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Is it possible to ice skate on an ice moon/world?
When the Moon comes crashing down (wait, it doesn't)Is a moon inside a hollow Earth possible?The Ice of Eurasia, in Full DetailFrozen inside an ice cubeRocky core, internal ocean, ice crust, external oceanHow to make ice magic possible?Does it make sense to have a world with a very quickly orbiting moon?Is this habitable moon possible?If ice was denser than water what plants could survive?Conditions for an Ice Covered Moon to survive around a Terrestrial Planet
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If you found out a way to produce a smooth icy surface on an ice moon like Ganymede, Enceladus, or Callisto, what kind of challenges would someone face if they tried to start ice skating? I figured you'd have problems with traction or staying glued on the surface in a low gravity world. Would this be possible?
physics gravity moons ice
New contributor
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add a comment |
$begingroup$
If you found out a way to produce a smooth icy surface on an ice moon like Ganymede, Enceladus, or Callisto, what kind of challenges would someone face if they tried to start ice skating? I figured you'd have problems with traction or staying glued on the surface in a low gravity world. Would this be possible?
physics gravity moons ice
New contributor
$endgroup$
1
$begingroup$
nytimes.com/2006/02/21/science/21ice.html
$endgroup$
– Ville Niemi
2 days ago
add a comment |
$begingroup$
If you found out a way to produce a smooth icy surface on an ice moon like Ganymede, Enceladus, or Callisto, what kind of challenges would someone face if they tried to start ice skating? I figured you'd have problems with traction or staying glued on the surface in a low gravity world. Would this be possible?
physics gravity moons ice
New contributor
$endgroup$
If you found out a way to produce a smooth icy surface on an ice moon like Ganymede, Enceladus, or Callisto, what kind of challenges would someone face if they tried to start ice skating? I figured you'd have problems with traction or staying glued on the surface in a low gravity world. Would this be possible?
physics gravity moons ice
physics gravity moons ice
New contributor
New contributor
edited 2 days ago
Cyn
11.1k12351
11.1k12351
New contributor
asked 2 days ago
Sean KindleSean Kindle
1088
1088
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1
$begingroup$
nytimes.com/2006/02/21/science/21ice.html
$endgroup$
– Ville Niemi
2 days ago
add a comment |
1
$begingroup$
nytimes.com/2006/02/21/science/21ice.html
$endgroup$
– Ville Niemi
2 days ago
1
1
$begingroup$
nytimes.com/2006/02/21/science/21ice.html
$endgroup$
– Ville Niemi
2 days ago
$begingroup$
nytimes.com/2006/02/21/science/21ice.html
$endgroup$
– Ville Niemi
2 days ago
add a comment |
3 Answers
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$begingroup$
First of all, the surfaces of these moons are relatively smooth; that is to say, given the resolution of our images of their surfaces, they look smooth from a distance but that isn't to say that the surface is ragged or textured in some way. If you look at pictures of the Earth from a distance for example, the oceans look smooth but they still have waves and in some cases quite choppy surfaces that just don't appear at that resolution.
That said, assuming for the sake of argument you could find a pocket of the surface that is smooth enough, there are a number of other challenges that would make ice-skating difficult. The issue with weight in the lesser gravity is actually the easiest to fix, just like bouyancy in scuba diving, you simply wear weights. You could even use skates that are already weighed down so that traction is better.
Of more concern is whether or not your skates could actually move on the surface. Enceladus for instance is supposed to have an ice coating of actual water, but it would be very cold on that surface. One of the reasons why skaters move so gracefully over smooth ice is that the friction of the blade actually melts the ice it travels over, and that ice either becomes slush on the surface or re-freezes, which is why ice skating rinks have to be regularly resurfaced.
On Enceladus however, it is so cold that the ice would probably re-freeze (if the friction had any effect at all) so quickly that it could freeze your skate in place on the ice. Given that the temperatures on that moon are estimated to be around -201oC, it's even doubtful that there would be enough energy in the friction of the blade over the ice to heat it up to above 0oC, and therefore get it to melt. As such, your problem may not actually be too little traction, but too much.
Finally, and perhaps most importantly, given that Endeladus has no atmosphere and is so cold, you'd have to be on the surface in a full space-suit. This is going to be bulky, heavy and may solve your weight problem in its own right, at least in part, but it's also not going to be super flexible and allow the movement that one needs to stay balanced on the ice.
So assuming that the surface really is smooth enough (and it probably isn't), that the skate doesn't stick to the ice (and it probably will), you're still going to be in the exact opposite of a figure skating costume while on the ice, reducing your ability to skate normally (let alone do anything acrobatic or artistic) to almost zero.
$endgroup$
2
$begingroup$
Icescating reputedly already doesn't work very well below -20°C.
$endgroup$
– Karl
2 days ago
2
$begingroup$
you could have adaptively-heated blades that detect the temperature of the surface ant heat up accordingly - so that you dont get stuck when you stand in place
$endgroup$
– Derte Trdelnik
2 days ago
1
$begingroup$
The friction model doesn't really work. The main problem is that it explains why the surface behind your skates is melted. Another explanation points to the melted layer of water on top of the ice - the melting temperature of 273.15K is a bulk property. Surface entropy means that ice on the surface melts at lower temperatures, down to ~253K. And as @Karl points out, you can indeed not skate when it's that cold. The friction model fails to explain this - the energy needed to heat ice by 20K is much less than the heat needed to melt it.
$endgroup$
– MSalters
2 days ago
$begingroup$
Objection: The ice melts because the pressure of the skate lowers the melting point to below it's current temperature. You still have the same problem that if it's cold enough it doesn't melt and your skates don't work, though.
$endgroup$
– Loren Pechtel
2 days ago
1
$begingroup$
@LorenPechtel That's supposed to be a myth. The pressure is in the range of 1 MPa, ten bar. Not really enough to significantly lower the m.p. of water. ... Not sure where the story goes if you take into account that it's a surface under pressure.
