Rings made out of water? [duplicate]












8















This question already has an answer here:




  • Is it possible for a planet to have a liquid ring?

    4 answers




There have been numerous questions on this site about moons being composed entirely of water. However, is it possible for a planet to have rings made out of water?



I think that the ring would probably freeze over/dissipate, but is there a way to realize this?










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marked as duplicate by rek, bilbo_pingouin, Mathaddict, Culyx, Vincent Dec 18 '18 at 22:36


This question has been asked before and already has an answer. If those answers do not fully address your question, please ask a new question.











  • 17




    To clarify: based on the "would probably freeze over", you want the rings to be composed of liquid water?
    – Cadence
    Dec 18 '18 at 7:09
















8















This question already has an answer here:




  • Is it possible for a planet to have a liquid ring?

    4 answers




There have been numerous questions on this site about moons being composed entirely of water. However, is it possible for a planet to have rings made out of water?



I think that the ring would probably freeze over/dissipate, but is there a way to realize this?










share|improve this question













marked as duplicate by rek, bilbo_pingouin, Mathaddict, Culyx, Vincent Dec 18 '18 at 22:36


This question has been asked before and already has an answer. If those answers do not fully address your question, please ask a new question.











  • 17




    To clarify: based on the "would probably freeze over", you want the rings to be composed of liquid water?
    – Cadence
    Dec 18 '18 at 7:09














8












8








8








This question already has an answer here:




  • Is it possible for a planet to have a liquid ring?

    4 answers




There have been numerous questions on this site about moons being composed entirely of water. However, is it possible for a planet to have rings made out of water?



I think that the ring would probably freeze over/dissipate, but is there a way to realize this?










share|improve this question














This question already has an answer here:




  • Is it possible for a planet to have a liquid ring?

    4 answers




There have been numerous questions on this site about moons being composed entirely of water. However, is it possible for a planet to have rings made out of water?



I think that the ring would probably freeze over/dissipate, but is there a way to realize this?





This question already has an answer here:




  • Is it possible for a planet to have a liquid ring?

    4 answers








orbital-mechanics planetary-rings






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share|improve this question











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share|improve this question










asked Dec 18 '18 at 6:44









Adrian Zhang

689417




689417




marked as duplicate by rek, bilbo_pingouin, Mathaddict, Culyx, Vincent Dec 18 '18 at 22:36


This question has been asked before and already has an answer. If those answers do not fully address your question, please ask a new question.






marked as duplicate by rek, bilbo_pingouin, Mathaddict, Culyx, Vincent Dec 18 '18 at 22:36


This question has been asked before and already has an answer. If those answers do not fully address your question, please ask a new question.










  • 17




    To clarify: based on the "would probably freeze over", you want the rings to be composed of liquid water?
    – Cadence
    Dec 18 '18 at 7:09














  • 17




    To clarify: based on the "would probably freeze over", you want the rings to be composed of liquid water?
    – Cadence
    Dec 18 '18 at 7:09








17




17




To clarify: based on the "would probably freeze over", you want the rings to be composed of liquid water?
– Cadence
Dec 18 '18 at 7:09




To clarify: based on the "would probably freeze over", you want the rings to be composed of liquid water?
– Cadence
Dec 18 '18 at 7:09










4 Answers
4






active

oldest

votes


















25















is it possible for a planet to have rings made out of water?




Of course it is. Just look at Saturn and its ring.




The rings of Saturn are the most extensive ring system of any planet in the Solar System. They consist of countless small particles, ranging from μm to m in size, that orbit about Saturn. The ring particles are made almost entirely of water ice, with a trace component of rocky material.




When you put liquids in space, they partially evaporate and most of it freezes. This happened routinely when Space Shuttle discharged the urine produced by the astronauts before landing the orbiter, leading to a plume of ice clearly visible from Earth (the so called Constellation of Urion)






share|improve this answer































    11














    This is the phase diagram for water.



    Phase diagram for water



    As you can see, it takes pressure for water to be a proper liquid. In a vacuum, it goes straight from solid to gas and vice-versa.



    It would take approximately 0.6% atmospheres to allow for liquid water. As low as that seems, it is still much more than what you would get in space.



    But don't give up just yet!



