Survival on Mars: Radiation & Temperature Challenges

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In summary: The conversation revolves around the challenges of surviving and colonizing Mars, including radiation protection and temperature issues, as well as the importance of addressing basic needs such as food, water, and air. The discussion also touches on the challenges of maintaining a base and producing necessary resources locally, as well as the potential of utilizing local resources like Martian soil.
  • #246
enorbet said:
I don't assume any level of confidence past much more than a decade or two.
Well, we won't have manned flights to Mars for a decade or two.

Also, one manned mission to one robot is not a fair comparison. For the price of a manned mission for a few months you can send 10+ robots, exploring 10 different locations potentially for years.
enorbet said:
Tangent - One possibly important area of difference between men and machines is the response when predictions are in error. I wonder how any machine now or in the near future would deal with fundamental errors such as discovered by Vera Rubin in galactic rotation, or the various Nobel Laureates seeking to measure how much expansion was slowing down. It would take a savvy programmer to "if then this" such deep prejudice. It may be a cause for pause and check in humans but may cause a computer to crash :)
Such a fundamental discovery won't happen on a daily basis, and then light travel delay does not matter (even humans would ask for assistance from experts on Earth). If it is a mission-critical thing: losing a rover is better than losing an astronaut.
 
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  • #248
mfb said:
Well, we won't have manned flights to Mars for a decade or two.

Already agreed upon and stated by most here, including myself, throughout this thread.

mfb said:
Also, one manned mission to one robot is not a fair comparison. For the price of a manned mission for a few months you can send 10+ robots, exploring 10 different locations potentially for years.Such a fundamental discovery won't happen on a daily basis, and then light travel delay does not matter (even humans would ask for assistance from experts on Earth). If it is a mission-critical thing: losing a rover is better than losing an astronaut.

If we agree that at least for a little while longer it is not possible to make anything close to a human capacity equivalent machine in the same volume and mass and that perhaps the greatest leap from walking on the Moon to walking on Mars, is money applied over that decade or two, and furthermore that it is an important goal for Mankind to become Space a faring species, all I'm asking is that a wee bit more money and thinking be spent to that end.

Please do recall that most experts in the field thought JFKs challenge in 1961 to put a man on the moon by the end of the decade as farfetched and fanciful given it was little more than 2 years after we finally managed to put "a basketball" in orbit. It is now quite impossible to imagine what the world would look like and what it would mean to live in it had that challenge, and those funds (which iirc at it's peak never exceeded ~4.5% of the annual Federal Budget, but is currently less than one half of 1%) not occurred.

FWIW of course humans on Mars would still need coms to Earthbound humans, but not anywhere near as often as machines, plus humans accompanied by machines would reduce that delay as well. That substantially improves efficiency and benefit per unit cost.
 
  • #249
enorbet said:
If we agree that at least for a little while longer it is not possible to make anything close to a human capacity equivalent machine in the same volume and mass and that perhaps the greatest leap from walking on the Moon to walking on Mars, is money applied over that decade or two, and furthermore that it is an important goal for Mankind to become Space a faring species, all I'm asking is that a wee bit more money and thinking be spent to that end.
We agree, and money does get spent already.

I'm not sure if space exploration would have looked completely different without Apollo. LEO space stations didn't need that project, and the mission to moon could have been done at some later point.
 
  • #250
mfb said:
We agree, and money does get spent already.

Note I didn't say no money was being spent, only that it is roughly 1/10th of Apollo era now.
mfb said:
I'm not sure if space exploration would have looked completely different without Apollo. LEO space stations didn't need that project, and the mission to moon could have been done at some later point.

Well I did say "the world and life in it" but even if we just focus on space exploration, please note that Russian exploration developed over somewhat different lines (big boosters) because they were a bit behind the US in miniaturization and computers back then. Considering Saturn V was developed specifically for Apollo, there is at least some doubt that US boosters would be as advanced as they are now, or hope soon to be. That must certainly qualify as a "Butterfly Effect" event, impossible to calculate the impact of never having built it nor fostering the level of inter disciplinary scientific and corporate cooperation required by the Apollo rush to the moon.
 