$endgroup$
– Karl
yesterday
add a comment |
$begingroup$
Let's take you at your word
We'll assume whatever technology is necessary to produce your skating rink has been provided. A nice dome, temperature control, a Zamboni, the works. What's left over is the gravitational difference between the moon and Earth. Would someone be able to ice skate?
Yup, no problem. But there are some gotchas.
An adult ice skating on a moon will weigh about the same as a child ice skating on Earth. So, from a very simplistic perspective, traction isn't the problem. The three primary problems are the adult's (a) mass, (b) height, and (c) strength. (You shouldn't be surprised that these three issues are tightly interrelated.)
Mass
The problem with mass is that it takes the same amount of force to move it around on a moon (or in space) as it does on Earth. All that's missing is the gravitational component that sometimes works in your favor and sometimes doesn't. Skating on a moon means the adult will experience the weight of a child. Since children can skate just dandy on Earth, the weight of a child (an adult) on the moon can skate, too.
But the mass is another issue. If the skater gets moving too fast, they may not be able to stop because the mass is still there and requires the same stopping force as it would on Earth. But, with less weight, the edge of the skate may no longer hold the mass of the adult in place.
Height
Another problem is height, which in this case is a fancy word for "leverage." Remember all that mass we were just talking about? In an adult, a lot of that mass is a long way off the ground compared to a child. Attributed to Archimedes is the phrase, "Give me a place to stand and with a lever I will move the whole world." He wasn't kidding, leverage is a power multiplier, meaning a little force goes a long way. An adult's height could lead to the skater's feet stopping as expected, but their torso not stopping with them. The usual consequence is a sore bottom (but, with the lower weight, it won't hurt as much as your pride).
Strength
This is probably the greatest problem. An adult obviously has substantially more strength than a child (assuming equal weights, moon vs. Earth). That means an expected hop-and-spin might just land you in the bleachers. Or an expected turn might turn into an unexpected full stop. However, skaters would quickly learn how to "pull their punches" and exert less strength. The real problem is when they get back to Earth and all those atrophied muscles suddenly keep them from skating.
What this means is that an adult on a moon must skate like a child on Earth: slower, gentler, and with less self-consciousness.
$endgroup$
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Mass and strength seem to be solved by making carry weights around at all times. If gravity is 40% less than earth a 200lb person has to carry an 80lb weight.
$endgroup$
– cybernard
2 days ago
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Bouncing up on cybernard answer and the "Mass" paragraph: wouldn't the skater be at risk of reaching escape velocity and just fly off? (I suppose it depends of gravity and other factors, but with the premise of 40% less gravity, isn't ice skating a very dangerous sport?)
$endgroup$
– Nyakouai
2 days ago
$begingroup$
@Nyakouai - Well this answer does mention being inside a dome, so worst case would be bumping into the ceiling, but I suspect even a speed skater is not likely to be able to reach escape velocity without some form of propulsion (muscles can only increase your speed while on the ground, after all).
$endgroup$
– Darrel Hoffman
2 days ago
$begingroup$
@cybernard Adding mass (not a function of gravity) to compensate for weight (a function of gravity) solves one problem (strength) by exacerbating another (mass). There's more mass. More energy is now required to move, speed up, slow down, and stop. There is no perfect solution.
$endgroup$
– JBH
2 days ago
1
$begingroup$
@Nyakouai, it is impossible to hit a golf ball on our own moon and drive it into orbit. 1, 2. Ice skating is perfectly safe (from the perspective of escape velocity). If such a risk did exist, you'd be ice skating on a very small asteroid.
$endgroup$
– JBH
2 days ago
|
show 1 more comment
$begingroup$
It would depend on the temperature and the gravity.
Iceskating works (and ice is slippery) because of a very thin layer of liquid water on its surface. It's a combination of temperature differences at the interface and pressure applied on the ice's surface that make it possible to skate on ice.
If the gravity is weak enough that a skater's weight doesn't produce enough pressure, and/or the temperature is low enough, it can become physically impossible for ice to melt when the skates' blades come in contact with it. When that happens the ice stops being slippery and behaves like other types of rocks.
You could probably imagine workarounds in some edge cases, for instance by heating the skates' blades to overcome too low a pressure applied on the ice or too low a temperature.
$endgroup$
add a comment |
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3 Answers
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$begingroup$
First of all, the surfaces of these moons are relatively smooth; that is to say, given the resolution of our images of their surfaces, they look smooth from a distance but that isn't to say that the surface is ragged or textured in some way. If you look at pictures of the Earth from a distance for example, the oceans look smooth but they still have waves and in some cases quite choppy surfaces that just don't appear at that resolution.
That said, assuming for the sake of argument you could find a pocket of the surface that is smooth enough, there are a number of other challenges that would make ice-skating difficult. The issue with weight in the lesser gravity is actually the easiest to fix, just like bouyancy in scuba diving, you simply wear weights. You could even use skates that are already weighed down so that traction is better.
Of more concern is whether or not your skates could actually move on the surface. Enceladus for instance is supposed to have an ice coating of actual water, but it would be very cold on that surface. One of the reasons why skaters move so gracefully over smooth ice is that the friction of the blade actually melts the ice it travels over, and that ice either becomes slush on the surface or re-freezes, which is why ice skating rinks have to be regularly resurfaced.
On Enceladus however, it is so cold that the ice would probably re-freeze (if the friction had any effect at all) so quickly that it could freeze your skate in place on the ice. Given that the temperatures on that moon are estimated to be around -201oC, it's even doubtful that there would be enough energy in the friction of the blade over the ice to heat it up to above 0oC, and therefore get it to melt. As such, your problem may not actually be too little traction, but too much.