    Interstellar Ice Acts Like a Liquid in Ultraviolet Light




    When exposed to ultraviolet light, interstellar ice may act more like a liquid than a solid, a new study has found.



    Researchers discovered this effect while re-creating the conditions of our early solar system's planet-forming disk in a laboratory environment, revealing how organic chemistry might react to the deep freeze of the system's outer regions and how the seeds of planets accumulate material.




    And what is the biggest UV source in our solar system? Why, the sun itself!



    So while the ice in the planet's rings gets enough sun exposure, it will become amorphous ice. While technically a solid, it behaves like a liquid, which allows for it to work as a solvent for chemical reactions much like proper water. Any reactions will be orders of magnitude slower than whay they would be here, and most might not be possible, so don't expect it to harbor life (at least as we know it).






    share|improve this answer

















    • 1




      <<This so-called "radical formation" may increase the microscopic mobility of the chemicals, creating a viscous or liquid-like state>> -- That means that it is possible to search life on Europa by skimming material from close to the surface, in places where organic residues (brown stripes) are observed, long before we have the necessary technology to dig deep into the ocean under the ice!
      – Christmas Snow
      Dec 18 '18 at 10:44










    • @ChristmasSnow yes - same goes for many moons of Saturn and Pluto as well :)
      – Renan
      Dec 18 '18 at 10:47



















    6














    It is important to note that the zero pressure of the vacuum is below the water's triple point. Below the triple-point pressure, water can either exist as vapor or as solid, but not a liquid. That is why there is no surface liquid water on Mars, in-spite of abundant ice caps. In other words, when you heat a chunk of ice in space, it just evaporates without turning to a liquid -- It sublimes.



    The temperature too close to a star is above the frostline. The water ice will sublime and be gradually lost in space. At or beyond the frost line, the ice will remain solid for a long time, on a geological timescale.



    Note that the sun's heat causes evaporation. Evaporative cooling freezes the water. Evaporation slows down as it cools and freezes, but the chunk of ice will eventually evaporate completely, if placed too close outside the frost line.



    So, the answer is "yes", but it's water in the form of ice, not liquid water.






    share|improve this answer





















    • But… Mars has atmosphere, there's no vacuum on the surface. It has 0,06% of Earth atmosphere density, but still.
      – user28434
      Dec 18 '18 at 11:33










    • @user28434 If you look at the chart in Renan's post, the triple point of water is at about 0.6 kPa, which puts it almost exactly at the atmospheric pressure on Mars, so it is still just barely too low for liquid water there, even if the temperature were warm enough for it, which it definitely isn't.
      – Darrel Hoffman
      Dec 18 '18 at 14:52



















    -1














    How about a sun with a ring of water?



    In The Integral Trees, a 1984 science fiction novel by Larry Niven




    The story occurs around the fictional neutron star Levoy's Star (abbreviated "Voy"). The gas giant Goldblatt's World (abbreviated "Gold") orbits this star just outside its Roche limit and therefore its gravity is insufficient to keep its atmosphere, which is pulled loose into an independent orbit around Voy and forms a ring that is known as a gas torus. The gas torus is huge—one million kilometers thick—but most of it is too thin to be habitable. The central part of the Gas Torus, where the air is thicker, is known as the Smoke Ring. The Smoke Ring supports a wide variety of life.




    In the story there are lakes/ponds that are bubbles of water, If Gold was a water planet with little to no free atmosphere, the ring would be water that harbored life.






    share|improve this answer





















    • Would the water be stable, or would it evaporate? I rather suspect it would evaporate, and you'd get a cloud of water vapor being blown outward by the solar wind.
      – Mark
      Dec 19 '18 at 1:38


















    4 Answers
    4






    active

    oldest

    votes








    4 Answers
    4






    active

    oldest

    votes









    active

    oldest

    votes






    active

    oldest

    votes









    25















    is it possible for a planet to have rings made out of water?




    Of course it is. Just look at Saturn and its ring.




    The rings of Saturn are the most extensive ring system of any planet in the Solar System. They consist of countless small particles, ranging from μm to m in size, that orbit about Saturn. The ring particles are made almost entirely of water ice, with a trace component of rocky material.