  • #251
mfb said:
Why do you expect a linear relationship between g on the surface and atmospheric pressure?

Without solar wind, the key quantity is the average kinetic energy of the molecules (in the upper atmosphere) compared to the energy necessary to escape from the planet. The escape velocity is about 5 km/s for Mars, for Earth it is 11.2 km/s.

Let's take Earth: T=2000 K, E=3/2 kT = 250 meV (the hot temperature is driven by solar radiation).
The necessary energy to escape for Helium is ##\frac{1}{2} m_{He} v^2_{esc} = 2.6 eV = 10.4 * 250 meV.
While it is rare, some helium atoms will get 10 times their average energy (and move upwards), and escape. Over geological timescales, most helium atoms escape.
Elementary nitrogen needs 3.5 times this energy, or ~35 times the average energy. That is really rare. Molecular nitrogen needs even more energy.

=> on Earth, helium escapes, but nitrogen does not (not including effects of solar wind).

Sorry, but still don't understand it fully. So escape speed is half on Mars (compared to Earth), kinetic energy is divided by four. But the rad dose from Sun is also about half (based on square of distance). That makes me think (of course i can be wrong), that chance to escape is twice that much, is that enough for such thin air?
Lighter elements also escape from Earth. Isnt it possible, that while lighter elements escaped from Mars, the heavier ones (nitrogen, molecules with oxygen) are rather frozen, captured by regolith?
How can we estimate the amount of ice on the caps?
About the speculation, what can be underground : https://www.nasaspaceflight.com/2015/09/nasa-confirms-salt-water-flows-mars/
 
  • #252
The chance of thermal escape depends on the temperature, which depends on the solar radiation but not in a linear way. The temperature on Mars is more than half the temperature of Earth (absolute temperature of course). Yes, thermal escape is significantly easier on Mars. Which means helium escapes very quickly, but the heavier elements still stay around for a long time.
 
  • #253
mfb said:
The chance of thermal escape depends on the temperature, which depends on the solar radiation but not in a linear way. The temperature on Mars is more than half the temperature of Earth (absolute temperature of course). Yes, thermal escape is significantly easier on Mars. Which means helium escapes very quickly, but the heavier elements still stay around for a long time.

Thank you, but if you don't mind, i'd still like to ask.
Venus avarage temperature is 737 Kelvin, more than double of Earth, while gravity is smaller. Why doesn't it loose its atmosphere?
 
  • #254
See the calculation I did in post 111. The temperature at the surface does not matter, the temperature is relevant at a place where atoms can escape without further collisions. The atmosphere of Earth is quite hot at that place, and still most elements cannot escape.
 
  • #255
mfb said:
See the calculation I did in post 111. The temperature at the surface does not matter, the temperature is relevant at a place where atoms can escape without further collisions. The atmosphere of Earth is quite hot at that place, and still most elements cannot escape.

Ok, thanks.
 
  • #258
It should be easier on Mars as you directly have water ice. Maybe something like this: Dig or drill through the surface layer (1-10m) and put the material aside (can be used to cover habitats as radiation shielding). Continue excavating (now with >=50% water ice content), but this time put the material in a box, close the box once full. Heat it (concentrated sunlight, or worst case electricity).

(A) Let the water in the produced slush leave the chamber via a series of filters. Pressure can be provided by evaporation, some stirring looks useful but no pumps are needed. Dump the rest, clean the filters if necessary, repeat.

(B) Alternatively, use the vapor only: let it go to a box that is not heated, then just wait. Water/ice will accumulate there. Takes longer, even with a heat exchanger system, but the water will be very pure. Once the rate of water extracted gets too low, dump the rest, repeat.
 
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  • #259
How much delta-V could be saved by aerobreaking when descend to Mars? 1-2km/s?

What could be the daily routine to sustain a small colony with local resources?
Cleanse solar panels? Filter the dust for peroxides, water, dry ice? Is it something like dewfall on Mars?
Fergitilize plants, check everything, whether maintenance needed?
 