Finally, and perhaps most importantly, given that Endeladus has no atmosphere and is so cold, you'd have to be on the surface in a full space-suit. This is going to be bulky, heavy and may solve your weight problem in its own right, at least in part, but it's also not going to be super flexible and allow the movement that one needs to stay balanced on the ice.
So assuming that the surface really is smooth enough (and it probably isn't), that the skate doesn't stick to the ice (and it probably will), you're still going to be in the exact opposite of a figure skating costume while on the ice, reducing your ability to skate normally (let alone do anything acrobatic or artistic) to almost zero.
$endgroup$
2
$begingroup$
Icescating reputedly already doesn't work very well below -20°C.
$endgroup$
– Karl
2 days ago
2
$begingroup$
you could have adaptively-heated blades that detect the temperature of the surface ant heat up accordingly - so that you dont get stuck when you stand in place
$endgroup$
– Derte Trdelnik
2 days ago
1
$begingroup$
The friction model doesn't really work. The main problem is that it explains why the surface behind your skates is melted. Another explanation points to the melted layer of water on top of the ice - the melting temperature of 273.15K is a bulk property. Surface entropy means that ice on the surface melts at lower temperatures, down to ~253K. And as @Karl points out, you can indeed not skate when it's that cold. The friction model fails to explain this - the energy needed to heat ice by 20K is much less than the heat needed to melt it.
$endgroup$
– MSalters
2 days ago
$begingroup$
Objection: The ice melts because the pressure of the skate lowers the melting point to below it's current temperature. You still have the same problem that if it's cold enough it doesn't melt and your skates don't work, though.
$endgroup$
– Loren Pechtel
2 days ago
1
$begingroup$
@LorenPechtel That's supposed to be a myth. The pressure is in the range of 1 MPa, ten bar. Not really enough to significantly lower the m.p. of water. ... Not sure where the story goes if you take into account that it's a surface under pressure.
$endgroup$
– Karl
yesterday
add a comment |
$begingroup$
First of all, the surfaces of these moons are relatively smooth; that is to say, given the resolution of our images of their surfaces, they look smooth from a distance but that isn't to say that the surface is ragged or textured in some way. If you look at pictures of the Earth from a distance for example, the oceans look smooth but they still have waves and in some cases quite choppy surfaces that just don't appear at that resolution.
That said, assuming for the sake of argument you could find a pocket of the surface that is smooth enough, there are a number of other challenges that would make ice-skating difficult. The issue with weight in the lesser gravity is actually the easiest to fix, just like bouyancy in scuba diving, you simply wear weights. You could even use skates that are already weighed down so that traction is better.
Of more concern is whether or not your skates could actually move on the surface. Enceladus for instance is supposed to have an ice coating of actual water, but it would be very cold on that surface. One of the reasons why skaters move so gracefully over smooth ice is that the friction of the blade actually melts the ice it travels over, and that ice either becomes slush on the surface or re-freezes, which is why ice skating rinks have to be regularly resurfaced.
On Enceladus however, it is so cold that the ice would probably re-freeze (if the friction had any effect at all) so quickly that it could freeze your skate in place on the ice. Given that the temperatures on that moon are estimated to be around -201oC, it's even doubtful that there would be enough energy in the friction of the blade over the ice to heat it up to above 0oC, and therefore get it to melt. As such, your problem may not actually be too little traction, but too much.
Finally, and perhaps most importantly, given that Endeladus has no atmosphere and is so cold, you'd have to be on the surface in a full space-suit. This is going to be bulky, heavy and may solve your weight problem in its own right, at least in part, but it's also not going to be super flexible and allow the movement that one needs to stay balanced on the ice.
So assuming that the surface really is smooth enough (and it probably isn't), that the skate doesn't stick to the ice (and it probably will), you're still going to be in the exact opposite of a figure skating costume while on the ice, reducing your ability to skate normally (let alone do anything acrobatic or artistic) to almost zero.
$endgroup$
2
$begingroup$
Icescating reputedly already doesn't work very well below -20°C.
$endgroup$
– Karl
2 days ago
2
$begingroup$
you could have adaptively-heated blades that detect the temperature of the surface ant heat up accordingly - so that you dont get stuck when you stand in place
$endgroup$
– Derte Trdelnik
2 days ago
1
$begingroup$
The friction model doesn't really work. The main problem is that it explains why the surface behind your skates is melted. Another explanation points to the melted layer of water on top of the ice - the melting temperature of 273.15K is a bulk property. Surface entropy means that ice on the surface melts at lower temperatures, down to ~253K. And as @Karl points out, you can indeed not skate when it's that cold. The friction model fails to explain this - the energy needed to heat ice by 20K is much less than the heat needed to melt it.
$endgroup$
– MSalters
2 days ago
$begingroup$
Objection: The ice melts because the pressure of the skate lowers the melting point to below it's current temperature. You still have the same problem that if it's cold enough it doesn't melt and your skates don't work, though.
$endgroup$
– Loren Pechtel
2 days ago
1
$begingroup$
@LorenPechtel That's supposed to be a myth. The pressure is in the range of 1 MPa, ten bar. Not really enough to significantly lower the m.p. of water. ... Not sure where the story goes if you take into account that it's a surface under pressure.
$endgroup$
– Karl
yesterday
add a comment |
$begingroup$
First of all, the surfaces of these moons are relatively smooth; that is to say, given the resolution of our images of their surfaces, they look smooth from a distance but that isn't to say that the surface is ragged or textured in some way. If you look at pictures of the Earth from a distance for example, the oceans look smooth but they still have waves and in some cases quite choppy surfaces that just don't appear at that resolution.
That said, assuming for the sake of argument you could find a pocket of the surface that is smooth enough, there are a number of other challenges that would make ice-skating difficult. The issue with weight in the lesser gravity is actually the easiest to fix, just like bouyancy in scuba diving, you simply wear weights. You could even use skates that are already weighed down so that traction is better.
