against it with forces much greater than gravity, and that field has to span a far bigger area. Those 1000T magnets (and the few with even higher strengths) are destroyed in the experiments, so not exactly suitable for a permanent wall. I'm not saying it's impossible, but it sounds like the kind of thing that could immediately fall apart when you actually run the numbers.
$endgroup$
– Jeroen Mostert
Dec 5 '18 at 5:14
$begingroup$
@Mark This is a solvable engineering problem. The falloff is quick but the range is effectively unlimited. They would simply need to meter the strength of the field for the applicable area. In this case the area is confined to a pass and presumably the field can be generated from 3 sides. Height has only been measured by the deflection of a low mass projectile at a steep angle (the ionic wind generated by the field might even be enough to deflect the arrow into a tumble).
$endgroup$
– Skek Tek
Dec 5 '18 at 13:44
|
show 2 more comments
$begingroup$
Magnetic Barrier
A very, very, very strong magnetic field would be both entirely transparent and impervious to all materials*. Because it's not a static surface it will always remain perfectly clear as it won't collect dirt or debris.
How does it work? Unlike ferromagnetism, which is a property only exhibited by a few materials, diamagnetism is a property of all materials. Given a strong enough magnetic field everything would be repelled*.
To anyone experimenting with this "wall" it might appear to be soft. As they begin to press against it they would feel increasing push back as the repulsion force builds until they can't press further (which may become painful). Objects thrown again this "wall" would have a slight bounce back.
Sound can also be controlled by magnetism. The "wall" could be deliberately engineered to reflect sound back to its source. However the very nature of such a strong field may perturb the phonons of sound enough to make the "wall" naturally acoustically impermeable.
* Strictly speaking a field strong enough to repel solid objects would only have a weak interaction with sparse substances such as the oxygen and nitrogen in the atmosphere. Perhaps producing a slight wind and/or higher levels of oxygen at the wall. Additionally, photon lensing would be imperceivable at this level.
$endgroup$
1
$begingroup$
What would be a ballpark figure on the strength of a magnetic field like that? Is it in any way realistic to generate with technology we could imagine, even if just in theory? I'm not a physicist, but my guesses to the answers would be "go fetch me a neutron star" and "LOL no", respectively, but it would be interesting to consider the practical ramifications rather than just postulate the field is there somehow.
$endgroup$
– Jeroen Mostert
Dec 4 '18 at 19:10
$begingroup$
@JeroenMostert this site goes into more detail behind the physics. It requires ~10 teslas to levitate a small diamagnetic object. 1000 tesla magnets have already been built. Surprisingly magnetic fields aren't very resource expensive. For example the power requirements to levitate a maglev train car are approximately equivalent to the that of a room air conditioner. The energy costs would be high, but not impossible so.
$endgroup$
– Skek Tek
Dec 4 '18 at 20:48
$begingroup$
@SkekTek, thing is, magnetic field strength falls off as the inverse cube of distance. Those frog-levitating magnets are only that strong in a roughly frog-sized volume. If you're trying to block off an entire mountain pass, you're going to need an insanely strong magnet. (And I suspect the pass will very quickly get blocked off by stray bits of iron and other ferromagnetic materials.)
$endgroup$
– Mark
Dec 5 '18 at 2:51
$begingroup$
What @Mark said: a 16T field may levitate a 20g frog, but you're talking about a field capable of (at least) repelling a fully grown adult and speeding projectiles pushing against it with forces much greater than gravity, and that field has to span a far bigger area. Those 1000T magnets (and the few with even higher strengths) are destroyed in the experiments, so not exactly suitable for a permanent wall. I'm not saying it's impossible, but it sounds like the kind of thing that could immediately fall apart when you actually run the numbers.
$endgroup$
– Jeroen Mostert
Dec 5 '18 at 5:14
$begingroup$
@Mark This is a solvable engineering problem. The falloff is quick but the range is effectively unlimited. They would simply need to meter the strength of the field for the applicable area. In this case the area is confined to a pass and presumably the field can be generated from 3 sides. Height has only been measured by the deflection of a low mass projectile at a steep angle (the ionic wind generated by the field might even be enough to deflect the arrow into a tumble).
$endgroup$
– Skek Tek
Dec 5 '18 at 13:44
|
show 2 more comments
$begingroup$
Magnetic Barrier
A very, very, very strong magnetic field would be both entirely transparent and impervious to all materials*. Because it's not a static surface it will always remain perfectly clear as it won't collect dirt or debris.
How does it work? Unlike ferromagnetism, which is a property only exhibited by a few materials, diamagnetism is a property of all materials. Given a strong enough magnetic field everything would be repelled*.
To anyone experimenting with this "wall" it might appear to be soft. As they begin to press against it they would feel increasing push back as the repulsion force builds until they can't press further (which may become painful). Objects thrown again this "wall" would have a slight bounce back.
Sound can also be controlled by magnetism. The "wall" could be deliberately engineered to reflect sound back to its source. However the very nature of such a strong field may perturb the phonons of sound enough to make the "wall" naturally acoustically impermeable.
* Strictly speaking a field strong enough to repel solid objects would only have a weak interaction with sparse substances such as the oxygen and nitrogen in the atmosphere. Perhaps producing a slight wind and/or higher levels of oxygen at the wall. Additionally, photon lensing would be imperceivable at this level.