    When you put liquids in space, they partially evaporate and most of it freezes. This happened routinely when Space Shuttle discharged the urine produced by the astronauts before landing the orbiter, leading to a plume of ice clearly visible from Earth (the so called Constellation of Urion)






    share|improve this answer




























      25















      is it possible for a planet to have rings made out of water?




      Of course it is. Just look at Saturn and its ring.




      The rings of Saturn are the most extensive ring system of any planet in the Solar System. They consist of countless small particles, ranging from μm to m in size, that orbit about Saturn. The ring particles are made almost entirely of water ice, with a trace component of rocky material.




      When you put liquids in space, they partially evaporate and most of it freezes. This happened routinely when Space Shuttle discharged the urine produced by the astronauts before landing the orbiter, leading to a plume of ice clearly visible from Earth (the so called Constellation of Urion)






      share|improve this answer


























        25












        25








        25







        is it possible for a planet to have rings made out of water?




        Of course it is. Just look at Saturn and its ring.




        The rings of Saturn are the most extensive ring system of any planet in the Solar System. They consist of countless small particles, ranging from μm to m in size, that orbit about Saturn. The ring particles are made almost entirely of water ice, with a trace component of rocky material.




        When you put liquids in space, they partially evaporate and most of it freezes. This happened routinely when Space Shuttle discharged the urine produced by the astronauts before landing the orbiter, leading to a plume of ice clearly visible from Earth (the so called Constellation of Urion)






        share|improve this answer















        is it possible for a planet to have rings made out of water?




        Of course it is. Just look at Saturn and its ring.




        The rings of Saturn are the most extensive ring system of any planet in the Solar System. They consist of countless small particles, ranging from μm to m in size, that orbit about Saturn. The ring particles are made almost entirely of water ice, with a trace component of rocky material.




        When you put liquids in space, they partially evaporate and most of it freezes. This happened routinely when Space Shuttle discharged the urine produced by the astronauts before landing the orbiter, leading to a plume of ice clearly visible from Earth (the so called Constellation of Urion)







        share|improve this answer














        share|improve this answer



        share|improve this answer








        edited Dec 18 '18 at 9:36

























        answered Dec 18 '18 at 7:03









        L.Dutch

        76.7k25183374




        76.7k25183374























            11














            This is the phase diagram for water.



            Phase diagram for water



            As you can see, it takes pressure for water to be a proper liquid. In a vacuum, it goes straight from solid to gas and vice-versa.



            It would take approximately 0.6% atmospheres to allow for liquid water. As low as that seems, it is still much more than what you would get in space.



            But don't give up just yet!



            Interstellar Ice Acts Like a Liquid in Ultraviolet Light




            When exposed to ultraviolet light, interstellar ice may act more like a liquid than a solid, a new study has found.



            Researchers discovered this effect while re-creating the conditions of our early solar system's planet-forming disk in a laboratory environment, revealing how organic chemistry might react to the deep freeze of the system's outer regions and how the seeds of planets accumulate material.




            And what is the biggest UV source in our solar system? Why, the sun itself!



            So while the ice in the planet's rings gets enough sun exposure, it will become amorphous ice. While technically a solid, it behaves like a liquid, which allows for it to work as a solvent for chemical reactions much like proper water. Any reactions will be orders of magnitude slower than whay they would be here, and most might not be possible, so don't expect it to harbor life (at least as we know it).






            share|improve this answer

















            • 1




              <<This so-called "radical formation" may increase the microscopic mobility of the chemicals, creating a viscous or liquid-like state>> -- That means that it is possible to search life on Europa by skimming material from close to the surface, in places where organic residues (brown stripes) are observed, long before we have the necessary technology to dig deep into the ocean under the ice!
              – Christmas Snow
              Dec 18 '18 at 10:44










            • @ChristmasSnow yes - same goes for many moons of Saturn and Pluto as well :)
              – Renan
              Dec 18 '18 at 10:47
















            11














            This is the phase diagram for water.



            Phase diagram for water



            As you can see, it takes pressure for water to be a proper liquid. In a vacuum, it goes straight from solid to gas and vice-versa.



            It would take approximately 0.6% atmospheres to allow for liquid water. As low as that seems, it is still much more than what you would get in space.



            But don't give up just yet!