Of more concern is whether or not your skates could actually move on the surface. Enceladus for instance is supposed to have an ice coating of actual water, but it would be very cold on that surface. One of the reasons why skaters move so gracefully over smooth ice is that the friction of the blade actually melts the ice it travels over, and that ice either becomes slush on the surface or re-freezes, which is why ice skating rinks have to be regularly resurfaced.
On Enceladus however, it is so cold that the ice would probably re-freeze (if the friction had any effect at all) so quickly that it could freeze your skate in place on the ice. Given that the temperatures on that moon are estimated to be around -201oC, it's even doubtful that there would be enough energy in the friction of the blade over the ice to heat it up to above 0oC, and therefore get it to melt. As such, your problem may not actually be too little traction, but too much.
Finally, and perhaps most importantly, given that Endeladus has no atmosphere and is so cold, you'd have to be on the surface in a full space-suit. This is going to be bulky, heavy and may solve your weight problem in its own right, at least in part, but it's also not going to be super flexible and allow the movement that one needs to stay balanced on the ice.
So assuming that the surface really is smooth enough (and it probably isn't), that the skate doesn't stick to the ice (and it probably will), you're still going to be in the exact opposite of a figure skating costume while on the ice, reducing your ability to skate normally (let alone do anything acrobatic or artistic) to almost zero.
$endgroup$
First of all, the surfaces of these moons are relatively smooth; that is to say, given the resolution of our images of their surfaces, they look smooth from a distance but that isn't to say that the surface is ragged or textured in some way. If you look at pictures of the Earth from a distance for example, the oceans look smooth but they still have waves and in some cases quite choppy surfaces that just don't appear at that resolution.
That said, assuming for the sake of argument you could find a pocket of the surface that is smooth enough, there are a number of other challenges that would make ice-skating difficult. The issue with weight in the lesser gravity is actually the easiest to fix, just like bouyancy in scuba diving, you simply wear weights. You could even use skates that are already weighed down so that traction is better.
Of more concern is whether or not your skates could actually move on the surface. Enceladus for instance is supposed to have an ice coating of actual water, but it would be very cold on that surface. One of the reasons why skaters move so gracefully over smooth ice is that the friction of the blade actually melts the ice it travels over, and that ice either becomes slush on the surface or re-freezes, which is why ice skating rinks have to be regularly resurfaced.
On Enceladus however, it is so cold that the ice would probably re-freeze (if the friction had any effect at all) so quickly that it could freeze your skate in place on the ice. Given that the temperatures on that moon are estimated to be around -201oC, it's even doubtful that there would be enough energy in the friction of the blade over the ice to heat it up to above 0oC, and therefore get it to melt. As such, your problem may not actually be too little traction, but too much.
Finally, and perhaps most importantly, given that Endeladus has no atmosphere and is so cold, you'd have to be on the surface in a full space-suit. This is going to be bulky, heavy and may solve your weight problem in its own right, at least in part, but it's also not going to be super flexible and allow the movement that one needs to stay balanced on the ice.
So assuming that the surface really is smooth enough (and it probably isn't), that the skate doesn't stick to the ice (and it probably will), you're still going to be in the exact opposite of a figure skating costume while on the ice, reducing your ability to skate normally (let alone do anything acrobatic or artistic) to almost zero.
answered 2 days ago
Tim B IITim B II
32.4k672128
32.4k672128
2
$begingroup$
Icescating reputedly already doesn't work very well below -20°C.
$endgroup$
– Karl
2 days ago
2
$begingroup$
you could have adaptively-heated blades that detect the temperature of the surface ant heat up accordingly - so that you dont get stuck when you stand in place
$endgroup$
– Derte Trdelnik
2 days ago
1
$begingroup$
The friction model doesn't really work. The main problem is that it explains why the surface behind your skates is melted. Another explanation points to the melted layer of water on top of the ice - the melting temperature of 273.15K is a bulk property. Surface entropy means that ice on the surface melts at lower temperatures, down to ~253K. And as @Karl points out, you can indeed not skate when it's that cold. The friction model fails to explain this - the energy needed to heat ice by 20K is much less than the heat needed to melt it.
$endgroup$
– MSalters
2 days ago
$begingroup$
Objection: The ice melts because the pressure of the skate lowers the melting point to below it's current temperature. You still have the same problem that if it's cold enough it doesn't melt and your skates don't work, though.
$endgroup$
– Loren Pechtel
2 days ago
1
$begingroup$
@LorenPechtel That's supposed to be a myth. The pressure is in the range of 1 MPa, ten bar. Not really enough to significantly lower the m.p. of water. ... Not sure where the story goes if you take into account that it's a surface under pressure.
$endgroup$
– Karl
yesterday
add a comment |
2
$begingroup$
Icescating reputedly already doesn't work very well below -20°C.
$endgroup$
– Karl
2 days ago
2
$begingroup$
you could have adaptively-heated blades that detect the temperature of the surface ant heat up accordingly - so that you dont get stuck when you stand in place
$endgroup$
– Derte Trdelnik
2 days ago
1
$begingroup$
The friction model doesn't really work. The main problem is that it explains why the surface behind your skates is melted. Another explanation points to the melted layer of water on top of the ice - the melting temperature of 273.15K is a bulk property. Surface entropy means that ice on the surface melts at lower temperatures, down to ~253K. And as @Karl points out, you can indeed not skate when it's that cold. The friction model fails to explain this - the energy needed to heat ice by 20K is much less than the heat needed to melt it.
$endgroup$
– MSalters
2 days ago
$begingroup$
Objection: The ice melts because the pressure of the skate lowers the melting point to below it's current temperature. You still have the same problem that if it's cold enough it doesn't melt and your skates don't work, though.
