Difference between revisions of "Volatiles"

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===Helium 3, Special Considerations===
 
===Helium 3, Special Considerations===
 
[[Helium 3]] is a special case. As detailed in [[Harrison Schmitt]]'s book "Return to the Moon", it is the only lunar resource worth shipping back to the surface of the Earth at this time. In the long term, it could be used in fusion power plants on Earth as a source of clean, non-carbon energy. This type of power plant is currently under development, but is not yet near commercial operation.
 
[[Helium 3]] is a special case. As detailed in [[Harrison Schmitt]]'s book "Return to the Moon", it is the only lunar resource worth shipping back to the surface of the Earth at this time. In the long term, it could be used in fusion power plants on Earth as a source of clean, non-carbon energy. This type of power plant is currently under development, but is not yet near commercial operation.
   
+
 
 
Helium 3 is very rare on Earth and only a minor component of the lunar regolith volatiles. To refine enough to feed a power plant for a medium size city would require processing regolith at the rate of about 50 tons an hour. The scale of processing needed is directly reflected in the large scale of the proposed [[Sandworms|Sandworm]]. A commercial operation of this size on Earth would not be considered a very large facility, but we are talking about the Moon.
 
Helium 3 is very rare on Earth and only a minor component of the lunar regolith volatiles. To refine enough to feed a power plant for a medium size city would require processing regolith at the rate of about 50 tons an hour. The scale of processing needed is directly reflected in the large scale of the proposed [[Sandworms|Sandworm]]. A commercial operation of this size on Earth would not be considered a very large facility, but we are talking about the Moon.
   
+
 
 +
====Chronic shortage of Helium-3 isotope could be resolved by mining lunar regolith====
 +
 
 +
Demand for Helium-3 is steadily increasing primarily for Neutron detectors.for cargo screening (for illegal fissile material).
 +
 
 +
In 2008, a total of 80,000 liters of He3 were sold worldwide, at an average price of $100, i.e. total market of $8 million -
 +
 
 +
Then starting 2009 the DOE has introduced rationing,
 +
 
 +
In 2010  DOE released 14,000 liters per year, at a spot market auction price of $2,000 per liter (US government customers received subsidized prices). This is a proven global market of around $28 million, perhaps more if we include non US DOE sources, e.g. in Russia.
 +
 
 +
The market could expand to say $50 million or even $100 million per year if plentiful lunar He3 comes on line (price TBD).
 +
 
 +
There is a critical shortage of He3 today, due to two factors:
 +
 
 +
1) increasing demand for neutron detectors since 2001 for cargo screening at airport and seaports. There is also increasing demand at research facilities.
 +
 
 +
2) reduced supply due to decommissioning of nuclear warheads in USA and Russia
 +
 
 +
Reference:
 +
 
 +
<ref>The Helium-3 Shortage: Supply, Demand, and Options for Congress
 +
Dana A. Shea + Daniel Morgan - Specialist s in Science and Technology Policy
 +
Dec 22, 2010 Congressional Research Service 7-5700 www.crs.gov R41419</refref>
 +
 
 +
<ref>GAO-11-472 from May 2011,
 +
title: MANAGING CRITICAL ISOTOPES Weaknesses in DOE’s Management of Helium-3 Delayed the Federal Response to a Critical Supply Shortage</ref>
 +
 
 +
Table-3 in the preceding ref shows Helium-3 price trends steadily increasing. The spot price has more than doubled in the last 3 years (2009 though 2011). The stockpiles of He-3 are shrinking rapidly, and there are only a few years of supply left in the current stockpiles, at which point the price could jump by orders of magnitude.
 +
 
 +
Alternative terrestrial sources are scarce and non-viable. For example, extracting He3 from natural gas could cost $12,000 per liter.
 +
 
 +
The commercial amount of He3 needed would be 10,000 liters per year to 100,000 liters per year. He3 density is about 0.1g per liter at NTP, so we need about 1kg to 10 kg of the gas per year. At average concentration about 150,000 tons of regolith per year would need to be processed. About 500 tons per day, 22 tones per hour
 +
 
 +
Markets consider upside pressures and downside pressures.
 +
 
 +
Helium-3 is a very unusual commodity, in that presently it is completely synthetic, and the Helium-3 traded has not been occurring in nature.
 +
 
 +
We have been feeding off of the nuclear warhead stockpile which has been the source of all the He3 in the world... that warhead stockpile is now mostly gone, so the rate at which we can replenish the He3 stockpile has dropped off a cliff
 +
 