            Interstellar Ice Acts Like a Liquid in Ultraviolet Light




            When exposed to ultraviolet light, interstellar ice may act more like a liquid than a solid, a new study has found.



            Researchers discovered this effect while re-creating the conditions of our early solar system's planet-forming disk in a laboratory environment, revealing how organic chemistry might react to the deep freeze of the system's outer regions and how the seeds of planets accumulate material.




            And what is the biggest UV source in our solar system? Why, the sun itself!



            So while the ice in the planet's rings gets enough sun exposure, it will become amorphous ice. While technically a solid, it behaves like a liquid, which allows for it to work as a solvent for chemical reactions much like proper water. Any reactions will be orders of magnitude slower than whay they would be here, and most might not be possible, so don't expect it to harbor life (at least as we know it).






            share|improve this answer

















            • 1




              <<This so-called "radical formation" may increase the microscopic mobility of the chemicals, creating a viscous or liquid-like state>> -- That means that it is possible to search life on Europa by skimming material from close to the surface, in places where organic residues (brown stripes) are observed, long before we have the necessary technology to dig deep into the ocean under the ice!
              – Christmas Snow
              Dec 18 '18 at 10:44










            • @ChristmasSnow yes - same goes for many moons of Saturn and Pluto as well :)
              – Renan
              Dec 18 '18 at 10:47














            11












            11








            11






            This is the phase diagram for water.



            Phase diagram for water



            As you can see, it takes pressure for water to be a proper liquid. In a vacuum, it goes straight from solid to gas and vice-versa.



            It would take approximately 0.6% atmospheres to allow for liquid water. As low as that seems, it is still much more than what you would get in space.



            But don't give up just yet!



            Interstellar Ice Acts Like a Liquid in Ultraviolet Light




            When exposed to ultraviolet light, interstellar ice may act more like a liquid than a solid, a new study has found.



            Researchers discovered this effect while re-creating the conditions of our early solar system's planet-forming disk in a laboratory environment, revealing how organic chemistry might react to the deep freeze of the system's outer regions and how the seeds of planets accumulate material.




            And what is the biggest UV source in our solar system? Why, the sun itself!



            So while the ice in the planet's rings gets enough sun exposure, it will become amorphous ice. While technically a solid, it behaves like a liquid, which allows for it to work as a solvent for chemical reactions much like proper water. Any reactions will be orders of magnitude slower than whay they would be here, and most might not be possible, so don't expect it to harbor life (at least as we know it).






            share|improve this answer












            This is the phase diagram for water.



            Phase diagram for water



            As you can see, it takes pressure for water to be a proper liquid. In a vacuum, it goes straight from solid to gas and vice-versa.



            It would take approximately 0.6% atmospheres to allow for liquid water. As low as that seems, it is still much more than what you would get in space.



            But don't give up just yet!



            Interstellar Ice Acts Like a Liquid in Ultraviolet Light




            When exposed to ultraviolet light, interstellar ice may act more like a liquid than a solid, a new study has found.



            Researchers discovered this effect while re-creating the conditions of our early solar system's planet-forming disk in a laboratory environment, revealing how organic chemistry might react to the deep freeze of the system's outer regions and how the seeds of planets accumulate material.




            And what is the biggest UV source in our solar system? Why, the sun itself!



            So while the ice in the planet's rings gets enough sun exposure, it will become amorphous ice. While technically a solid, it behaves like a liquid, which allows for it to work as a solvent for chemical reactions much like proper water. Any reactions will be orders of magnitude slower than whay they would be here, and most might not be possible, so don't expect it to harbor life (at least as we know it).







            share|improve this answer












            share|improve this answer



            share|improve this answer










            answered Dec 18 '18 at 10:33









            Renan

            42.9k1198218




            42.9k1198218








            • 1




              <<This so-called "radical formation" may increase the microscopic mobility of the chemicals, creating a viscous or liquid-like state>> -- That means that it is possible to search life on Europa by skimming material from close to the surface, in places where organic residues (brown stripes) are observed, long before we have the necessary technology to dig deep into the ocean under the ice!
              – Christmas Snow
              Dec 18 '18 at 10:44










            • @ChristmasSnow yes - same goes for many moons of Saturn and Pluto as well :)
              – Renan
              Dec 18 '18 at 10:47