  • #260
GTOM said:
How much delta-V could be saved by aerobreaking when descend to Mars? 1-2km/s?
Coming from Earth, you enter the atmosphere at about 6 km/s. A heat shield followed by a parachute can slow you down to less than 1 km/s, which leads to about 5km/s delta_v from the atmosphere.

Take care of food production, fix things that break (preferably remotely if outside), produce new things and install them.

The atmosphere has a little bit of water vapor, but extracting ice from the ground looks much more interesting.
 
  • #262
Chronos said:
Spending a long time in cramped quarters is not fun and provokes enduring psychological issues. A mission to Mars would land a menagerie of psychologically impaired people in a hostile. alien environmnet. That is a recipe for disaaster, IMO.
Exactly. I think that we should concentrate on building large, comfortable free-flying space stations (perhaps with spinning to create artificial gravity) and build and sustain them with robot mining, so they have freely available resources. Then we can head off to Mars in comfort and safety, using plenty of shielding, using the large amounts of fuel available, having lots of know-how about growing our own food, and with off-the-shelf mining robots and virtual reality controllers to operate them. We stop at Deimos to find easily available resources, and send robots down to prospect for a good landing site. Or just to prospect.
 
  • #263
Magnetic fields are irrelevant on timescales interesting for humans. Sure, if you install such a magnetic field and wait for a few million years, Mars will have a slightly thicker atmosphere. But who wants to wait that long? And who wants to use 21st century technology for a multi-million-year project? People in 3000, assuming humans are still around, will laugh at our attempts, long before the artificial magnetic field would have any notable effect.

Similarly: If we find a way to give Mars an atmosphere, just do it and don't worry about the magnetic field. It doesn't make a difference if we add it in 2100 or in the year 210,000.
 
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  • #264
Al_ said:
Exactly. I think that we should concentrate on building large, comfortable free-flying space stations (perhaps with spinning to create artificial gravity) and build and sustain them with robot mining, so they have freely available resources. Then we can head off to Mars in comfort and safety, using plenty of shielding

...and meet children of those who dared to endure "cramped quarters".
 
  • #265
mfb said:
Magnetic fields are irrelevant on timescales interesting for humans. Sure, if you install such a magnetic field and wait for a few million years, Mars will have a slightly thicker atmosphere. But who wants to wait that long? And who wants to use 21st century technology for a multi-million-year project? People in 3000, assuming humans are still around, will laugh at our attempts, long before the artificial magnetic field would have any notable effect.

Similarly: If we find a way to give Mars an atmosphere, just do it and don't worry about the magnetic field. It doesn't make a difference if we add it in 2100 or in the year 210,000.

What about the other issue, radiation protection? (As far as i know, high speed charged particles are a significant percent of radiation hazard) Simply pack another layer to houses easier, however, glass houses are better for plants, they also need rad protection.
Also if we build in a space station in orbit (to eventually convert it to a big mothership for travel) than thicker walls require more material, and launch from surface is expensive.
 
  • #266
The proposed magnetic field is irrelevant for galactic cosmic rays, and probably doesn't much against strong solar flares. People on Mars will need radiation shielding anyway - either an atmosphere or some solid material.
GTOM said:
Also if we build in a space station in orbit (to eventually convert it to a big mothership for travel) than thicker walls require more material, and launch from surface is expensive.
How is that related to the discussed magnetic field?
 
  • #267
mfb said:
The proposed magnetic field is irrelevant for galactic cosmic rays, and probably doesn't much against strong solar flares. People on Mars will need radiation shielding anyway - either an atmosphere or some solid material.How is that related to the discussed magnetic field?

So, a strong magnetic field doesn't seem to be an easier way for rad protection, than simply lift more mass (whether on a planet, or during the trip to Mars).
 
  • #268
I really feel that any permanent residency on Mars is reallistically a LONG way off.
Sure we could (technology and determination, not budget/psychology)establish some form of habitat that could sustain life within 50 years - however, so few people would be there and a single 'disaster' could threaten everything.
For maybe 6 month, 2 maybe even 5 year extended trials - an equivalent kind of research station (As is found in Arctic, Antartic, now the ISS) seems to be a tried and tested foray into remote and dangerous locations.