$endgroup$
– Loren Pechtel
2 days ago
1
$begingroup$
@LorenPechtel That's supposed to be a myth. The pressure is in the range of 1 MPa, ten bar. Not really enough to significantly lower the m.p. of water. ... Not sure where the story goes if you take into account that it's a surface under pressure.
$endgroup$
– Karl
yesterday
2
2
$begingroup$
Icescating reputedly already doesn't work very well below -20°C.
$endgroup$
– Karl
2 days ago
$begingroup$
Icescating reputedly already doesn't work very well below -20°C.
$endgroup$
– Karl
2 days ago
2
2
$begingroup$
you could have adaptively-heated blades that detect the temperature of the surface ant heat up accordingly - so that you dont get stuck when you stand in place
$endgroup$
– Derte Trdelnik
2 days ago
$begingroup$
you could have adaptively-heated blades that detect the temperature of the surface ant heat up accordingly - so that you dont get stuck when you stand in place
$endgroup$
– Derte Trdelnik
2 days ago
1
1
$begingroup$
The friction model doesn't really work. The main problem is that it explains why the surface behind your skates is melted. Another explanation points to the melted layer of water on top of the ice - the melting temperature of 273.15K is a bulk property. Surface entropy means that ice on the surface melts at lower temperatures, down to ~253K. And as @Karl points out, you can indeed not skate when it's that cold. The friction model fails to explain this - the energy needed to heat ice by 20K is much less than the heat needed to melt it.
$endgroup$
– MSalters
2 days ago
$begingroup$
The friction model doesn't really work. The main problem is that it explains why the surface behind your skates is melted. Another explanation points to the melted layer of water on top of the ice - the melting temperature of 273.15K is a bulk property. Surface entropy means that ice on the surface melts at lower temperatures, down to ~253K. And as @Karl points out, you can indeed not skate when it's that cold. The friction model fails to explain this - the energy needed to heat ice by 20K is much less than the heat needed to melt it.
$endgroup$
– MSalters
2 days ago
$begingroup$
Objection: The ice melts because the pressure of the skate lowers the melting point to below it's current temperature. You still have the same problem that if it's cold enough it doesn't melt and your skates don't work, though.
$endgroup$
– Loren Pechtel
2 days ago
$begingroup$
Objection: The ice melts because the pressure of the skate lowers the melting point to below it's current temperature. You still have the same problem that if it's cold enough it doesn't melt and your skates don't work, though.
$endgroup$
– Loren Pechtel
2 days ago
1
1
$begingroup$
@LorenPechtel That's supposed to be a myth. The pressure is in the range of 1 MPa, ten bar. Not really enough to significantly lower the m.p. of water. ... Not sure where the story goes if you take into account that it's a surface under pressure.
$endgroup$
– Karl
yesterday
$begingroup$
@LorenPechtel That's supposed to be a myth. The pressure is in the range of 1 MPa, ten bar. Not really enough to significantly lower the m.p. of water. ... Not sure where the story goes if you take into account that it's a surface under pressure.
$endgroup$
– Karl
yesterday
add a comment |
$begingroup$
Let's take you at your word
We'll assume whatever technology is necessary to produce your skating rink has been provided. A nice dome, temperature control, a Zamboni, the works. What's left over is the gravitational difference between the moon and Earth. Would someone be able to ice skate?
Yup, no problem. But there are some gotchas.
An adult ice skating on a moon will weigh about the same as a child ice skating on Earth. So, from a very simplistic perspective, traction isn't the problem. The three primary problems are the adult's (a) mass, (b) height, and (c) strength. (You shouldn't be surprised that these three issues are tightly interrelated.)
Mass
The problem with mass is that it takes the same amount of force to move it around on a moon (or in space) as it does on Earth. All that's missing is the gravitational component that sometimes works in your favor and sometimes doesn't. Skating on a moon means the adult will experience the weight of a child. Since children can skate just dandy on Earth, the weight of a child (an adult) on the moon can skate, too.
But the mass is another issue. If the skater gets moving too fast, they may not be able to stop because the mass is still there and requires the same stopping force as it would on Earth. But, with less weight, the edge of the skate may no longer hold the mass of the adult in place.
Height
Another problem is height, which in this case is a fancy word for "leverage." Remember all that mass we were just talking about? In an adult, a lot of that mass is a long way off the ground compared to a child. Attributed to Archimedes is the phrase, "Give me a place to stand and with a lever I will move the whole world." He wasn't kidding, leverage is a power multiplier, meaning a little force goes a long way. An adult's height could lead to the skater's feet stopping as expected, but their torso not stopping with them. The usual consequence is a sore bottom (but, with the lower weight, it won't hurt as much as your pride).
Strength
This is probably the greatest problem. An adult obviously has substantially more strength than a child (assuming equal weights, moon vs. Earth). That means an expected hop-and-spin might just land you in the bleachers. Or an expected turn might turn into an unexpected full stop. However, skaters would quickly learn how to "pull their punches" and exert less strength. The real problem is when they get back to Earth and all those atrophied muscles suddenly keep them from skating.
What this means is that an adult on a moon must skate like a child on Earth: slower, gentler, and with less self-consciousness.
$endgroup$
$begingroup$
Mass and strength seem to be solved by making carry weights around at all times. If gravity is 40% less than earth a 200lb person has to carry an 80lb weight.
$endgroup$
– cybernard
2 days ago
$begingroup$
Bouncing up on cybernard answer and the "Mass" paragraph: wouldn't the skater be at risk of reaching escape velocity and just fly off? (I suppose it depends of gravity and other factors, but with the premise of 40% less gravity, isn't ice skating a very dangerous sport?)