            • 1




              <<This so-called "radical formation" may increase the microscopic mobility of the chemicals, creating a viscous or liquid-like state>> -- That means that it is possible to search life on Europa by skimming material from close to the surface, in places where organic residues (brown stripes) are observed, long before we have the necessary technology to dig deep into the ocean under the ice!
              – Christmas Snow
              Dec 18 '18 at 10:44










            • @ChristmasSnow yes - same goes for many moons of Saturn and Pluto as well :)
              – Renan
              Dec 18 '18 at 10:47








            1




            1




            <<This so-called "radical formation" may increase the microscopic mobility of the chemicals, creating a viscous or liquid-like state>> -- That means that it is possible to search life on Europa by skimming material from close to the surface, in places where organic residues (brown stripes) are observed, long before we have the necessary technology to dig deep into the ocean under the ice!
            – Christmas Snow
            Dec 18 '18 at 10:44




            <<This so-called "radical formation" may increase the microscopic mobility of the chemicals, creating a viscous or liquid-like state>> -- That means that it is possible to search life on Europa by skimming material from close to the surface, in places where organic residues (brown stripes) are observed, long before we have the necessary technology to dig deep into the ocean under the ice!
            – Christmas Snow
            Dec 18 '18 at 10:44












            @ChristmasSnow yes - same goes for many moons of Saturn and Pluto as well :)
            – Renan
            Dec 18 '18 at 10:47




            @ChristmasSnow yes - same goes for many moons of Saturn and Pluto as well :)
            – Renan
            Dec 18 '18 at 10:47











            6














            It is important to note that the zero pressure of the vacuum is below the water's triple point. Below the triple-point pressure, water can either exist as vapor or as solid, but not a liquid. That is why there is no surface liquid water on Mars, in-spite of abundant ice caps. In other words, when you heat a chunk of ice in space, it just evaporates without turning to a liquid -- It sublimes.



            The temperature too close to a star is above the frostline. The water ice will sublime and be gradually lost in space. At or beyond the frost line, the ice will remain solid for a long time, on a geological timescale.



            Note that the sun's heat causes evaporation. Evaporative cooling freezes the water. Evaporation slows down as it cools and freezes, but the chunk of ice will eventually evaporate completely, if placed too close outside the frost line.



            So, the answer is "yes", but it's water in the form of ice, not liquid water.






            share|improve this answer





















            • But… Mars has atmosphere, there's no vacuum on the surface. It has 0,06% of Earth atmosphere density, but still.
              – user28434
              Dec 18 '18 at 11:33










            • @user28434 If you look at the chart in Renan's post, the triple point of water is at about 0.6 kPa, which puts it almost exactly at the atmospheric pressure on Mars, so it is still just barely too low for liquid water there, even if the temperature were warm enough for it, which it definitely isn't.
              – Darrel Hoffman
              Dec 18 '18 at 14:52
















            6














            It is important to note that the zero pressure of the vacuum is below the water's triple point. Below the triple-point pressure, water can either exist as vapor or as solid, but not a liquid. That is why there is no surface liquid water on Mars, in-spite of abundant ice caps. In other words, when you heat a chunk of ice in space, it just evaporates without turning to a liquid -- It sublimes.



            The temperature too close to a star is above the frostline. The water ice will sublime and be gradually lost in space. At or beyond the frost line, the ice will remain solid for a long time, on a geological timescale.



            Note that the sun's heat causes evaporation. Evaporative cooling freezes the water. Evaporation slows down as it cools and freezes, but the chunk of ice will eventually evaporate completely, if placed too close outside the frost line.



            So, the answer is "yes", but it's water in the form of ice, not liquid water.






            share|improve this answer





















            • But… Mars has atmosphere, there's no vacuum on the surface. It has 0,06% of Earth atmosphere density, but still.
              – user28434
              Dec 18 '18 at 11:33










            • @user28434 If you look at the chart in Renan's post, the triple point of water is at about 0.6 kPa, which puts it almost exactly at the atmospheric pressure on Mars, so it is still just barely too low for liquid water there, even if the temperature were warm enough for it, which it definitely isn't.
              – Darrel Hoffman
              Dec 18 '18 at 14:52














            6












            6








            6






            It is important to note that the zero pressure of the vacuum is below the water's triple point. Below the triple-point pressure, water can either exist as vapor or as solid, but not a liquid. That is why there is no surface liquid water on Mars, in-spite of abundant ice caps. In other words, when you heat a chunk of ice in space, it just evaporates without turning to a liquid -- It sublimes.