$endgroup$
Magnetic Barrier
A very, very, very strong magnetic field would be both entirely transparent and impervious to all materials*. Because it's not a static surface it will always remain perfectly clear as it won't collect dirt or debris.
How does it work? Unlike ferromagnetism, which is a property only exhibited by a few materials, diamagnetism is a property of all materials. Given a strong enough magnetic field everything would be repelled*.
To anyone experimenting with this "wall" it might appear to be soft. As they begin to press against it they would feel increasing push back as the repulsion force builds until they can't press further (which may become painful). Objects thrown again this "wall" would have a slight bounce back.
Sound can also be controlled by magnetism. The "wall" could be deliberately engineered to reflect sound back to its source. However the very nature of such a strong field may perturb the phonons of sound enough to make the "wall" naturally acoustically impermeable.
* Strictly speaking a field strong enough to repel solid objects would only have a weak interaction with sparse substances such as the oxygen and nitrogen in the atmosphere. Perhaps producing a slight wind and/or higher levels of oxygen at the wall. Additionally, photon lensing would be imperceivable at this level.
edited Dec 4 '18 at 14:51
answered Dec 4 '18 at 14:34
Skek TekSkek Tek
85218
85218
1
$begingroup$
What would be a ballpark figure on the strength of a magnetic field like that? Is it in any way realistic to generate with technology we could imagine, even if just in theory? I'm not a physicist, but my guesses to the answers would be "go fetch me a neutron star" and "LOL no", respectively, but it would be interesting to consider the practical ramifications rather than just postulate the field is there somehow.
$endgroup$
– Jeroen Mostert
Dec 4 '18 at 19:10
$begingroup$
@JeroenMostert this site goes into more detail behind the physics. It requires ~10 teslas to levitate a small diamagnetic object. 1000 tesla magnets have already been built. Surprisingly magnetic fields aren't very resource expensive. For example the power requirements to levitate a maglev train car are approximately equivalent to the that of a room air conditioner. The energy costs would be high, but not impossible so.
$endgroup$
– Skek Tek
Dec 4 '18 at 20:48
$begingroup$
@SkekTek, thing is, magnetic field strength falls off as the inverse cube of distance. Those frog-levitating magnets are only that strong in a roughly frog-sized volume. If you're trying to block off an entire mountain pass, you're going to need an insanely strong magnet. (And I suspect the pass will very quickly get blocked off by stray bits of iron and other ferromagnetic materials.)
$endgroup$
– Mark
Dec 5 '18 at 2:51
$begingroup$
What @Mark said: a 16T field may levitate a 20g frog, but you're talking about a field capable of (at least) repelling a fully grown adult and speeding projectiles pushing against it with forces much greater than gravity, and that field has to span a far bigger area. Those 1000T magnets (and the few with even higher strengths) are destroyed in the experiments, so not exactly suitable for a permanent wall. I'm not saying it's impossible, but it sounds like the kind of thing that could immediately fall apart when you actually run the numbers.
$endgroup$
– Jeroen Mostert
Dec 5 '18 at 5:14
$begingroup$
@Mark This is a solvable engineering problem. The falloff is quick but the range is effectively unlimited. They would simply need to meter the strength of the field for the applicable area. In this case the area is confined to a pass and presumably the field can be generated from 3 sides. Height has only been measured by the deflection of a low mass projectile at a steep angle (the ionic wind generated by the field might even be enough to deflect the arrow into a tumble).
$endgroup$
– Skek Tek
Dec 5 '18 at 13:44
|
show 2 more comments
1
$begingroup$
What would be a ballpark figure on the strength of a magnetic field like that? Is it in any way realistic to generate with technology we could imagine, even if just in theory? I'm not a physicist, but my guesses to the answers would be "go fetch me a neutron star" and "LOL no", respectively, but it would be interesting to consider the practical ramifications rather than just postulate the field is there somehow.
$endgroup$
– Jeroen Mostert
Dec 4 '18 at 19:10
$begingroup$
@JeroenMostert this site goes into more detail behind the physics. It requires ~10 teslas to levitate a small diamagnetic object. 1000 tesla magnets have already been built. Surprisingly magnetic fields aren't very resource expensive. For example the power requirements to levitate a maglev train car are approximately equivalent to the that of a room air conditioner. The energy costs would be high, but not impossible so.
$endgroup$
– Skek Tek
Dec 4 '18 at 20:48
$begingroup$
@SkekTek, thing is, magnetic field strength falls off as the inverse cube of distance. Those frog-levitating magnets are only that strong in a roughly frog-sized volume. If you're trying to block off an entire mountain pass, you're going to need an insanely strong magnet. (And I suspect the pass will very quickly get blocked off by stray bits of iron and other ferromagnetic materials.)
$endgroup$
– Mark
Dec 5 '18 at 2:51
$begingroup$
What @Mark said: a 16T field may levitate a 20g frog, but you're talking about a field capable of (at least) repelling a fully grown adult and speeding projectiles pushing against it with forces much greater than gravity, and that field has to span a far bigger area. Those 1000T magnets (and the few with even higher strengths) are destroyed in the experiments, so not exactly suitable for a permanent wall. I'm not saying it's impossible, but it sounds like the kind of thing that could immediately fall apart when you actually run the numbers.