$endgroup$
– Nyakouai
2 days ago
$begingroup$
@Nyakouai - Well this answer does mention being inside a dome, so worst case would be bumping into the ceiling, but I suspect even a speed skater is not likely to be able to reach escape velocity without some form of propulsion (muscles can only increase your speed while on the ground, after all).
$endgroup$
– Darrel Hoffman
2 days ago
$begingroup$
@cybernard Adding mass (not a function of gravity) to compensate for weight (a function of gravity) solves one problem (strength) by exacerbating another (mass). There's more mass. More energy is now required to move, speed up, slow down, and stop. There is no perfect solution.
$endgroup$
– JBH
2 days ago
1
$begingroup$
@Nyakouai, it is impossible to hit a golf ball on our own moon and drive it into orbit. 1, 2. Ice skating is perfectly safe (from the perspective of escape velocity). If such a risk did exist, you'd be ice skating on a very small asteroid.
$endgroup$
– JBH
2 days ago
|
show 1 more comment
$begingroup$
Let's take you at your word
We'll assume whatever technology is necessary to produce your skating rink has been provided. A nice dome, temperature control, a Zamboni, the works. What's left over is the gravitational difference between the moon and Earth. Would someone be able to ice skate?
Yup, no problem. But there are some gotchas.
An adult ice skating on a moon will weigh about the same as a child ice skating on Earth. So, from a very simplistic perspective, traction isn't the problem. The three primary problems are the adult's (a) mass, (b) height, and (c) strength. (You shouldn't be surprised that these three issues are tightly interrelated.)
Mass
The problem with mass is that it takes the same amount of force to move it around on a moon (or in space) as it does on Earth. All that's missing is the gravitational component that sometimes works in your favor and sometimes doesn't. Skating on a moon means the adult will experience the weight of a child. Since children can skate just dandy on Earth, the weight of a child (an adult) on the moon can skate, too.
But the mass is another issue. If the skater gets moving too fast, they may not be able to stop because the mass is still there and requires the same stopping force as it would on Earth. But, with less weight, the edge of the skate may no longer hold the mass of the adult in place.
Height
Another problem is height, which in this case is a fancy word for "leverage." Remember all that mass we were just talking about? In an adult, a lot of that mass is a long way off the ground compared to a child. Attributed to Archimedes is the phrase, "Give me a place to stand and with a lever I will move the whole world." He wasn't kidding, leverage is a power multiplier, meaning a little force goes a long way. An adult's height could lead to the skater's feet stopping as expected, but their torso not stopping with them. The usual consequence is a sore bottom (but, with the lower weight, it won't hurt as much as your pride).
Strength
This is probably the greatest problem. An adult obviously has substantially more strength than a child (assuming equal weights, moon vs. Earth). That means an expected hop-and-spin might just land you in the bleachers. Or an expected turn might turn into an unexpected full stop. However, skaters would quickly learn how to "pull their punches" and exert less strength. The real problem is when they get back to Earth and all those atrophied muscles suddenly keep them from skating.
What this means is that an adult on a moon must skate like a child on Earth: slower, gentler, and with less self-consciousness.
$endgroup$
$begingroup$
Mass and strength seem to be solved by making carry weights around at all times. If gravity is 40% less than earth a 200lb person has to carry an 80lb weight.
$endgroup$
– cybernard
2 days ago
$begingroup$
Bouncing up on cybernard answer and the "Mass" paragraph: wouldn't the skater be at risk of reaching escape velocity and just fly off? (I suppose it depends of gravity and other factors, but with the premise of 40% less gravity, isn't ice skating a very dangerous sport?)
$endgroup$
– Nyakouai
2 days ago
$begingroup$
@Nyakouai - Well this answer does mention being inside a dome, so worst case would be bumping into the ceiling, but I suspect even a speed skater is not likely to be able to reach escape velocity without some form of propulsion (muscles can only increase your speed while on the ground, after all).
$endgroup$
– Darrel Hoffman
2 days ago
$begingroup$
@cybernard Adding mass (not a function of gravity) to compensate for weight (a function of gravity) solves one problem (strength) by exacerbating another (mass). There's more mass. More energy is now required to move, speed up, slow down, and stop. There is no perfect solution.
$endgroup$
– JBH
2 days ago
1
$begingroup$
@Nyakouai, it is impossible to hit a golf ball on our own moon and drive it into orbit. 1, 2. Ice skating is perfectly safe (from the perspective of escape velocity). If such a risk did exist, you'd be ice skating on a very small asteroid.
$endgroup$
– JBH
2 days ago
|
show 1 more comment
$begingroup$
Let's take you at your word
We'll assume whatever technology is necessary to produce your skating rink has been provided. A nice dome, temperature control, a Zamboni, the works. What's left over is the gravitational difference between the moon and Earth. Would someone be able to ice skate?
Yup, no problem. But there are some gotchas.
An adult ice skating on a moon will weigh about the same as a child ice skating on Earth. So, from a very simplistic perspective, traction isn't the problem. The three primary problems are the adult's (a) mass, (b) height, and (c) strength. (You shouldn't be surprised that these three issues are tightly interrelated.)
Mass
The problem with mass is that it takes the same amount of force to move it around on a moon (or in space) as it does on Earth. All that's missing is the gravitational component that sometimes works in your favor and sometimes doesn't. Skating on a moon means the adult will experience the weight of a child. Since children can skate just dandy on Earth, the weight of a child (an adult) on the moon can skate, too.
But the mass is another issue. If the skater gets moving too fast, they may not be able to stop because the mass is still there and requires the same stopping force as it would on Earth. But, with less weight, the edge of the skate may no longer hold the mass of the adult in place.
