Could a research base on Mercury be the key to unlocking solar mysteries?

In summary, building a research base on Mercury may have its challenges, such as the extreme temperatures and the difficulty of landing due to its lack of atmosphere. However, it also has potential benefits, such as the ability to gather valuable information about solar flares and storms, harnessing solar energy, and potentially accessing water from ice at the planet's North Pole. It may also have a lower surface gravity compared to Earth, which could make movement easier. However, it is worth considering if living on a planet is truly necessary for conducting research, as observing the Sun can be done from a free-flying spacecraft.
  • #1
GTOM
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Lets suppose in not so far future we want to build a research base on Mercury.
What would be the main hardships and benefits? For the later, it could gain lots of information about solar flares and storms, solar panels could give it more than enough energy, and if it is landed on North pole it could gather water from ice, less payload to ship.
 
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  • #2
GTOM said:
Lets suppose in not so far future we want to build a research base on Mercury.
What would be the main hardships and benefits? For the later, it could gain lots of information about solar flares and storms, solar panels could give it more than enough energy, and if it is landed on North pole it could gather water from ice, less payload to ship.

There isn't much ice on Mercury, except a little bit that may exist in some craters, so that is not an option.

We can send probes into orbit around the sun (such as SOHO). We can learn about solar flares, etc., and use the solar panels to gain energy.

The only real advantage I can see is that we can send a rover on Mercury, similar to those of Mars. We can learn more about composition, and maybe do some drilling.
 
  • #3
How do you get there? You have to pick up a lot of speed to land on Mercury - MESSENGER took 6 years and a billion miles to do it.
 
  • #4
Vanadium 50 said:
How do you get there? You have to pick up a lot of speed to land on Mercury - MESSENGER took 6 years and a billion miles to do it.
How much more delta-v required than to Mars?
 
  • #5
GTOM said:
How much more delta-v required than to Mars?

About double I believe.
 
  • #6
Clever Penguin said:
There isn't much ice on Mercury, except a little bit that may exist in some craters, so that is not an option.

We can send probes into orbit around the sun (such as SOHO). We can learn about solar flares, etc., and use the solar panels to gain energy.

The only real advantage I can see is that we can send a rover on Mercury, similar to those of Mars. We can learn more about composition, and maybe do some drilling.

http://www.nytimes.com/2012/11/30/s...enger- spacecraft -findings-suggest.html?_r=0

According to that one, the amount of ice isn't that small.
How do get there, well i had the assumption that nuclear powered spacecraft isn't that far future.
 
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  • #8
There's no issue with getting to Mercury except perhaps that we don't currently have a launch vehicle powerful enough to lift the equipment required to build and maintain a research facility into space. Conventional rockets would work just fine for actually getting out of Earth's orbit and getting into Mercury's assuming you can lift the whole thing into Earth orbit. Lighter weight space propulsion technology would, obviously, make this entire process easier and less expensive, as you'd have less "dead weight" to carry.

GTOM said:
According to that one, the amount of ice isn't that small.

Perhaps, but this probably isn't just a big block of ice sitting at the bottom of a crater. The ice is most likely buried under the regolith and may be incorporated into the structure of the dirt and rock, making it very difficult to extract in large quantities. If so, the equipment needed to harvest the ice would need to be shipped from Earth and will have to be maintained. I have no idea how complex such machinery would be, so I don't know if this would be a serious challenge or merely a "normal" challenge. :biggrin:

Assuming you can establish a research facility under the surface, the challenges are mostly the same as with any other attempt to create a permanent or semi-permanent habitat beyond Earth.
 
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  • #9
Drakkith said:
There's no issue with getting to Mercury
A big issue could be that the temperature of the skin of the craft would be round about 400°C for some while. Quite a refrigeration trick to achieve with human cargo inside. I suppose there could be clever satellite tricks like having a shiny surface on the sunny side and a good black radiator on the shadow side but I wouldn't be a trivial problem over a protracted length of time. Shuttle tiles wouldn't do the trick.
 
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  • #10
True. You don't want a Christmas roast arriving at Mercury instead of you research team...
 
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  • #11
GTOM said:
Lets suppose in not so far future we want to build a research base on Mercury.
What would be the main hardships and benefits? For the later, it could gain lots of information about solar flares and storms, solar panels could give it more than enough energy, and if it is landed on North pole it could gather water from ice, less payload to ship.
I wish to ask: why is it supposed to be necessary to live on a planet? Or a planetlike body?

