Project Icarus it was called, the fourth space program of that name and the first for which it was appropriate. Long before Jacob’s parents were born—before the Overturn and the Covenant, before the Power Satellite League, before even the full flower of the old Bureaucracy—old grandfather NASA decided that it would be interesting to drop expendable probes into the Sun to see what happened.
They discovered that the probes did a quaint thing when they got close. They burned up.
In America’s “Indian Summer” nothing was thought impossible. Americans were building cities in space—a more durable probe couldn’t be much of a challenge!
Shells were made, with materials that could take unheard of stress and whose surfaces reflected almost anything. Magnetic fields guided the diffuse but tremendously hot plasmas of corona and chromosphere around and away from those hulls. Powerful communications lasers pierced the solar atmosphere with two-way streams of commands and data.
Still, the robot ships burned. However good the mirrors and insulation, however evenly the superconductors distributed heat, the laws of thermodynamics still held. heat will pass from a higher temperature to a zone where the temperature is lower, sooner or later.
The solar physicists might have gone on resignedly burning up probes in exchange for fleeting bursts of information had Tina Merchant not offered another way. “Why don’t you refrigerate?” she asked. “You have all the power you want. You can run refrigerators to push heat from one part of the probe to another.”
Her colleagues answered that, with superconductors, equalizing heat throughout was no problem.
“Who said anything about equalizing?” the Belle of Cambridge replied. “You should take all excess heat from the part of the ship were the instruments are and pump it into another part where the instruments aren’t.”
“And that part will burn up!” one colleague said. “Yes, but we can make a chain of these ‘heat dumps,’” said another engineer, slightly more bright. “And then we can drop them off, one by one …”
“No, no you don’t quite understand.” The triple Nobel Laureate strode to the chalkboard and drew a circle, then another circle within.
'Here!" She pointed to the inner circle. “You pump your heat into here until it is, for a short time, hotter than the ambient plasma outside of the ship. Then, before it can do harm there, you dump it out into the chromosphere.”
“And how,” asked a renowned physicist, “do you expect to do that?”
Tina Merchant had smiled as if she could almost see the Astronautics Prize held out to her. “Why I’m surprised at all of you!” she said. “You have onboard a communications laser with a brightness temperature of millions of degrees! Use it!”
Enter the age of the Solar Bathysphere. Floating in part by buoyancy and also by balancing atop the thrust of their refrigerator lasers, probes lingered for days, weeks, monitoring the subtle variations at the Sun, that wrought weather on the Earth.
You need to think about how an infrared laser works. You’re taking electricity, converting it into light and then focusing the light.
So you’d need to take the heat from your GPUs, inefficiently convert it into electricity (a lot of it would remain as heat), then inefficiently convert electricity into light (much of the electricity would turn back into heat in this process) and then focus the light away from the space data centre.
Now, we already have a process for moving heat away from things as infrared light, without going through all those steps (which would just reduce the efficiency of the process). It’s called a radiator, and it’s how we cool things in space. That’s literally where the name comes from; they radiate heat away as infrared light. That’s why hot things glow in thermal cameras.
It is incredibly inefficient. Radiation (ie, infrared light) is, by far, the worst way of cooling things. But in space its the only option you have, because there’s no convection or conduction across vacuum.
A top end GPU puts out about 1,000 watts of waste heat. The entire International Space Station has enough cooling for 14 of those, if it was doing nothing else whatsoever. An average server rack contains 72. The ISS cost $100 billion dollars. So at a minimum you’re looking at around $500 billion to put one single server rack in space. And that’s before accounting for the heat from the sun, which we can’t avoid because we need solar power to run this thing. So probably closer to a trillion. In other words, twice the already ludicrous price tag of Sam Altman’s “Stargate” project. For a single server rack.
Hmm, this has me thinking about the stealth ships in The Expanse. The engineering needed to make it work makes me want to cry, but in principle you could run a Peltier cooler with a swappable heat sink.
To be clear, I don’t think this is a viable option, but it’s interesting to think about.
Basically the way you would make a stealth spaceship would be by focusing as much as possible on energy efficiency. At every juncture you would try to use as little power as possible, and use every bit of it as efficiently as possible, so that you’re not remitting waste. That waste, in the form of heat, radio waves, etc, is what gets you spotted.
You could also run heatsinks temporarily for enhanced stealth as you suggest, then open up radiators to cool them - or eject them - once it’s safe to do so.
(For the Elite: Dangerous players, yes, that game got it right.)
The entire ISS has 14GW of cooling (and a lot of that just goes towards keeping the sun from cooking it). A single server rack can produce around 72GW of heat.
The ISS cost about $100 billion.
Basically, if you took the entire budget of Sam Altman’s “Stargate” project (money that, to be clear, he does not have and will not get) and put it into space data centres you might, optimistically, put one rack in space.
Most data centres have dozens to hundreds.
You’re absolutely correct, but “quite big” might be the single biggest understatement I’ve seen in my life.
I don’t know if it would work but… Could an infrared laser expel enough heat?
— David Brin, Sundiver, 1980
Here’s an interesting discussion about the concept, with Brin himself explaining his reasoning.
You need to think about how an infrared laser works. You’re taking electricity, converting it into light and then focusing the light.
So you’d need to take the heat from your GPUs, inefficiently convert it into electricity (a lot of it would remain as heat), then inefficiently convert electricity into light (much of the electricity would turn back into heat in this process) and then focus the light away from the space data centre.
Now, we already have a process for moving heat away from things as infrared light, without going through all those steps (which would just reduce the efficiency of the process). It’s called a radiator, and it’s how we cool things in space. That’s literally where the name comes from; they radiate heat away as infrared light. That’s why hot things glow in thermal cameras.
It is incredibly inefficient. Radiation (ie, infrared light) is, by far, the worst way of cooling things. But in space its the only option you have, because there’s no convection or conduction across vacuum.
A top end GPU puts out about 1,000 watts of waste heat. The entire International Space Station has enough cooling for 14 of those, if it was doing nothing else whatsoever. An average server rack contains 72. The ISS cost $100 billion dollars. So at a minimum you’re looking at around $500 billion to put one single server rack in space. And that’s before accounting for the heat from the sun, which we can’t avoid because we need solar power to run this thing. So probably closer to a trillion. In other words, twice the already ludicrous price tag of Sam Altman’s “Stargate” project. For a single server rack.
Hmm, this has me thinking about the stealth ships in The Expanse. The engineering needed to make it work makes me want to cry, but in principle you could run a Peltier cooler with a swappable heat sink.
To be clear, I don’t think this is a viable option, but it’s interesting to think about.
Basically the way you would make a stealth spaceship would be by focusing as much as possible on energy efficiency. At every juncture you would try to use as little power as possible, and use every bit of it as efficiently as possible, so that you’re not remitting waste. That waste, in the form of heat, radio waves, etc, is what gets you spotted.
You could also run heatsinks temporarily for enhanced stealth as you suggest, then open up radiators to cool them - or eject them - once it’s safe to do so.
(For the Elite: Dangerous players, yes, that game got it right.)
You could cool them through radiative panels but you would need quite big panels to radiate away the heat a data center produces.
The entire ISS has 14GW of cooling (and a lot of that just goes towards keeping the sun from cooking it). A single server rack can produce around 72GW of heat.
The ISS cost about $100 billion.
Basically, if you took the entire budget of Sam Altman’s “Stargate” project (money that, to be clear, he does not have and will not get) and put it into space data centres you might, optimistically, put one rack in space.
Most data centres have dozens to hundreds.
You’re absolutely correct, but “quite big” might be the single biggest understatement I’ve seen in my life.