            The temperature too close to a star is above the frostline. The water ice will sublime and be gradually lost in space. At or beyond the frost line, the ice will remain solid for a long time, on a geological timescale.



            Note that the sun's heat causes evaporation. Evaporative cooling freezes the water. Evaporation slows down as it cools and freezes, but the chunk of ice will eventually evaporate completely, if placed too close outside the frost line.



            So, the answer is "yes", but it's water in the form of ice, not liquid water.






            share|improve this answer












            It is important to note that the zero pressure of the vacuum is below the water's triple point. Below the triple-point pressure, water can either exist as vapor or as solid, but not a liquid. That is why there is no surface liquid water on Mars, in-spite of abundant ice caps. In other words, when you heat a chunk of ice in space, it just evaporates without turning to a liquid -- It sublimes.



            The temperature too close to a star is above the frostline. The water ice will sublime and be gradually lost in space. At or beyond the frost line, the ice will remain solid for a long time, on a geological timescale.



            Note that the sun's heat causes evaporation. Evaporative cooling freezes the water. Evaporation slows down as it cools and freezes, but the chunk of ice will eventually evaporate completely, if placed too close outside the frost line.



            So, the answer is "yes", but it's water in the form of ice, not liquid water.







            share|improve this answer












            share|improve this answer



            share|improve this answer










            answered Dec 18 '18 at 10:15









            Christmas Snow

            2,153313




            2,153313












            • But… Mars has atmosphere, there's no vacuum on the surface. It has 0,06% of Earth atmosphere density, but still.
              – user28434
              Dec 18 '18 at 11:33










            • @user28434 If you look at the chart in Renan's post, the triple point of water is at about 0.6 kPa, which puts it almost exactly at the atmospheric pressure on Mars, so it is still just barely too low for liquid water there, even if the temperature were warm enough for it, which it definitely isn't.
              – Darrel Hoffman
              Dec 18 '18 at 14:52


















            • But… Mars has atmosphere, there's no vacuum on the surface. It has 0,06% of Earth atmosphere density, but still.
              – user28434
              Dec 18 '18 at 11:33










            • @user28434 If you look at the chart in Renan's post, the triple point of water is at about 0.6 kPa, which puts it almost exactly at the atmospheric pressure on Mars, so it is still just barely too low for liquid water there, even if the temperature were warm enough for it, which it definitely isn't.
              – Darrel Hoffman
              Dec 18 '18 at 14:52
















            But… Mars has atmosphere, there's no vacuum on the surface. It has 0,06% of Earth atmosphere density, but still.
            – user28434
            Dec 18 '18 at 11:33




            But… Mars has atmosphere, there's no vacuum on the surface. It has 0,06% of Earth atmosphere density, but still.
            – user28434
            Dec 18 '18 at 11:33












            @user28434 If you look at the chart in Renan's post, the triple point of water is at about 0.6 kPa, which puts it almost exactly at the atmospheric pressure on Mars, so it is still just barely too low for liquid water there, even if the temperature were warm enough for it, which it definitely isn't.
            – Darrel Hoffman
            Dec 18 '18 at 14:52




            @user28434 If you look at the chart in Renan's post, the triple point of water is at about 0.6 kPa, which puts it almost exactly at the atmospheric pressure on Mars, so it is still just barely too low for liquid water there, even if the temperature were warm enough for it, which it definitely isn't.
            – Darrel Hoffman
            Dec 18 '18 at 14:52











            -1














            How about a sun with a ring of water?



            In The Integral Trees, a 1984 science fiction novel by Larry Niven




            The story occurs around the fictional neutron star Levoy's Star (abbreviated "Voy"). The gas giant Goldblatt's World (abbreviated "Gold") orbits this star just outside its Roche limit and therefore its gravity is insufficient to keep its atmosphere, which is pulled loose into an independent orbit around Voy and forms a ring that is known as a gas torus. The gas torus is huge—one million kilometers thick—but most of it is too thin to be habitable. The central part of the Gas Torus, where the air is thicker, is known as the Smoke Ring. The Smoke Ring supports a wide variety of life.