$endgroup$
– Jeroen Mostert
Dec 5 '18 at 5:14
$begingroup$
@Mark This is a solvable engineering problem. The falloff is quick but the range is effectively unlimited. They would simply need to meter the strength of the field for the applicable area. In this case the area is confined to a pass and presumably the field can be generated from 3 sides. Height has only been measured by the deflection of a low mass projectile at a steep angle (the ionic wind generated by the field might even be enough to deflect the arrow into a tumble).
$endgroup$
– Skek Tek
Dec 5 '18 at 13:44
1
1
$begingroup$
What would be a ballpark figure on the strength of a magnetic field like that? Is it in any way realistic to generate with technology we could imagine, even if just in theory? I'm not a physicist, but my guesses to the answers would be "go fetch me a neutron star" and "LOL no", respectively, but it would be interesting to consider the practical ramifications rather than just postulate the field is there somehow.
$endgroup$
– Jeroen Mostert
Dec 4 '18 at 19:10
$begingroup$
What would be a ballpark figure on the strength of a magnetic field like that? Is it in any way realistic to generate with technology we could imagine, even if just in theory? I'm not a physicist, but my guesses to the answers would be "go fetch me a neutron star" and "LOL no", respectively, but it would be interesting to consider the practical ramifications rather than just postulate the field is there somehow.
$endgroup$
– Jeroen Mostert
Dec 4 '18 at 19:10
$begingroup$
@JeroenMostert this site goes into more detail behind the physics. It requires ~10 teslas to levitate a small diamagnetic object. 1000 tesla magnets have already been built. Surprisingly magnetic fields aren't very resource expensive. For example the power requirements to levitate a maglev train car are approximately equivalent to the that of a room air conditioner. The energy costs would be high, but not impossible so.
$endgroup$
– Skek Tek
Dec 4 '18 at 20:48
$begingroup$
@JeroenMostert this site goes into more detail behind the physics. It requires ~10 teslas to levitate a small diamagnetic object. 1000 tesla magnets have already been built. Surprisingly magnetic fields aren't very resource expensive. For example the power requirements to levitate a maglev train car are approximately equivalent to the that of a room air conditioner. The energy costs would be high, but not impossible so.
$endgroup$
– Skek Tek
Dec 4 '18 at 20:48
$begingroup$
@SkekTek, thing is, magnetic field strength falls off as the inverse cube of distance. Those frog-levitating magnets are only that strong in a roughly frog-sized volume. If you're trying to block off an entire mountain pass, you're going to need an insanely strong magnet. (And I suspect the pass will very quickly get blocked off by stray bits of iron and other ferromagnetic materials.)
$endgroup$
– Mark
Dec 5 '18 at 2:51
$begingroup$
@SkekTek, thing is, magnetic field strength falls off as the inverse cube of distance. Those frog-levitating magnets are only that strong in a roughly frog-sized volume. If you're trying to block off an entire mountain pass, you're going to need an insanely strong magnet. (And I suspect the pass will very quickly get blocked off by stray bits of iron and other ferromagnetic materials.)
$endgroup$
– Mark
Dec 5 '18 at 2:51
$begingroup$
What @Mark said: a 16T field may levitate a 20g frog, but you're talking about a field capable of (at least) repelling a fully grown adult and speeding projectiles pushing against it with forces much greater than gravity, and that field has to span a far bigger area. Those 1000T magnets (and the few with even higher strengths) are destroyed in the experiments, so not exactly suitable for a permanent wall. I'm not saying it's impossible, but it sounds like the kind of thing that could immediately fall apart when you actually run the numbers.
$endgroup$
– Jeroen Mostert
Dec 5 '18 at 5:14
$begingroup$
What @Mark said: a 16T field may levitate a 20g frog, but you're talking about a field capable of (at least) repelling a fully grown adult and speeding projectiles pushing against it with forces much greater than gravity, and that field has to span a far bigger area. Those 1000T magnets (and the few with even higher strengths) are destroyed in the experiments, so not exactly suitable for a permanent wall. I'm not saying it's impossible, but it sounds like the kind of thing that could immediately fall apart when you actually run the numbers.
$endgroup$
– Jeroen Mostert
Dec 5 '18 at 5:14
$begingroup$
@Mark This is a solvable engineering problem. The falloff is quick but the range is effectively unlimited. They would simply need to meter the strength of the field for the applicable area. In this case the area is confined to a pass and presumably the field can be generated from 3 sides. Height has only been measured by the deflection of a low mass projectile at a steep angle (the ionic wind generated by the field might even be enough to deflect the arrow into a tumble).
$endgroup$
– Skek Tek
Dec 5 '18 at 13:44
$begingroup$
@Mark This is a solvable engineering problem. The falloff is quick but the range is effectively unlimited. They would simply need to meter the strength of the field for the applicable area. In this case the area is confined to a pass and presumably the field can be generated from 3 sides. Height has only been measured by the deflection of a low mass projectile at a steep angle (the ionic wind generated by the field might even be enough to deflect the arrow into a tumble).
$endgroup$
– Skek Tek
Dec 5 '18 at 13:44
|
show 2 more comments
$begingroup$
Relax the definition of "Transparent"
As several other answers have discussed, building a massive, impenetrable wall out of transparent material is impossible. But if the ancients had advanced technology, the same effect can be achieved without the wall actually being transparent in the sense that light passes through unobstructed. Simply cover the wall on all sides with a cloaking device.
