Deep Space Exploration - Looking for Planetary Paydirt

space.com ^ | 14 Nov 01 | Leonard David

[RightWhale]

Deep Space Exploration - Looking for Planetary Paydirt

By Leonard David

Senior Space Writer

posted: 07:00 am ET

14 November 2000

GOLDEN, COLORADO -- Here's the claim: A "miner" breakthrough is needed to develop and utilize the resources of space, be they from asteroids, the Moon or Mars. The solar system is a heaven-sent treasure trove -- a bounty, ready and waiting, of metals and materials that can fortify humankind's outward reach into the cosmos.

Experts from NASA, federal research labs, industry, universities, and private groups met here October 24-26 at the Colorado School of Mines, taking part in a "Space Resources Utilization Roundtable."

New spacecraft data clearly picture the inner and outer solar system as a prospector's paradise. But don't take your pick, shovel, and drill bits out of the tool shed just yet. Strategizing a "big dig" of the solar system is short of having a solid plan to assure hitting paydirt.

Starting small

"We're seeing a big picture approach to developing space resources," said Michael Duke, technical coordinator at the School of Mines for the roundtable. "There are new and useful ideas being discussed. These are the kind of things that start the juices flowing in terms of the big picture," he told SPACE.com.

Starting small and carrying out experiments that show the resource potential of space is an advisable strategy, Duke added. Useful demonstrations can be done on robotic missions to the Moon and Mars. "In some cases, we may be able to try out small-scale technologies that improve the effectiveness of spacecraft missions," he said.

Utilizing technologies that benefit science return from space missions, but also shed light on the economic benefit of using on-the-spot resources is a good match, Duke said.

As example, processing of Martian resources to churn out fuel for a Mars sample return mission could be later scaled up to support human expeditionary crews on the red planet.

"On the Moon, we want to look at those lunar polar regions, where there may be hydrogen concentrations…water ice, perhaps," Duke said. "We need to learn what its distribution is, what are the environmental considerations that go into extracting it and processing that material," he said.

Planetary prospecting

Planetary geologist, Jeffrey Taylor of the University of Hawaii in Honolulu, said space resources are essential for space settlement. He is working on a plan of action to promote planetary prospecting.

Celestial campsites on the Moon or Mars that support more than a few thousand people require use of local, down-and-dirty resources to build and sustain those far-flung housing projects and generate products for export, Taylor argues.

In the case of setting up a Martian settlement, Taylor said, it may be cost effective to ship out needed water, oxygen, hydrogen, major metals, and food from a lively lunar operation, at least initially. "As we begin to settle the Moon and Mars, we must also keep track of changing economic conditions, such as launch costs or substitutes of one material for another," he said.

Taylor and Linda Martel, both of the Hawai'i Institute of Geophysics and Planetary Science, emphasized that data now in hand, as well as new information from lunar and Mars missions, should be assessed in terms of spotting the heaviest deposits of resources. Also, pinpointing odd, anomalous regions is a priority.

"We have to find resources in more concentrated places, as on Earth," Taylor said.

Either ore

To date, mostly robot prospectors have been busy at work.

For the Moon, the U.S. Pentagon's Clementine, NASA's Lunar Prospector, as well as samples brought back by foot-stomping Apollo astronauts, offer a wealth of insight about resources there. For Mars, a number of orbiters and landers have in the past, are now, and will in the future, sensor-scan the red planet to chart minerals and look for evidence of water.

"Prospecting can begin immediately," Taylor said, by studying data already archived. But that data needs to be looked at with the eyes of specially trained planetary economic geologists, an expert workforce that he and Martel are now trying to help shape.

Taylor explained that work should focus on the "unusual economics" of planetary ores, including the relationship of lunar and Martian development to each other. By definition, ores are rocks or minerals that can be mined, processed, and delivered to the marketplace or to technology at a profit.

Aggregate will be an important resource on both the Moon and Mars. Here on Earth, it is the most mined material in the United States, at some 2.3 billion tons a year. It is used for roads, concrete, bridges, roofing materials, and glass, Taylor notes.

On Earth, aggregate comes mainly in the form of gravel, sand, and solid rock that's quarried to make crushed stone. The busted up and heavily cratered lunar surface is rife with aggregate. But on Mars, Taylor points out, a thorough search for unconsolidated aggregate is necessary. Martian sand dunes might prove key in this regard. Debris at the base of cliffs on Mars could also be another possibility, he said.

How low can you go?

Biting down hard on Mars may not be too far off in the future.

A commercial drilling firm has teamed up with NASA's Johnson Space Center (JSC) and the Jet Propulsion Laboratory to explore the feasibility of a Mars drill. Preliminary work looks very promising, said Humboldt Mandell, Jr., in JSC's Exploration Office.

A proprietary drill design -- capable of digging down to over 650-feet (200-meters) below Mars' surface -- has been scoped out by Baker Hughes of Houston, Texas. A leader in oilfield drilling services, the firm works on high-technology ways to go deep to find oil and gas reservoirs, supplying separation technologies to the worldwide process industries.