 +
We are now left with a known finite stockpile of He3 which is shrinking at a known rate.
 +
 
 +
Unlike most commodities, we know exactly how big the He3 stockpile is, and we can track how it is being consumed.
 +
 
 +
The stockpile is now down to about 50,000 liters, and the US DOE is presently releasing it at about 14,000 liters per year, and replenishing it with 8,000 liters per year.
 +
 
 +
Since natural demand has been demonstrated at 80,000 liters per year (2008), DOE is implementing a form of strict rationing, to try and eke out the He3 stockpile as long as possible.
 +
 
 +
There is a shortfall of 80,000 minus 14,000 liters = 66,000 liters of pent up demand, or to put it another way, the existing supply of He3 can only satisfy 17.5% of world demand.
 +
 
 +
There is no terrestrial solution to the He3 supply side, so for once the Moon has a real shot at being a solution to a real terrestrial economic problem.
 +
 
 +
At present the US Govt is investing heavily in Boron-10 technology as a second rate alternative to Helium-3 for neutron detectors.
 +
 
 +
According to Harrison Schnmitt in his 2006 book "Return to the Moon", the Mark-II lunar miner of the Wisconsin Uni Fusion Institute, would cost about $1 billion. This Mark-II plant would produce 33 kg of He3 per year. This is several times more than needed to service the existing terrestrial He3 market .... presumably we could build a plant to produce 10 kg per year for $500 million?
 +
 
 
===Cooking out the O2===
 
===Cooking out the O2===
 
The easiest source of oxygen on the Moon is a [[Titanium]]-[[Iron]]-[[Oxygen]] mineral called [[ilmenite]] (FeTiO3) which can be processed via a [[ilmenite reduction|reduction reaction]]. It is a straight forward process to [[magnetically]] [[beneficiate]] this mineral while handling the [[regolith]] [[fines]].
 
The easiest source of oxygen on the Moon is a [[Titanium]]-[[Iron]]-[[Oxygen]] mineral called [[ilmenite]] (FeTiO3) which can be processed via a [[ilmenite reduction|reduction reaction]]. It is a straight forward process to [[magnetically]] [[beneficiate]] this mineral while handling the [[regolith]] [[fines]].

Revision as of 11:35, 20 December 2012

Sandworm proposal by Tom Riley, Side View

Volatile Recovery on the Moon

Long term lunar settlement, not to mention going on to Mars, will depend on successful extraction of volatile substances from the Moon.

Volatiles, The Key to Settlement

The primary resource of value to humans on the Moon is the volatile components found in the regolith. These are all the components that are gases at room temperature. Most of the volatiles have been deposited in the top layers of the Moon's surface by the solar wind over geologic time. A notable exception to this is Argon. the concentration of Argon in lunar soil is much higher than found in the solar wind, so must come from a different source. Especially, the isotope Argon-40. It is presently believed that the Argon-40 comes from radioactive decay of Potassium deep within the lunar mantle or core, and that the Argon-40 seeps out to the surface via fissures. This vented Argon enters the lunar atmosphere; then the Argon is implanted into the regolith by interactions with ions from the solar wind.

The volatiles contain material useful for rocket fuel, reaction mass, for making air to breath, and for industrial operations.

The various constituents of the volatiles vary from place to place on the Moon. Access to a mining area with high abundances will be a major concern for any settlement site.

Dr. Harrison Schmitt in his lectures at University of Wisonsin provides some links on their page page with data on abundance of luanr volatile components: [1].

That web page in turn has additional references which talk about the proportions of volatiles and their respective release temperatures.

The major components (when regolith heated to 700 deg C) are:

(in order of abundance)

When the regolith is heated to 900 deg C, a considerably quantity of sulfur compounds is released, including Hydrogen Sulfide and Sulfur Dioxide [2][3].

This chart is a very interesting depiction of the valitiles available when regolith is heated to 700 Deg c:

Inventory of Lunar Volatiles relative to the production of one tonne of helium-3

Apollo Regolith Testing

Regolith samples from Apollo 11 and Apollo 12 were returned to Earth and analyzed for the volatiles they emitted when heated in a vacuum.

Apollo 11 gas release from soil sample 10086,16
Apollo 12 gas release from soil sample 12023,9

The regolith samples were exposed to Earth air and may have picked up some volatiles in transport. Lunar regolith is regularly subject to heating from the sun to at least 150 C. Any volatiles coming out below that temperature was taken to be from Earth.