The real benefits, I feel, will come from enhanced automation capabilities of robots and AI in establishing and generally maintaining such a station until such occasions as human lives are absolutely required.

LONG term I see a larger scale terraforming (habitat, unlikely to be the entire world) endeavour to ensure a more sustainable, ' comfortable' and safer environs for people
 
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  • #269
_PJ_ said:
I really feel that any permanent residency on Mars is reallistically a LONG way off.
Sure we could (technology and determination, not budget/psychology)establish some form of habitat that could sustain life within 50 years - however, so few people would be there and a single 'disaster' could threaten everything.
For maybe 6 month, 2 maybe even 5 year extended trials - an equivalent kind of research station (As is found in Arctic, Antartic, now the ISS) seems to be a tried and tested foray into remote and dangerous locations.

Antarctic is not developed/colonized due to treaties prohibiting that.
ISS is a tried and tested foray how to NOT go about expanding into space.

I suggest we try something new, which is also a rather old method: after we have initial tech working reasonably well, send people to Mars who volunteer to go there intending to stay. Colonies on Earth were not generally planned as 5-year stints. _That_ method often worked remarkably better than ISS or our Moon program.
And if you don't like cramped spaces, please reread carefully: "volunteer". Nobody will force _you_ to go.
 
  • #270
nikkkom said:
intending to stay.
That's the problem really.
 
  • #271
nikkkom said:
...and meet children of those who dared to endure "cramped quarters".
- as they head in the opposite direction!
 
  • #272
nikkkom said:
I suggest we try something new, which is also a rather old method: after we have initial tech working reasonably well, send people to Mars who volunteer to go there intending to stay. Colonies on Earth were not generally planned as 5-year stints. _That_ method often worked remarkably better than ISS or our Moon program.
And if you don't like cramped spaces, please reread carefully: "volunteer". Nobody will force _you_ to go.

We'd get a better return on investment by setting up closed ecosystems on Earth. For the price (and risk) of shipping infrastructure, an ecosystem and a nascent local economy to Mars we could try out multiple parallel tests on Earth. Iteratively grow increasingly self sufficient cities in the world's deserts.
 
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  • #273
A desert without any readily avaivable air, water or organic resources would make that scenario more realistic.
 
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  • #274
nikkkom said:
Colonies on Earth were not generally planned as 5-year stints. _That_ method often worked remarkably better than ISS or our Moon program.
Colonies on Earth were built with different motivations, and in different places.
You might not like the ISS, but it is still our longest-running and most successful project to learn more about life in space (plus all the other experiments done there).
Chronos said:
A desert without any readily avaivable air, water or organic resources would make that scenario more realistic.
Water ice is quite readily available in places interesting for humans, and CO2 is available everywhere.
 
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  • #275
nikkkom said:
...and meet children of those who dared to endure "cramped quarters".

Why not have children in the "large, comfortable free-flying space" maternity ward station? If people want to visit Mar's surface they could still go when they are adults and not pregnant.
 
  • #276
Maybe self sufficient colonies on Antarctica?
Solar power ok, ice ok, extreme cold ok.
 
  • #277
GTOM said:
Maybe self sufficient colonies on Antarctica?
Solar power ok, ice ok, extreme cold ok.

Equatorial Mars gets more sun than Antarctica. The sun is up every 24 hours. 6 month battery supply is painful.

It often feels colder at -1°C in damp weather than a dry -15 °C. Low pressure argon is an excellent insulator. The measured temperatures on Antarctica and in Gail crater are comparable. Heat loss would be more serious in Antarctica.

There is a lot of spare room available in the equatorial mid pacific. There is no ice yet but you could make it with a solar powered freezer.

Saskatchewan has a large tar sands area. The Canadians are already tearing the face off the surface and then replacing it. You could bury a lot of colony habitats under the sand. SpaceX wants to charge $500k for tickets to the Mars colony. That price includes $millions per colonist in subsidies which could be lowered or even removed for a Saskatchewan colony. People willing to pay the $500k dollars will get a cramped space in a hole under the tundra and tunnel access to a sealed greenhouse where they can compost their own wastes. If the colonist's children grow up and decide they do not like living in a hole in Saskatchewan they could be evacuated by bus.
 