            In the story there are lakes/ponds that are bubbles of water, If Gold was a water planet with little to no free atmosphere, the ring would be water that harbored life.






            share|improve this answer





















            • Would the water be stable, or would it evaporate? I rather suspect it would evaporate, and you'd get a cloud of water vapor being blown outward by the solar wind.
              – Mark
              Dec 19 '18 at 1:38
















            -1














            How about a sun with a ring of water?



            In The Integral Trees, a 1984 science fiction novel by Larry Niven




            The story occurs around the fictional neutron star Levoy's Star (abbreviated "Voy"). The gas giant Goldblatt's World (abbreviated "Gold") orbits this star just outside its Roche limit and therefore its gravity is insufficient to keep its atmosphere, which is pulled loose into an independent orbit around Voy and forms a ring that is known as a gas torus. The gas torus is huge—one million kilometers thick—but most of it is too thin to be habitable. The central part of the Gas Torus, where the air is thicker, is known as the Smoke Ring. The Smoke Ring supports a wide variety of life.




            In the story there are lakes/ponds that are bubbles of water, If Gold was a water planet with little to no free atmosphere, the ring would be water that harbored life.






            share|improve this answer





















            • Would the water be stable, or would it evaporate? I rather suspect it would evaporate, and you'd get a cloud of water vapor being blown outward by the solar wind.
              – Mark
              Dec 19 '18 at 1:38














            -1












            -1








            -1






            How about a sun with a ring of water?



            In The Integral Trees, a 1984 science fiction novel by Larry Niven




            The story occurs around the fictional neutron star Levoy's Star (abbreviated "Voy"). The gas giant Goldblatt's World (abbreviated "Gold") orbits this star just outside its Roche limit and therefore its gravity is insufficient to keep its atmosphere, which is pulled loose into an independent orbit around Voy and forms a ring that is known as a gas torus. The gas torus is huge—one million kilometers thick—but most of it is too thin to be habitable. The central part of the Gas Torus, where the air is thicker, is known as the Smoke Ring. The Smoke Ring supports a wide variety of life.




            In the story there are lakes/ponds that are bubbles of water, If Gold was a water planet with little to no free atmosphere, the ring would be water that harbored life.






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            How about a sun with a ring of water?



            In The Integral Trees, a 1984 science fiction novel by Larry Niven




            The story occurs around the fictional neutron star Levoy's Star (abbreviated "Voy"). The gas giant Goldblatt's World (abbreviated "Gold") orbits this star just outside its Roche limit and therefore its gravity is insufficient to keep its atmosphere, which is pulled loose into an independent orbit around Voy and forms a ring that is known as a gas torus. The gas torus is huge—one million kilometers thick—but most of it is too thin to be habitable. The central part of the Gas Torus, where the air is thicker, is known as the Smoke Ring. The Smoke Ring supports a wide variety of life.




            In the story there are lakes/ponds that are bubbles of water, If Gold was a water planet with little to no free atmosphere, the ring would be water that harbored life.







            share|improve this answer












            share|improve this answer



            share|improve this answer










            answered Dec 18 '18 at 18:35









            James Jenkins

            397311




            397311












            • Would the water be stable, or would it evaporate? I rather suspect it would evaporate, and you'd get a cloud of water vapor being blown outward by the solar wind.
              – Mark
              Dec 19 '18 at 1:38


















            • Would the water be stable, or would it evaporate? I rather suspect it would evaporate, and you'd get a cloud of water vapor being blown outward by the solar wind.
              – Mark
              Dec 19 '18 at 1:38
















            Would the water be stable, or would it evaporate? I rather suspect it would evaporate, and you'd get a cloud of water vapor being blown outward by the solar wind.
            – Mark
            Dec 19 '18 at 1:38




            Would the water be stable, or would it evaporate? I rather suspect it would evaporate, and you'd get a cloud of water vapor being blown outward by the solar wind.
            – Mark
            Dec 19 '18 at 1:38



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