Between the temperatures of 150 C and 700 C substantial amounts of hydrogen, water, carbon dioxide, and helium came off the samples. In this temperature range the molecules must have been adsorbed on the surface of crystal grains and not bound in chemical compounds. These temperatures are probably achievable by the use of concentrated solar energy.

Between the temperatures of 700 C and 1400 C additional volatile materials come off including substantial amount so nitrogen, carbon monoxide, hydrogen sulfide, and finally oxygen. These volatiles probably represent the breakdown of more complex compounds. These temperatures are routinely achieved in industrial processes on Earth. The volatile output can probably be increased by providing a reducing atmosphere, such as hot hydrogen, and by the presence of a catalyst, such as platinum.

[[3]] Gibson, E. K., Jr.; Johnson, S. M., Thermal Analysis-Inorganic Gas Release of Lunar Samples

Processing Regolith

A major enterprise of any lunar settlement will be the processing of lunar regolith for volatile scavenging. Once the volatile gas mix has been extracted from the regolith, then fractional distillation can be used to separate out the different chemical constituents which have different boiling points. In one proposal, called the Sandworm, a very large vehicle would crawl across the landscape milling out a trench three meters deep and up to 23 meters wide. Some of these trenches could then be used as sites for buildings. Other proposals include smaller vehicle processing or the use of collection vehicles or other means for bringing regolith to a stationary processing facility.

The primary uses of the volatiles are:

  • Lunar use for breathable atmosphere
  • Spaceship atmosphere
  • Rocket fuel and oxidizer
  • Industrial stocks

It is necessary to process only a few tens of kilograms of regolith a shift to replace atmosphere loses in an early small station. A much higher rate of processing will be needed to produce air to grow the settlement and to produce fuel and oxidizer for return flights to the Earth or for trips on to Mars.

Helium 3, Special Considerations

Helium 3 is a special case. As detailed in Harrison Schmitt's book "Return to the Moon", it is the only lunar resource worth shipping back to the surface of the Earth at this time. In the long term, it could be used in fusion power plants on Earth as a source of clean, non-carbon energy. This type of power plant is currently under development, but is not yet near commercial operation.

Helium 3 is very rare on Earth and only a minor component of the lunar regolith volatiles. To refine enough to feed a power plant for a medium size city would require processing regolith at the rate of about 50 tons an hour. The scale of processing needed is directly reflected in the large scale of the proposed Sandworm. A commercial operation of this size on Earth would not be considered a very large facility, but we are talking about the Moon.

Chronic shortage of Helium-3 isotope could be resolved by mining lunar regolith

Demand for Helium-3 is steadily increasing primarily for Neutron detectors.for cargo screening (for illegal fissile material).

In 2008, a total of 80,000 liters of He3 were sold worldwide, at an average price of $100, i.e. total market of $8 million -

Then starting 2009 the DOE has introduced rationing,

In 2010 DOE released 14,000 liters per year, at a spot market auction price of $2,000 per liter (US government customers received subsidized prices). This is a proven global market of around $28 million, perhaps more if we include non US DOE sources, e.g. in Russia.

The market could expand to say $50 million or even $100 million per year if plentiful lunar He3 comes on line (price TBD).

There is a critical shortage of He3 today, due to two factors:

1) increasing demand for neutron detectors since 2001 for cargo screening at airport and seaports. There is also increasing demand at research facilities.

2) reduced supply due to decommissioning of nuclear warheads in USA and Russia

Reference:

Cite error: Closing </ref> missing for <ref> tag

Table-3 in the preceding ref shows Helium-3 price trends steadily increasing. The spot price has more than doubled in the last 3 years (2009 though 2011). The stockpiles of He-3 are shrinking rapidly, and there are only a few years of supply left in the current stockpiles, at which point the price could jump by orders of magnitude.

Alternative terrestrial sources are scarce and non-viable. For example, extracting He3 from natural gas could cost $12,000 per liter.

The commercial amount of He3 needed would be 10,000 liters per year to 100,000 liters per year. He3 density is about 0.1g per liter at NTP, so we need about 1kg to 10 kg of the gas per year. At average concentration about 150,000 tons of regolith per year would need to be processed. About 500 tons per day, 22 tones per hour

Markets consider upside pressures and downside pressures.