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  • #278
mfb said:
You might not like the ISS, but it is still our longest-running and most successful project to learn more about life in space (plus all the other experiments done there).

I completely agree with you. ISS is a valuable project. Its main lesson: whatever you do, do not let government bureaucrats run your space project.
For those not convinced yet, we also run a duplicate experiment called "SLS". Elon Musk just wrote its death note by launching Falcon Heavy.
 
  • #279
stefan r said:
Why not have children in the "large, comfortable free-flying space" maternity ward station? If people want to visit Mar's surface they could still go when they are adults and not pregnant.

I still prefer "If people want to visit Mar's surface they should be allowed to, _whenever they want_, not when someone else allows them to". But then, I'm this dangerous "classical liberal", with his outdated ideas of "freedom" and "limited government"...
 
  • #280
nikkkom said:
I still prefer "If people want to visit Mar's surface they should be allowed to, _whenever they want_, not when someone else allows them to". But then, I'm this dangerous "classical liberal", with his outdated ideas of "freedom" and "limited government"...

I was assuming that fetuses grown in odd gravity might turn into odd children or come out sick and dying.

I have no idea how childbirth itself would feel on Earth or anywhere else. Some midwives claim it is easier to give birth upright because gravity assists. In a space station you could adjust rpms or radius to get an ideal gravity setting.

It occurred to me that you could test birth under various gravitational conditions using the vomit comet. With in flight refueling the plane could keep flying for a long duration. You could set the autopilot to increase g-force during contractions and switch to low-g in between. This might be the worst idea I have had in a long time so I thought I should share it.
 
<h2>1. What are the main challenges of surviving on Mars?</h2><p>The main challenges of surviving on Mars include extreme radiation levels, harsh temperature fluctuations, lack of breathable air, and limited access to resources.</p><h2>2. How does radiation on Mars affect human health?</h2><p>Radiation on Mars is significantly higher than on Earth due to the planet's thin atmosphere and lack of a protective magnetic field. This can lead to increased risk of cancer, damage to the central nervous system, and other health issues.</p><h2>3. What measures can be taken to protect against radiation on Mars?</h2><p>To protect against radiation on Mars, astronauts can use shielding materials, such as lead or water, to reduce exposure. They can also limit their time outside and use specialized suits and habitats designed to block radiation.</p><h2>4. How do temperature fluctuations on Mars impact survival?</h2><p>Mars experiences extreme temperature fluctuations, with average temperatures ranging from -80°F to -195°F. This can make it difficult to maintain a habitable environment and can also affect equipment and technology.</p><h2>5. What are the potential solutions for surviving the harsh conditions on Mars?</h2><p>Potential solutions for surviving on Mars include developing advanced technologies for radiation protection, creating self-sustaining habitats, and finding ways to terraform the planet to make it more habitable. Additionally, conducting further research and experiments on the planet will help us better understand how to adapt and survive in its unique environment.</p>

1. What are the main challenges of surviving on Mars?

The main challenges of surviving on Mars include extreme radiation levels, harsh temperature fluctuations, lack of breathable air, and limited access to resources.

2. How does radiation on Mars affect human health?

Radiation on Mars is significantly higher than on Earth due to the planet's thin atmosphere and lack of a protective magnetic field. This can lead to increased risk of cancer, damage to the central nervous system, and other health issues.

3. What measures can be taken to protect against radiation on Mars?

To protect against radiation on Mars, astronauts can use shielding materials, such as lead or water, to reduce exposure. They can also limit their time outside and use specialized suits and habitats designed to block radiation.

4. How do temperature fluctuations on Mars impact survival?

Mars experiences extreme temperature fluctuations, with average temperatures ranging from -80°F to -195°F. This can make it difficult to maintain a habitable environment and can also affect equipment and technology.

5. What are the potential solutions for surviving the harsh conditions on Mars?

Potential solutions for surviving on Mars include developing advanced technologies for radiation protection, creating self-sustaining habitats, and finding ways to terraform the planet to make it more habitable. Additionally, conducting further research and experiments on the planet will help us better understand how to adapt and survive in its unique environment.

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