In essence, make the whole thing a screen that shows the viewer the light hitting the wall on the opposite side, captured by nanotech cameras or similar. Rudimentary versions of this technology already exist (with varying degrees of success). For fictional ancients with advanced technology, a perfected version that shows the correct image from any viewing angle should be trivial. Cover the screen with a layer of diamond to protect its "transparency" from attack, and then build the wall out of whatever you want. The bigger and more sturdy the better, so there's room on the inside for the massive computers required to make the thing run.
Since you've already got sophisticated computers powering the thing, adding a noise cancellation module seems straightforward.
$endgroup$
add a comment |
$begingroup$
Relax the definition of "Transparent"
As several other answers have discussed, building a massive, impenetrable wall out of transparent material is impossible. But if the ancients had advanced technology, the same effect can be achieved without the wall actually being transparent in the sense that light passes through unobstructed. Simply cover the wall on all sides with a cloaking device.
In essence, make the whole thing a screen that shows the viewer the light hitting the wall on the opposite side, captured by nanotech cameras or similar. Rudimentary versions of this technology already exist (with varying degrees of success). For fictional ancients with advanced technology, a perfected version that shows the correct image from any viewing angle should be trivial. Cover the screen with a layer of diamond to protect its "transparency" from attack, and then build the wall out of whatever you want. The bigger and more sturdy the better, so there's room on the inside for the massive computers required to make the thing run.
Since you've already got sophisticated computers powering the thing, adding a noise cancellation module seems straightforward.
$endgroup$
add a comment |
$begingroup$
Relax the definition of "Transparent"
As several other answers have discussed, building a massive, impenetrable wall out of transparent material is impossible. But if the ancients had advanced technology, the same effect can be achieved without the wall actually being transparent in the sense that light passes through unobstructed. Simply cover the wall on all sides with a cloaking device.
In essence, make the whole thing a screen that shows the viewer the light hitting the wall on the opposite side, captured by nanotech cameras or similar. Rudimentary versions of this technology already exist (with varying degrees of success). For fictional ancients with advanced technology, a perfected version that shows the correct image from any viewing angle should be trivial. Cover the screen with a layer of diamond to protect its "transparency" from attack, and then build the wall out of whatever you want. The bigger and more sturdy the better, so there's room on the inside for the massive computers required to make the thing run.
Since you've already got sophisticated computers powering the thing, adding a noise cancellation module seems straightforward.
$endgroup$
Relax the definition of "Transparent"
As several other answers have discussed, building a massive, impenetrable wall out of transparent material is impossible. But if the ancients had advanced technology, the same effect can be achieved without the wall actually being transparent in the sense that light passes through unobstructed. Simply cover the wall on all sides with a cloaking device.
In essence, make the whole thing a screen that shows the viewer the light hitting the wall on the opposite side, captured by nanotech cameras or similar. Rudimentary versions of this technology already exist (with varying degrees of success). For fictional ancients with advanced technology, a perfected version that shows the correct image from any viewing angle should be trivial. Cover the screen with a layer of diamond to protect its "transparency" from attack, and then build the wall out of whatever you want. The bigger and more sturdy the better, so there's room on the inside for the massive computers required to make the thing run.
Since you've already got sophisticated computers powering the thing, adding a noise cancellation module seems straightforward.
answered Dec 4 '18 at 18:35
rsandlerrsandler
358211
358211
add a comment |
add a comment |
$begingroup$
The Wall is an surreal absurdity.
https://www.nytimes.com/1978/05/07/archives/surreal-and-absurd-surreal.html
The paradox of this kind of literature is that if the symbols are too
easily comprehensible they tend to appear monotonous and‐ trite, while
if they are totally opaque, they offer no purchase for the mind and
merely replace the Absurdist face of the world by an impenetrable
surface of apparently random verbal signs. The ideal solution, not
easy to achieve, is a convincingly pregnant mystery.
With a wall like this, your fiction should be absurdist and surreal. A clear wall separating 2 societies is going to be a metaphor. If you establish that it is clear aluminum oxide that falls under trite. Leaving it up in the air will be frustrating. Best: you can have various characters explain it in detail and have it be different each time. In the absurdist tradition, each citizen can have his or her own persuasion about how the wall works and what it is made of - glass, or wind, or force, or living creatures, or an erotic dream. I can envision the same character who put forth one explanation then putting forth a different one later in the story. If challenged, the character may or may not recall his original explanation, and will good-naturedly try to change the subject.
$endgroup$
$begingroup$
The eventual aim is that a heroic character will climb the cliffs and defeat the monsters. They will then find a secret entrance and discover the ancient mechanism (which they don't understand but the reader might from a description of what everything looks like). Then they press the right button and the barrier slides back.
$endgroup$
– chasly from UK
Dec 6 '18 at 13:11
add a comment |
$begingroup$
The Wall is an surreal absurdity.
https://www.nytimes.com/1978/05/07/archives/surreal-and-absurd-surreal.html
The paradox of this kind of literature is that if the symbols are too
easily comprehensible they tend to appear monotonous and‐ trite, while
if they are totally opaque, they offer no purchase for the mind and
merely replace the Absurdist face of the world by an impenetrable
surface of apparently random verbal signs. The ideal solution, not
easy to achieve, is a convincingly pregnant mystery.