Height
Another problem is height, which in this case is a fancy word for "leverage." Remember all that mass we were just talking about? In an adult, a lot of that mass is a long way off the ground compared to a child. Attributed to Archimedes is the phrase, "Give me a place to stand and with a lever I will move the whole world." He wasn't kidding, leverage is a power multiplier, meaning a little force goes a long way. An adult's height could lead to the skater's feet stopping as expected, but their torso not stopping with them. The usual consequence is a sore bottom (but, with the lower weight, it won't hurt as much as your pride).
Strength
This is probably the greatest problem. An adult obviously has substantially more strength than a child (assuming equal weights, moon vs. Earth). That means an expected hop-and-spin might just land you in the bleachers. Or an expected turn might turn into an unexpected full stop. However, skaters would quickly learn how to "pull their punches" and exert less strength. The real problem is when they get back to Earth and all those atrophied muscles suddenly keep them from skating.
What this means is that an adult on a moon must skate like a child on Earth: slower, gentler, and with less self-consciousness.
$endgroup$
Let's take you at your word
We'll assume whatever technology is necessary to produce your skating rink has been provided. A nice dome, temperature control, a Zamboni, the works. What's left over is the gravitational difference between the moon and Earth. Would someone be able to ice skate?
Yup, no problem. But there are some gotchas.
An adult ice skating on a moon will weigh about the same as a child ice skating on Earth. So, from a very simplistic perspective, traction isn't the problem. The three primary problems are the adult's (a) mass, (b) height, and (c) strength. (You shouldn't be surprised that these three issues are tightly interrelated.)
Mass
The problem with mass is that it takes the same amount of force to move it around on a moon (or in space) as it does on Earth. All that's missing is the gravitational component that sometimes works in your favor and sometimes doesn't. Skating on a moon means the adult will experience the weight of a child. Since children can skate just dandy on Earth, the weight of a child (an adult) on the moon can skate, too.
But the mass is another issue. If the skater gets moving too fast, they may not be able to stop because the mass is still there and requires the same stopping force as it would on Earth. But, with less weight, the edge of the skate may no longer hold the mass of the adult in place.
Height
Another problem is height, which in this case is a fancy word for "leverage." Remember all that mass we were just talking about? In an adult, a lot of that mass is a long way off the ground compared to a child. Attributed to Archimedes is the phrase, "Give me a place to stand and with a lever I will move the whole world." He wasn't kidding, leverage is a power multiplier, meaning a little force goes a long way. An adult's height could lead to the skater's feet stopping as expected, but their torso not stopping with them. The usual consequence is a sore bottom (but, with the lower weight, it won't hurt as much as your pride).
Strength
This is probably the greatest problem. An adult obviously has substantially more strength than a child (assuming equal weights, moon vs. Earth). That means an expected hop-and-spin might just land you in the bleachers. Or an expected turn might turn into an unexpected full stop. However, skaters would quickly learn how to "pull their punches" and exert less strength. The real problem is when they get back to Earth and all those atrophied muscles suddenly keep them from skating.
What this means is that an adult on a moon must skate like a child on Earth: slower, gentler, and with less self-consciousness.
answered 2 days ago
JBHJBH
47.8k699224
47.8k699224
$begingroup$
Mass and strength seem to be solved by making carry weights around at all times. If gravity is 40% less than earth a 200lb person has to carry an 80lb weight.
$endgroup$
– cybernard
2 days ago
$begingroup$
Bouncing up on cybernard answer and the "Mass" paragraph: wouldn't the skater be at risk of reaching escape velocity and just fly off? (I suppose it depends of gravity and other factors, but with the premise of 40% less gravity, isn't ice skating a very dangerous sport?)
$endgroup$
– Nyakouai
2 days ago
$begingroup$
@Nyakouai - Well this answer does mention being inside a dome, so worst case would be bumping into the ceiling, but I suspect even a speed skater is not likely to be able to reach escape velocity without some form of propulsion (muscles can only increase your speed while on the ground, after all).
$endgroup$
– Darrel Hoffman
2 days ago
$begingroup$
@cybernard Adding mass (not a function of gravity) to compensate for weight (a function of gravity) solves one problem (strength) by exacerbating another (mass). There's more mass. More energy is now required to move, speed up, slow down, and stop. There is no perfect solution.
$endgroup$
– JBH
2 days ago
1
$begingroup$
@Nyakouai, it is impossible to hit a golf ball on our own moon and drive it into orbit. 1, 2. Ice skating is perfectly safe (from the perspective of escape velocity). If such a risk did exist, you'd be ice skating on a very small asteroid.
$endgroup$
– JBH
2 days ago
|
show 1 more comment
$begingroup$
Mass and strength seem to be solved by making carry weights around at all times. If gravity is 40% less than earth a 200lb person has to carry an 80lb weight.
$endgroup$
– cybernard
2 days ago
$begingroup$
Bouncing up on cybernard answer and the "Mass" paragraph: wouldn't the skater be at risk of reaching escape velocity and just fly off? (I suppose it depends of gravity and other factors, but with the premise of 40% less gravity, isn't ice skating a very dangerous sport?)
$endgroup$
– Nyakouai
2 days ago
$begingroup$
@Nyakouai - Well this answer does mention being inside a dome, so worst case would be bumping into the ceiling, but I suspect even a speed skater is not likely to be able to reach escape velocity without some form of propulsion (muscles can only increase your speed while on the ground, after all).
$endgroup$
– Darrel Hoffman
2 days ago
$begingroup$
@cybernard Adding mass (not a function of gravity) to compensate for weight (a function of gravity) solves one problem (strength) by exacerbating another (mass). There's more mass. More energy is now required to move, speed up, slow down, and stop. There is no perfect solution.
$endgroup$
– JBH
2 days ago
1
$begingroup$
@Nyakouai, it is impossible to hit a golf ball on our own moon and drive it into orbit. 1, 2. Ice skating is perfectly safe (from the perspective of escape velocity). If such a risk did exist, you'd be ice skating on a very small asteroid.