Helium-3 is a very unusual commodity, in that presently it is completely synthetic, and the Helium-3 traded has not been occurring in nature.

We have been feeding off of the nuclear warhead stockpile which has been the source of all the He3 in the world... that warhead stockpile is now mostly gone, so the rate at which we can replenish the He3 stockpile has dropped off a cliff

We are now left with a known finite stockpile of He3 which is shrinking at a known rate.

Unlike most commodities, we know exactly how big the He3 stockpile is, and we can track how it is being consumed.

The stockpile is now down to about 50,000 liters, and the US DOE is presently releasing it at about 14,000 liters per year, and replenishing it with 8,000 liters per year.

Since natural demand has been demonstrated at 80,000 liters per year (2008), DOE is implementing a form of strict rationing, to try and eke out the He3 stockpile as long as possible.

There is a shortfall of 80,000 minus 14,000 liters = 66,000 liters of pent up demand, or to put it another way, the existing supply of He3 can only satisfy 17.5% of world demand.

There is no terrestrial solution to the He3 supply side, so for once the Moon has a real shot at being a solution to a real terrestrial economic problem.

At present the US Govt is investing heavily in Boron-10 technology as a second rate alternative to Helium-3 for neutron detectors.

According to Harrison Schnmitt in his 2006 book "Return to the Moon", the Mark-II lunar miner of the Wisconsin Uni Fusion Institute, would cost about $1 billion. This Mark-II plant would produce 33 kg of He3 per year. This is several times more than needed to service the existing terrestrial He3 market .... presumably we could build a plant to produce 10 kg per year for $500 million?

Cooking out the O2

The easiest source of oxygen on the Moon is a Titanium-Iron-Oxygen mineral called ilmenite (FeTiO3) which can be processed via a reduction reaction. It is a straight forward process to magnetically beneficiate this mineral while handling the regolith fines.

The magnetically beneficiated material is valuable as an ore concentrate and can be robotically handled. It is placed in a pressure vessel with an atmosphere of hydrogen, which is the largest component of the volatile extraction. The vessel is then solar heated to about 1200 C for 20 minutes. The result is that the ore is reduced to iron, titanium dioxide, and water. The water comes off as a vapor and can be electrically split into hydrogen and oxygen. This process appears to be the least energetic approach for obtaining substantial amounts of water and oxygen on the Moon.

Byproducts
Solid Byproducts

The solids left from this process will remain a good titanium and iron ore. This material may become a valuable asset for later settlers and can be used to make ceramic tiles for flooring or as feedstock for other chemical processes.

Gaseous Byproducts

After the hydrogen has been consumed, the remaining volatiles will be mostly Helium and Argon. The Argon can be removed by fractionally distilling the gas mixture. The Argon can be used as propellant for electric propulsion thrusters (ion drives). The Helium can be separated into the two main isotopes by methods described elsewhere. The isotope Helium 3 is potentially useful as fuel for nuclear fusion reactors.

Ice at the Poles

Two missions so far (Clementine and Lunar Prospector) have produced evidence for hydrogen in the polar regions of the Moon. The present theory is that it is in the form of water ice particles mixed with the regolith in permanently shadowed craters. The amount and properties of this resource are not currently known, but we soon will have definitive data from the Lunar Reconnaissance Orbiter mission (LRO) by 2010.

Even if substantial amounts of water are present in the polar traps, it may be very difficult to mine. The very nature of the traps is that they have no access to solar power at all and they are at the bottoms of deep craters. For a settlement to take advantage of this resource it will need to be on near by high ground and work the area robotically.

This will be very difficult work at the cryogenic temperatures in the traps. It is not clear whither simply working the sunlit uplands, with plenty of solar power but only a trace of volatiles, is not the better idea. We will know soon.

Outgassing of Volatiles

There are some sites on the Moon where natural release of volatiles via outgassing of volatiles has been observed. In particular, the crater Aristarchus is well known. Outgassing sites would be attractive locations for settlements[4].

References

  1. NEEP602 Course Notes (Fall 1996) Resources from Space Lecture #13: It's only a gassy Moon! Title: Resources of the Moon: Solar Wind/Cosmic Ray Derived
  2. [1] Inventory of Lunar Volatiles in first three meters of regolith (note log scale)
  3. [2] Concentrations of Various Volatiles in Apollo 11 Regolith
  4. Lunar Flash Mystery Solved: Moon Just Passing Gas By David Powell posted: 30 July 2007