With a wall like this, your fiction should be absurdist and surreal. A clear wall separating 2 societies is going to be a metaphor. If you establish that it is clear aluminum oxide that falls under trite. Leaving it up in the air will be frustrating. Best: you can have various characters explain it in detail and have it be different each time. In the absurdist tradition, each citizen can have his or her own persuasion about how the wall works and what it is made of - glass, or wind, or force, or living creatures, or an erotic dream. I can envision the same character who put forth one explanation then putting forth a different one later in the story. If challenged, the character may or may not recall his original explanation, and will good-naturedly try to change the subject.
$endgroup$
$begingroup$
The eventual aim is that a heroic character will climb the cliffs and defeat the monsters. They will then find a secret entrance and discover the ancient mechanism (which they don't understand but the reader might from a description of what everything looks like). Then they press the right button and the barrier slides back.
$endgroup$
– chasly from UK
Dec 6 '18 at 13:11
add a comment |
$begingroup$
The Wall is an surreal absurdity.
https://www.nytimes.com/1978/05/07/archives/surreal-and-absurd-surreal.html
The paradox of this kind of literature is that if the symbols are too
easily comprehensible they tend to appear monotonous and‐ trite, while
if they are totally opaque, they offer no purchase for the mind and
merely replace the Absurdist face of the world by an impenetrable
surface of apparently random verbal signs. The ideal solution, not
easy to achieve, is a convincingly pregnant mystery.
With a wall like this, your fiction should be absurdist and surreal. A clear wall separating 2 societies is going to be a metaphor. If you establish that it is clear aluminum oxide that falls under trite. Leaving it up in the air will be frustrating. Best: you can have various characters explain it in detail and have it be different each time. In the absurdist tradition, each citizen can have his or her own persuasion about how the wall works and what it is made of - glass, or wind, or force, or living creatures, or an erotic dream. I can envision the same character who put forth one explanation then putting forth a different one later in the story. If challenged, the character may or may not recall his original explanation, and will good-naturedly try to change the subject.
$endgroup$
The Wall is an surreal absurdity.
https://www.nytimes.com/1978/05/07/archives/surreal-and-absurd-surreal.html
The paradox of this kind of literature is that if the symbols are too
easily comprehensible they tend to appear monotonous and‐ trite, while
if they are totally opaque, they offer no purchase for the mind and
merely replace the Absurdist face of the world by an impenetrable
surface of apparently random verbal signs. The ideal solution, not
easy to achieve, is a convincingly pregnant mystery.
With a wall like this, your fiction should be absurdist and surreal. A clear wall separating 2 societies is going to be a metaphor. If you establish that it is clear aluminum oxide that falls under trite. Leaving it up in the air will be frustrating. Best: you can have various characters explain it in detail and have it be different each time. In the absurdist tradition, each citizen can have his or her own persuasion about how the wall works and what it is made of - glass, or wind, or force, or living creatures, or an erotic dream. I can envision the same character who put forth one explanation then putting forth a different one later in the story. If challenged, the character may or may not recall his original explanation, and will good-naturedly try to change the subject.
edited Dec 5 '18 at 16:45
answered Dec 5 '18 at 15:10
WillkWillk
104k25197440
104k25197440
$begingroup$
The eventual aim is that a heroic character will climb the cliffs and defeat the monsters. They will then find a secret entrance and discover the ancient mechanism (which they don't understand but the reader might from a description of what everything looks like). Then they press the right button and the barrier slides back.
$endgroup$
– chasly from UK
Dec 6 '18 at 13:11
add a comment |
$begingroup$
The eventual aim is that a heroic character will climb the cliffs and defeat the monsters. They will then find a secret entrance and discover the ancient mechanism (which they don't understand but the reader might from a description of what everything looks like). Then they press the right button and the barrier slides back.
$endgroup$
– chasly from UK
Dec 6 '18 at 13:11
$begingroup$
The eventual aim is that a heroic character will climb the cliffs and defeat the monsters. They will then find a secret entrance and discover the ancient mechanism (which they don't understand but the reader might from a description of what everything looks like). Then they press the right button and the barrier slides back.
$endgroup$
– chasly from UK
Dec 6 '18 at 13:11
$begingroup$
The eventual aim is that a heroic character will climb the cliffs and defeat the monsters. They will then find a secret entrance and discover the ancient mechanism (which they don't understand but the reader might from a description of what everything looks like). Then they press the right button and the barrier slides back.
$endgroup$
– chasly from UK
Dec 6 '18 at 13:11
add a comment |
$begingroup$
A dense packing of optical fibres, endlessly rising from the ground. This would give observers the impression of people being inches away that in reality are meters distant. An underground source let's it rise up, taking any damage with it (making it impermeable) and slowly disintegrating in lofty heights (keeping its secret). The height is what makes it unsurpassable. If the world otherwise has never seen a TV-stone no one would figure it https://en.m.wikipedia.org/wiki/Ulexite.
The see- through would be quite limited, but the weird 'right below the surface' vibe of anything that IS seen might make up for it.
$endgroup$
add a comment |
$begingroup$
A dense packing of optical fibres, endlessly rising from the ground. This would give observers the impression of people being inches away that in reality are meters distant. An underground source let's it rise up, taking any damage with it (making it impermeable) and slowly disintegrating in lofty heights (keeping its secret). The height is what makes it unsurpassable. If the world otherwise has never seen a TV-stone no one would figure it https://en.m.wikipedia.org/wiki/Ulexite.