$endgroup$
– JBH
2 days ago
$begingroup$
Mass and strength seem to be solved by making carry weights around at all times. If gravity is 40% less than earth a 200lb person has to carry an 80lb weight.
$endgroup$
– cybernard
2 days ago
$begingroup$
Mass and strength seem to be solved by making carry weights around at all times. If gravity is 40% less than earth a 200lb person has to carry an 80lb weight.
$endgroup$
– cybernard
2 days ago
$begingroup$
Bouncing up on cybernard answer and the "Mass" paragraph: wouldn't the skater be at risk of reaching escape velocity and just fly off? (I suppose it depends of gravity and other factors, but with the premise of 40% less gravity, isn't ice skating a very dangerous sport?)
$endgroup$
– Nyakouai
2 days ago
$begingroup$
Bouncing up on cybernard answer and the "Mass" paragraph: wouldn't the skater be at risk of reaching escape velocity and just fly off? (I suppose it depends of gravity and other factors, but with the premise of 40% less gravity, isn't ice skating a very dangerous sport?)
$endgroup$
– Nyakouai
2 days ago
$begingroup$
@Nyakouai - Well this answer does mention being inside a dome, so worst case would be bumping into the ceiling, but I suspect even a speed skater is not likely to be able to reach escape velocity without some form of propulsion (muscles can only increase your speed while on the ground, after all).
$endgroup$
– Darrel Hoffman
2 days ago
$begingroup$
@Nyakouai - Well this answer does mention being inside a dome, so worst case would be bumping into the ceiling, but I suspect even a speed skater is not likely to be able to reach escape velocity without some form of propulsion (muscles can only increase your speed while on the ground, after all).
$endgroup$
– Darrel Hoffman
2 days ago
$begingroup$
@cybernard Adding mass (not a function of gravity) to compensate for weight (a function of gravity) solves one problem (strength) by exacerbating another (mass). There's more mass. More energy is now required to move, speed up, slow down, and stop. There is no perfect solution.
$endgroup$
– JBH
2 days ago
$begingroup$
@cybernard Adding mass (not a function of gravity) to compensate for weight (a function of gravity) solves one problem (strength) by exacerbating another (mass). There's more mass. More energy is now required to move, speed up, slow down, and stop. There is no perfect solution.
$endgroup$
– JBH
2 days ago
1
1
$begingroup$
@Nyakouai, it is impossible to hit a golf ball on our own moon and drive it into orbit. 1, 2. Ice skating is perfectly safe (from the perspective of escape velocity). If such a risk did exist, you'd be ice skating on a very small asteroid.
$endgroup$
– JBH
2 days ago
$begingroup$
@Nyakouai, it is impossible to hit a golf ball on our own moon and drive it into orbit. 1, 2. Ice skating is perfectly safe (from the perspective of escape velocity). If such a risk did exist, you'd be ice skating on a very small asteroid.
$endgroup$
– JBH
2 days ago
|
show 1 more comment
$begingroup$
It would depend on the temperature and the gravity.
Iceskating works (and ice is slippery) because of a very thin layer of liquid water on its surface. It's a combination of temperature differences at the interface and pressure applied on the ice's surface that make it possible to skate on ice.
If the gravity is weak enough that a skater's weight doesn't produce enough pressure, and/or the temperature is low enough, it can become physically impossible for ice to melt when the skates' blades come in contact with it. When that happens the ice stops being slippery and behaves like other types of rocks.
You could probably imagine workarounds in some edge cases, for instance by heating the skates' blades to overcome too low a pressure applied on the ice or too low a temperature.
$endgroup$
add a comment |
$begingroup$
It would depend on the temperature and the gravity.
Iceskating works (and ice is slippery) because of a very thin layer of liquid water on its surface. It's a combination of temperature differences at the interface and pressure applied on the ice's surface that make it possible to skate on ice.
If the gravity is weak enough that a skater's weight doesn't produce enough pressure, and/or the temperature is low enough, it can become physically impossible for ice to melt when the skates' blades come in contact with it. When that happens the ice stops being slippery and behaves like other types of rocks.
You could probably imagine workarounds in some edge cases, for instance by heating the skates' blades to overcome too low a pressure applied on the ice or too low a temperature.
$endgroup$
add a comment |
$begingroup$
It would depend on the temperature and the gravity.
Iceskating works (and ice is slippery) because of a very thin layer of liquid water on its surface. It's a combination of temperature differences at the interface and pressure applied on the ice's surface that make it possible to skate on ice.
If the gravity is weak enough that a skater's weight doesn't produce enough pressure, and/or the temperature is low enough, it can become physically impossible for ice to melt when the skates' blades come in contact with it. When that happens the ice stops being slippery and behaves like other types of rocks.
You could probably imagine workarounds in some edge cases, for instance by heating the skates' blades to overcome too low a pressure applied on the ice or too low a temperature.
$endgroup$
It would depend on the temperature and the gravity.
Iceskating works (and ice is slippery) because of a very thin layer of liquid water on its surface. It's a combination of temperature differences at the interface and pressure applied on the ice's surface that make it possible to skate on ice.
If the gravity is weak enough that a skater's weight doesn't produce enough pressure, and/or the temperature is low enough, it can become physically impossible for ice to melt when the skates' blades come in contact with it. When that happens the ice stops being slippery and behaves like other types of rocks.
You could probably imagine workarounds in some edge cases, for instance by heating the skates' blades to overcome too low a pressure applied on the ice or too low a temperature.
edited 2 days ago
answered 2 days ago
Denis de BernardyDenis de Bernardy
36118
36118
add a comment |
add a comment |
Sean Kindle is a new contributor. Be nice, and check out our Code of Conduct.
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1
$begingroup$
nytimes.com/2006/02/21/science/21ice.html
$endgroup$
– Ville Niemi
2 days ago