Observing the Sun can easily be done from a free-flying spacecraft . That saves on the rocket fuel that would be necessary to land on a planet.

Mercury has a surface gravity about 2/5 the Earth's, close to Mars's. That means that it would be easier to move around on Mercury than on the Earth, but that also means that one needs a high-thrust rocket to land on it. The planet lacks an atmosphere, which means that one cannot use an atmosphere to slow down, meaning that a rocket must make the full delta-V necessary. Mercury's escape velocity is 4.25 km/s, and its surface-satellite velocity is 3.01 km/s. From Tsiolkovsky's rocket equation, this means a mass ratio of 2.7 for arriving from orbit and 4.1 for arriving at escape velocity. You'd need the same mass ratio for departing.
 
  • #12
lpetrich said:
I wish to ask: why is it supposed to be necessary to live on a planet?
That's a question that people don't seem to ask as often as they should. Would someone really need to go down inside a volcano in order to monitor what's going on or spend a year on the ocean floor, observing the worms?
There are loonies queuing up for a one way ticket to Mars, too. What's it all about?
 
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  • #13
sophiecentaur said:
That's a question that people don't seem to ask as often as they should. Would someone really need to go down inside a volcano in order to monitor what's going on or spend a year on the ocean floor, observing the worms?
There are loonies queuing up for a one way ticket to Mars, too. What's it all about?

The analogy isn't really good. If one send a research team to another planet, they can just return anytime they want. A base can offer more space and comfort than a ship.
 
  • #14
GTOM said:
If one send a research team to another planet, they can just return anytime they want.

They can't or can return anytime the want? The latter is certainly not true.
 
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  • #15
Drakkith said:
They can't or can return anytime the want? The latter is certainly not true.
Sorry, missing t.
 
  • #16
GTOM said:
The analogy isn't really good. If one send a research team to another planet, they can just return anytime they want. A base can offer more space and comfort than a ship.
The question still stands as to why it is so important that humans should be there in the first place. Remember Beagle II ? You certainly would have remembered if a manned expedition had disappeared that way. Fact is that unmanned expeditions are a fraction of the cost of manned ones and their potential capabilities are improving as fast if not faster than the propulsion technology to take expeditions. Space exploration is basically Engineering and one serious concern of any Engineer is to ask whether a project is actually worth the cost. I am a realist and not a spoilsport.
 
  • #17
From my understanding, Mercury has no axis. It doesn't tilt. So its poles never see the sun, hence the abundance of ice.
 
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  • #18
Sue Rich said:
From my understanding, Mercury has no axis. It doesn't tilt. So its poles never see the sun, hence the abundance of ice.
Mercury rotates about its axis in 58.7 days (with respect to the stars). It orbits the Sun in 88 days. That's a 3:2 ratio, so a day on Mercury is 176 days.
 
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  • #20
D H said:
Mercury rotates about its axis in 58.7 days (with respect to the stars). It orbits the Sun in 88 days. That's a 3:2 ratio, so a day on Mercury is 176 days.
I had no idea, this is interesting. http://cseligman.com/text/planets/mercuryrot.htm
 
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Related to Could a research base on Mercury be the key to unlocking solar mysteries?

1. What is the average temperature on Mercury?

The average temperature on Mercury ranges from -173 degrees Celsius to 427 degrees Celsius. This extreme temperature difference is due to Mercury's close proximity to the sun, causing one side of the planet to face the sun and the other side to face away.

2. How long does it take for Mercury to orbit the sun?

Mercury's orbit around the sun takes approximately 88 Earth days. This is the shortest orbit of all the planets in our solar system.

3. What is the composition of Mercury's surface?

Mercury's surface is composed mostly of rocky material, including silicate rocks and metals like iron and nickel. The surface also has a high abundance of sulfur and small amounts of water ice have been discovered in some polar regions.

4. Why is it difficult to study Mercury?

It is difficult to study Mercury due to its close proximity to the sun, making it hard to observe from Earth. The planet also has a thin atmosphere, making it challenging for spacecraft to maintain orbit. Additionally, Mercury's surface experiences extreme temperatures and high levels of solar radiation, making it a hostile environment for instruments and technology.

5. What have we learned from past research on Mercury?

Through past research, we have learned that Mercury has a large iron core and a thin rocky mantle, similar to the structure of Earth. We have also discovered evidence of water ice on the planet's surface and have gained a better understanding of its geological history, including the formation of its many craters and volcanic features.

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