The see- through would be quite limited, but the weird 'right below the surface' vibe of anything that IS seen might make up for it.
$endgroup$
add a comment |
$begingroup$
A dense packing of optical fibres, endlessly rising from the ground. This would give observers the impression of people being inches away that in reality are meters distant. An underground source let's it rise up, taking any damage with it (making it impermeable) and slowly disintegrating in lofty heights (keeping its secret). The height is what makes it unsurpassable. If the world otherwise has never seen a TV-stone no one would figure it https://en.m.wikipedia.org/wiki/Ulexite.
The see- through would be quite limited, but the weird 'right below the surface' vibe of anything that IS seen might make up for it.
$endgroup$
A dense packing of optical fibres, endlessly rising from the ground. This would give observers the impression of people being inches away that in reality are meters distant. An underground source let's it rise up, taking any damage with it (making it impermeable) and slowly disintegrating in lofty heights (keeping its secret). The height is what makes it unsurpassable. If the world otherwise has never seen a TV-stone no one would figure it https://en.m.wikipedia.org/wiki/Ulexite.
The see- through would be quite limited, but the weird 'right below the surface' vibe of anything that IS seen might make up for it.
edited Dec 6 '18 at 10:32
answered Dec 5 '18 at 6:08
bukwyrmbukwyrm
3,509722
3,509722
add a comment |
add a comment |
$begingroup$
You want transparent, AND immune to surface degradation by thousands of years of wind and weather? In a mountain range, thus 100% guaranteed to be an earthquake zone at least in the very long term?
That is a very tall order!
Even a diamond surface would fail the test, you would have to resort to some mumble-fumble-handwaving forcefield or outright magic.
$endgroup$
add a comment |
$begingroup$
You want transparent, AND immune to surface degradation by thousands of years of wind and weather? In a mountain range, thus 100% guaranteed to be an earthquake zone at least in the very long term?
That is a very tall order!
Even a diamond surface would fail the test, you would have to resort to some mumble-fumble-handwaving forcefield or outright magic.
$endgroup$
add a comment |
$begingroup$
You want transparent, AND immune to surface degradation by thousands of years of wind and weather? In a mountain range, thus 100% guaranteed to be an earthquake zone at least in the very long term?
That is a very tall order!
Even a diamond surface would fail the test, you would have to resort to some mumble-fumble-handwaving forcefield or outright magic.
$endgroup$
You want transparent, AND immune to surface degradation by thousands of years of wind and weather? In a mountain range, thus 100% guaranteed to be an earthquake zone at least in the very long term?
That is a very tall order!
Even a diamond surface would fail the test, you would have to resort to some mumble-fumble-handwaving forcefield or outright magic.
answered Dec 6 '18 at 12:39
MarvinKitfoxMarvinKitfox
1712
1712
add a comment |
add a comment |
$begingroup$
It can't be done in a science-based way.
Diamond might come close, but it's a brittle material. Hit it hard with a sharp point (hardened steel, or rock) and it will crack. Toughened glass is more resistant to cracking, but shatters very spectacularly if you apply enough force (or grind your way through the outer toughened shell). You might try "toughened diamond", with no further explanation. Metals are resistant to cracking, but the physics which makes this so is the same physics that makes them opaque and reflective.
I'm tempted to add that it's obviously a General Products hull derivative, and so Puppeteers must be involved. "One giant molecule with its atomic bonds artificially strengthened using the output of a small nuclear reactor ..." Good handwavium, but impossible given science as we know it.
$endgroup$
add a comment |
$begingroup$
It can't be done in a science-based way.
Diamond might come close, but it's a brittle material. Hit it hard with a sharp point (hardened steel, or rock) and it will crack. Toughened glass is more resistant to cracking, but shatters very spectacularly if you apply enough force (or grind your way through the outer toughened shell). You might try "toughened diamond", with no further explanation. Metals are resistant to cracking, but the physics which makes this so is the same physics that makes them opaque and reflective.
I'm tempted to add that it's obviously a General Products hull derivative, and so Puppeteers must be involved. "One giant molecule with its atomic bonds artificially strengthened using the output of a small nuclear reactor ..." Good handwavium, but impossible given science as we know it.
$endgroup$
add a comment |
$begingroup$
It can't be done in a science-based way.
Diamond might come close, but it's a brittle material. Hit it hard with a sharp point (hardened steel, or rock) and it will crack. Toughened glass is more resistant to cracking, but shatters very spectacularly if you apply enough force (or grind your way through the outer toughened shell). You might try "toughened diamond", with no further explanation. Metals are resistant to cracking, but the physics which makes this so is the same physics that makes them opaque and reflective.
I'm tempted to add that it's obviously a General Products hull derivative, and so Puppeteers must be involved. "One giant molecule with its atomic bonds artificially strengthened using the output of a small nuclear reactor ..." Good handwavium, but impossible given science as we know it.
$endgroup$
It can't be done in a science-based way.
Diamond might come close, but it's a brittle material. Hit it hard with a sharp point (hardened steel, or rock) and it will crack. Toughened glass is more resistant to cracking, but shatters very spectacularly if you apply enough force (or grind your way through the outer toughened shell). You might try "toughened diamond", with no further explanation. Metals are resistant to cracking, but the physics which makes this so is the same physics that makes them opaque and reflective.