Baker Hughes has offered to deliver a space-rated drill in 24 months after go-ahead, at a fixed price of $12 million. "That's pretty cheap," Mandell said. Several iterations of the drill design have been made. Now being fabricated and near ready to test is a 110-pound (50-kilogram) version of the drill capable of reaching some 65-feet (20-meters) depth on Mars. The device would use extremely low power to do its work, he said.

Getting a drill on an advanced lander heading for Mars in 2007 or 2009 is the prime directive.

Boring for interest

"Depth does matter. The deeper, the more customers," JSC's Mandell said. "If you're operating at the surface, you are interesting a small number of geologists. The deeper you go, then you involve the organic chemists and life scientists. Below that, now you start getting into the possibility of liquid water. That's when you start picking up the support of the human exploration type of people that, conceivably someday, could put money into this," he told SPACE.com.

Techniques and technologies to measure while drilling are under review by NASA and Baker Hughes. So too are ways to produce intact, protected core samples that can be studied by automated means, Mandell said. Work underway today may lead to future drills on Mars that burrow down as deep as two-and-a-half miles (4-kilometers), he said.

Sucking up 200 watts of energy per day, the drill would make slow, but steady headway - about a little over three feet (one meter) per day for 200 Mars days, Mandell said. "If we had a nuclear power supply, then we could really go," he added.

Pavement of solar cells

Taking the Moon at face value is Alex Ignatiev, of the Space Vacuum Epitaxy Center at the University of Houston. He reported progress in using lunar-like materials to produce thin film silicon solar cells. Small quantities of carefully concocted, NASA-supplied, lunar "simulant" are used in his experiments.

In melting and evaporating the fake Moon material, an excellent substrate and anti-reflective and protective coating for thin film silicon solar cells has been created. Lab investigations are underway to fabricate silicon solar cells on melted lunar regolith, Ignatiev said. Ignatiev said that he envisions a solar cell grid on the Moon, powering up bases and science hardware.

Initially, a desk-sized crawler takes in the lunar regolith, laying out a pavement of solar cells as it moves about. Batches of the Moon-made solar cells would provide electricity, on the order of 200 kilowatts capacity per year. Over time, gigawatts of power can be made available.

"Then you can start beaming the power around the Moon to where you need it," Ignatiev said.

Novel breed of MicroCATS

Ultra-small technology offers big promise, said Robert Wegeng, chief engineer at the Department of Energy's Pacific Northwest National Laboratory in Richland, Washington. He gave an update on the building of Micro Chemical and Thermal Systems, or MicroCATS for short.

Microminiaturization has led to a novel breed of MicroCATS, Wegeng said. This work makes it possible to greatly reduce the weight, size, and expense of space systems, such as heating, cooling, and power generation hardware.

These tiny devices, best thought of as a chemical plant on a chip, can handle chemical reactions and chemical separations. Possible space applications include making rocket fuel or yielding oxygen for human consumption.

Wegeng said that the Moon's surface, plopped down on Mars, or planted upon near-Earth asteroids and comets - the palm of your hand-sized MicroCATS look promising in their ability to suck in resources and yield outputs of water, oxygen, and fuel.

Here's the dirt

The real message of the Space Resources Utilization Roundtable, the third gathering held to date, is "almost a destiny thing," said Taylor of the University of Hawaii.

"Great nations do great things, If we back away from space, what are the great things we're going to do?" he asked. "Even without the grand plans, as long as we have a goal of wanting to have permanent habitats on the Moon and Mars, then we can prepare for that objective with modest cost and great return," he said.

A few uncertainties, technologically and scientifically, need to be addressed over the next few years, said Duke of the Colorado School of Mines. For one, finding out how much water ice might be at the lunar poles is important. Public and private partnerships to spearhead technology development is another, he said.

"The roundtable is bringing together interested space professionals, experienced resources personnel from industry, and entrepreneurs," Duke said. "Our goal is to utilize the resources of space, including the Moon, Mars and asteroids, advancing the prospects for their commercial development."

"That's the strategy to get us to the decade of 2010, and beyond," Duke said.

[RightWhale]

As usual they miss most of the major points. They also think small. Their guns are small bore and always will be.

[WyldKard]

The only way we're going to be able to achieve any of this in our lifetime is by opening it up to private enterprise.

[longshadow]

solar system bump

[Lokibob]

One could come up with a conspiracy theory concerning the reason we quit going to the moon when linked to helium3. After all, a shuttle load of H3 would power the U.S. for a year. Following is from Space.com on helium 3:

Researchers and space enthusiasts see helium 3 as the perfect fuel source: extremely potent, nonpolluting, with virtually no radioactive by-product. Proponents claim it’s the fuel of the 21st century. The trouble is, hardly any of it is found on Earth. But there is plenty of it on the moon.

Society is straining to keep pace with energy demands, expected to increase eightfold by 2050 as the world population swells toward 12 billion. The moon just may be the answer.

"Helium 3 fusion energy may be the key to future space exploration and settlement," said Gerald Kulcinski, Director of the Fusion Technology Institute (FTI) at the University of Wisconsin at Madison.