I'm tempted to add that it's obviously a General Products hull derivative, and so Puppeteers must be involved. "One giant molecule with its atomic bonds artificially strengthened using the output of a small nuclear reactor ..." Good handwavium, but impossible given science as we know it.
answered Dec 4 '18 at 14:27
nigel222nigel222
8,7391226
8,7391226
add a comment |
add a comment |
$begingroup$
The materials of the neutron star or white dwarf can be extremely thin, transparent and cannot be influenced by any chemical way and their mechanical hardness is absolute for a medieval civilization.
Our contemporary science cannot create or keep such walls (same as superstrong walls of usual materials), but we are talking about some hypothetical super-civilization.
$endgroup$
7
$begingroup$
I don't know where you got part about being thin and transparent. It also cannot exist in conditions that allows for civilization next to it, so even if you're right, it id still useless.
$endgroup$
– Mołot
Dec 3 '18 at 23:08
5
$begingroup$
Conditions needed what happens inside neutron star are extreme. It's too big to post in comment, useful basic article here en.wikipedia.org/wiki/Neutron_star#Properties
$endgroup$
– Mołot
Dec 3 '18 at 23:22
7
$begingroup$
A sheet of neutron star material would weigh much, much more than a planet. Any engineering effort to make a neutron-star structure with non-destructive mass would remove the gravitational potential that holds the quarks in such an extremely compressed state, and would release an explosion somewhere between planet-killer and solar-system-killer on the explosion scale
$endgroup$
– Mark_Anderson
Dec 3 '18 at 23:23
6
$begingroup$
Rock samples taken from deep underground explode when the pressure they are subjected is released. And they are far from experiencing the pressures found in a neutron star...
$endgroup$
– L.Dutch♦
Dec 4 '18 at 0:14
1
$begingroup$
Just use a thin huge indestructible transparent wall to hold the neutron star material in place, aka. the ancient spellrecursion
.
$endgroup$
– nwp
Dec 4 '18 at 12:41
|
show 2 more comments
$begingroup$
The materials of the neutron star or white dwarf can be extremely thin, transparent and cannot be influenced by any chemical way and their mechanical hardness is absolute for a medieval civilization.
Our contemporary science cannot create or keep such walls (same as superstrong walls of usual materials), but we are talking about some hypothetical super-civilization.
$endgroup$
7
$begingroup$
I don't know where you got part about being thin and transparent. It also cannot exist in conditions that allows for civilization next to it, so even if you're right, it id still useless.
$endgroup$
– Mołot
Dec 3 '18 at 23:08
5
$begingroup$
Conditions needed what happens inside neutron star are extreme. It's too big to post in comment, useful basic article here en.wikipedia.org/wiki/Neutron_star#Properties
$endgroup$
– Mołot
Dec 3 '18 at 23:22
7
$begingroup$
A sheet of neutron star material would weigh much, much more than a planet. Any engineering effort to make a neutron-star structure with non-destructive mass would remove the gravitational potential that holds the quarks in such an extremely compressed state, and would release an explosion somewhere between planet-killer and solar-system-killer on the explosion scale
$endgroup$
– Mark_Anderson
Dec 3 '18 at 23:23
6
$begingroup$
Rock samples taken from deep underground explode when the pressure they are subjected is released. And they are far from experiencing the pressures found in a neutron star...
$endgroup$
– L.Dutch♦
Dec 4 '18 at 0:14
1
$begingroup$
Just use a thin huge indestructible transparent wall to hold the neutron star material in place, aka. the ancient spellrecursion
.
$endgroup$
– nwp
Dec 4 '18 at 12:41
|
show 2 more comments
$begingroup$
The materials of the neutron star or white dwarf can be extremely thin, transparent and cannot be influenced by any chemical way and their mechanical hardness is absolute for a medieval civilization.
Our contemporary science cannot create or keep such walls (same as superstrong walls of usual materials), but we are talking about some hypothetical super-civilization.
$endgroup$
The materials of the neutron star or white dwarf can be extremely thin, transparent and cannot be influenced by any chemical way and their mechanical hardness is absolute for a medieval civilization.
Our contemporary science cannot create or keep such walls (same as superstrong walls of usual materials), but we are talking about some hypothetical super-civilization.
edited Dec 5 '18 at 6:34
answered Dec 3 '18 at 22:48
GangnusGangnus
1,52539
1,52539
7
$begingroup$
I don't know where you got part about being thin and transparent. It also cannot exist in conditions that allows for civilization next to it, so even if you're right, it id still useless.
$endgroup$
– Mołot
Dec 3 '18 at 23:08
5
$begingroup$
Conditions needed what happens inside neutron star are extreme. It's too big to post in comment, useful basic article here en.wikipedia.org/wiki/Neutron_star#Properties
$endgroup$
– Mołot
Dec 3 '18 at 23:22
7
$begingroup$
A sheet of neutron star material would weigh much, much more than a planet. Any engineering effort to make a neutron-star structure with non-destructive mass would remove the gravitational potential that holds the quarks in such an extremely compressed state, and would release an explosion somewhere between planet-killer and solar-system-killer on the explosion scale
$endgroup$
– Mark_Anderson
Dec 3 '18 at 23:23
6
$begingroup$
Rock samples taken from deep underground explode when the pressure they are subjected is released. And they are far from experiencing the pressures found in a neutron star...