Scientists estimate there are about 1 million tons of helium 3 on the moon, enough to power the world for thousands of years. The equivalent of a single space shuttle load or roughly 25 tons could supply the entire United States' energy needs for a year, according to Apollo17 astronaut and FTI researcher Harrison Schmitt.

[PatrickHenry]

I think the working conditions of an asteroid miner would be rather harsh; but if the payoff is going to be tremendous, it would be worth it. I'd rather be an investor than a miner, however.

[Brett66]

Index.

[Brett66]

They do think small, just like you said. None of the toys that they envision can provide the mass tonnage neccessary to build large space hotels,manufacturing facilities or SPS's in space. Such structures demand ET mining. The economics would be almost impossible to justify if we ship the materials from Earth unless launch costs are driven down to less than $10/lb.

[longshadow]

I'd rather be an investor than a miner, however.

Look at the bright side: in the absence of an atmosphere, mine explosions will be a thing of the past, and the risk of "Miner's Lung" disease will be zreo.

And, they won't need to take canaries with them....

[PatrickHenry]

Look at the bright side: in the absence of an atmosphere ...

Yes, but think of the consequences of a gastric disturbance while sealed in a pressure suit.

[RightWhale]

I think the working conditions of an asteroid miner would be rather harsh

Here's a perceptual problem due to too many movies. It would be more like working in the control room of a modern nuclear power plant. It might even be boring unless you like to do tedious things such as taking math classes for fun. The hard part for some workers is the trip out and back, especially the ones who do their entire career on one ship on one mission. 16 years alone, or even worse, with a small group.

-Captain, we have met and decided we don't like your decision to unfurl the solar panels at 25 degrees to the ecliptic. The shadow is blocking the sundeck.

-Hear this, crew, this is not a democracy. Return to your assigned duties immediately.

-Well, Captain, we hereby remove you from authority over this mining ship and the claim.

-Fine with me, crew, but you will miss those special dumplings on Sundays, won't you.

((Crew confers))

-Captain, we have decided that since you appear willing to take your dumplings recipe with you to the grave, that we, the crew, will tolerate your continued captaincy. Be aware, dumplings is the only thing we like about you. Tyrant.

---

And that was just week No. one after leaving moon base.

[longshadow]

Yes, but think of the consequences of a gastric disturbance while sealed in a pressure suit.

Side story time: this is not a new problem. Astronauts, and aviators operating aircraft at very high altitudes (and thus wearing space suits), have long had to face this problem. Hence the "standard" breakfast prior to flight for such personnel: steak and eggs.

In space, flatus is NOT your friend.

[RightWhale]

opening it up to private enterprise.

Give me NASA for 4 years, and you will have your space transportation system and your business environment. Right-of-way railroad grants opened the West, if you need a hint where I am going with this.

[Cincinatus]

The helium-3 thing is a lot of snake-oil.

First, yes there is 3He on the Moon. It's present at about the one part per billion level. You have to heat the soil to about 700 degrees C to drive off the 3He -- that several megawatts per ton of heating dirt. To be charitable, let's assume that you use focusing mirrors to capture "free" solar thermal radiation. You then have to collect it, isotopically separate the 3He, cyrogenically freeze it, store it, and transport it back to Earth.

But when you get it home, then what? We haven't achieved D-T fusion above breakeven yet, let alone D-3He fusion (which is about an order of magnitude more difficult). Commercial fusion power is like the end of the rainbow -- it's always "just around the corner." So, you're stuck with several tons of 3He, which I guess is useful to fill balloon animals with.

A much more proactical way to get energy from the Moon is to make solar panels on the surface using local materials and lay out solar arrays on the surface. Then, beam the electrical power back to Earth using microwaves of lasers. Basically, the Solar Power satellite idea, without the enormous launch costs associated with that concept.

[Cincinatus]

Ooops! "using microwaves OR lasers"

[WyldKard]

Give me NASA for 4 years, and you will have your space transportation system and your business environment. Right-of-way railroad grants opened the West, if you need a hint where I am going with this.

Hmmmm....point taken.

[RightWhale]

to get energy from the Moon

I'll just mention this, an old idea in the FR archives.

---

Power generated on the moon or in space would be best used locally. Move power-hog industries such as aluminum and steel into space. This would do 4 things at once:

reduces power consumption on earth;
the nasty Kyoto agreement is mooted;
hastens development of space mineral resources;
more of earth's real estate may be zoned residential rather than heavy industry.

[RadioAstronomer]

Think of what kind of solar furnace you could construct. You would not even have the atmospheric contaminants to deal with.

There was a book written a few years ago called the "High Frontier" which delved into this subject (including mining the asteroids) quite thoroughly.

[RightWhale]

O'Neill [sp] was one of my asteroid mining gurus. I call space the "Endless Frontier" so as not to step on his "High Frontier". I did an economic analysis, lack of which seemed at the time to be a gap in the dreaming and planning. As a result I am very upbeat on the potential economic return of asteroid mining, but not on many of the other space development ideas.

[RadioAstronomer]

This is why I advocated "lunar base" as one of the top 5 projects on the other thread. The infrastructure required to support it would directly lead to further uses of our solar system including asteroid mining.

[RightWhale]

If I were king for a day I'd say, "And it shall be so."