$endgroup$
– L.Dutch♦
Dec 4 '18 at 0:14
1
$begingroup$
Just use a thin huge indestructible transparent wall to hold the neutron star material in place, aka. the ancient spellrecursion
.
$endgroup$
– nwp
Dec 4 '18 at 12:41
|
show 2 more comments
7
$begingroup$
I don't know where you got part about being thin and transparent. It also cannot exist in conditions that allows for civilization next to it, so even if you're right, it id still useless.
$endgroup$
– Mołot
Dec 3 '18 at 23:08
5
$begingroup$
Conditions needed what happens inside neutron star are extreme. It's too big to post in comment, useful basic article here en.wikipedia.org/wiki/Neutron_star#Properties
$endgroup$
– Mołot
Dec 3 '18 at 23:22
7
$begingroup$
A sheet of neutron star material would weigh much, much more than a planet. Any engineering effort to make a neutron-star structure with non-destructive mass would remove the gravitational potential that holds the quarks in such an extremely compressed state, and would release an explosion somewhere between planet-killer and solar-system-killer on the explosion scale
$endgroup$
– Mark_Anderson
Dec 3 '18 at 23:23
6
$begingroup$
Rock samples taken from deep underground explode when the pressure they are subjected is released. And they are far from experiencing the pressures found in a neutron star...
$endgroup$
– L.Dutch♦
Dec 4 '18 at 0:14
1
$begingroup$
Just use a thin huge indestructible transparent wall to hold the neutron star material in place, aka. the ancient spellrecursion
.
$endgroup$
– nwp
Dec 4 '18 at 12:41
7
7
$begingroup$
I don't know where you got part about being thin and transparent. It also cannot exist in conditions that allows for civilization next to it, so even if you're right, it id still useless.
$endgroup$
– Mołot
Dec 3 '18 at 23:08
$begingroup$
I don't know where you got part about being thin and transparent. It also cannot exist in conditions that allows for civilization next to it, so even if you're right, it id still useless.
$endgroup$
– Mołot
Dec 3 '18 at 23:08
5
5
$begingroup$
Conditions needed what happens inside neutron star are extreme. It's too big to post in comment, useful basic article here en.wikipedia.org/wiki/Neutron_star#Properties
$endgroup$
– Mołot
Dec 3 '18 at 23:22
$begingroup$
Conditions needed what happens inside neutron star are extreme. It's too big to post in comment, useful basic article here en.wikipedia.org/wiki/Neutron_star#Properties
$endgroup$
– Mołot
Dec 3 '18 at 23:22
7
7
$begingroup$
A sheet of neutron star material would weigh much, much more than a planet. Any engineering effort to make a neutron-star structure with non-destructive mass would remove the gravitational potential that holds the quarks in such an extremely compressed state, and would release an explosion somewhere between planet-killer and solar-system-killer on the explosion scale
$endgroup$
– Mark_Anderson
Dec 3 '18 at 23:23
$begingroup$
A sheet of neutron star material would weigh much, much more than a planet. Any engineering effort to make a neutron-star structure with non-destructive mass would remove the gravitational potential that holds the quarks in such an extremely compressed state, and would release an explosion somewhere between planet-killer and solar-system-killer on the explosion scale
$endgroup$
– Mark_Anderson
Dec 3 '18 at 23:23
6
6
$begingroup$
Rock samples taken from deep underground explode when the pressure they are subjected is released. And they are far from experiencing the pressures found in a neutron star...
$endgroup$
– L.Dutch♦
Dec 4 '18 at 0:14
$begingroup$
Rock samples taken from deep underground explode when the pressure they are subjected is released. And they are far from experiencing the pressures found in a neutron star...
$endgroup$
– L.Dutch♦
Dec 4 '18 at 0:14
1
1
$begingroup$
Just use a thin huge indestructible transparent wall to hold the neutron star material in place, aka. the ancient spell
recursion
.$endgroup$
– nwp
Dec 4 '18 at 12:41
$begingroup$
Just use a thin huge indestructible transparent wall to hold the neutron star material in place, aka. the ancient spell
recursion
.$endgroup$
– nwp
Dec 4 '18 at 12:41
|
show 2 more comments
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$begingroup$
You want the wall to be not just unbreakable - its surface should be non-degradable and unstainable?
$endgroup$
– Alexander
Dec 3 '18 at 21:53
1
$begingroup$
Keep in mind that over thousands of years the landscape can dramatically change, so building such a wall would be folly. For example Doggerland. Anyone who could build such a wall would know what could happen.
$endgroup$
– StephenG
Dec 4 '18 at 0:49
3
$begingroup$
If sound can't get through the wall, then I'm guessing air can't either? That could have some very interesting effects on wind and weather patterns near the wall, depending on how tall it was.
$endgroup$
– David K
Dec 4 '18 at 13:36
3
$begingroup$
This question can't be answered using science.
$endgroup$
– Geronimo
Dec 4 '18 at 13:38
$begingroup$
"smooth" : what stops someone from making some suction cups and just climbing up the wall? unless the wall has active defenses even 100 meters wouldn't be enough to stop someone climbing it.
$endgroup$
– Murphy
Dec 4 '18 at 13:47