Volatiles implanted into the lunar regolith by the solar wind are potentially important lunar resources. Wittenberg et al. (1986) have proposed that lunar He-3 could be used as a fuel for terrestrial nuclear fusion reactors. They argue that a fusion scheme involving D and He-3 would be cleaner and more efficient than currently-proposed schemes involving D and T. However, since the terrestrial inventory of He-3 is so small, they suggest that the lunar regolith, with concentrations of the order of parts per billion (by mass) would be an economical source of He-3. Solar-wind implantation is also the primary source of H, C, and N in lunar soil. These elements could also be important, particularly for life support and for propellant production. In a SERC study of the feasibility of obtaining the necessary amount of He-3, Swindle et al. (1990) concluded that the available amount is sufficient for early reactors, at least, but that the mining problems, while not necessarily insurmountable, are prodigious. The volatiles H, C, and N, on the other hand, come in parts per million level abundances. The differences in abundances mean that (1) a comparable amount of H, C, and/or N could be extracted with orders of magnitude smaller operations than required for He-3, and (2) if He-3 extraction ever becomes important, huge quantities of H, C, and N will be produced as by-products

Swindle, Timothy D.

English

NASA Technical Reports Server

N93-26692
Abundance of 3He and Other Solar-Wind-Derived Volatiles in Lunar Soil
Timothy D. Swindle
Lunar and Planetary Laboratory
University of Arizona
Abstract
P- F
Volatiles Implanted into the lunar regolith by the solar wind are potentially Important lunar resources.
Wittenberg et al. (1986) have proposed that lunar ZHe could be used as a fuel for terrestrial nuclear
fusion reactors. They argue that a fusion scheme Involving D and 3He would be cleaner and more
efficient than currently-proposed schemes involvingD and T. However, since the terrestrial inventory
of 3He is So small, they suggest that the lunar regolith, with concentrations of the order of parts per
billion (by mass) would be an economical source of 3He. Solar-wind implantation is also the primary
source of H, C and N in lunar soil. These elements could also be important, particularly for life
support and for propellant production.
In a SERC study of the feasibility of obtaining the necessary amount of 3He, Swindle et al.
(1990) concluded that the available amount is sufficient for early reactors, at least, but that the
mining problems, while not necessarily Insurmountable, are prodigious. The volatiles H, C, and N,
on the other hand, come in parts per million level abundances (Fegley and Swindle, 1992). The
differences in abundances mean that a) a comparable amount of H, C and/or N could be extracted
with orders of magnitude smaller operations than required for 3He and b) if ZHe extraction ever
becomes important, huge quantities of H, C, and N will be produced as by-products.
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Introduction
Previous work on Identifying promising sites for 3He mining has focused on ilmenite (and hence Ti)
content (e.g., Cameron, 1991), since ilmenite retains a higher fraction of the Implanted He than do
other common lunar minerals. Discussions of the abundances of H, C, and N, which are less
dependent on mineral chemistry, generally assume that these volatiles are rather uniformly
distributed inthe lunar regolith, with only local variations as a result of local impact cratering history
(Haskin 1989; see also Taylor 1991).
However, there are geometric factors affecting the abundance of all solar-wind-clerked volatiles that
have not been previously considered in discussions of resource utilization. In particular, since the
Earth's magnetosphere shields the Moon from the solar wind during the portion of each month in
which the subsolar point Is at the central nearside, that region has been exposed to considerably
less solar wind than has the central farslde. Inaddition, equatorial regions should receive more solar
wind that polar regions because the direction of the flow of the solar wind Is close to the plane of
the Moon's equator. Whether this translates into a difference In volatile"content depends on how
important saturation effects are: if the surfaces of samples from the central near side (such as the
well-studied Apollo samples) are saturated with solar-wind derived volatiles, additional exposure will
not lead to higher volatile contents.
In a previous nine-month grant, calculations were made of the expected size of variations in the
solar wind fluence. Under the current grant, we have combined these calculations with estimates
of lunar chemistry based on both telescopic and Apollo observations to identify sites that are
promising either as resources, or as areas to test for the effects of saturation. We have acquired
some crucial lunar samples and have performed some of the analyses to test for saturation,
although these experiments have not yet been completed.
Variations In solar wind fluence
As a first step, we calculated how the integrated solar wind fluence varies with latitude and longitude
on the Moon. The latitude effect Is simply proportional to the cosine of the latitude. The longitude
effect is more complicated, since it depends on the details of the Earth's magnetotail and
magnetosheath. Rather than modeling the magnetosheath in detail, we assumed that the Moon is
completely shielded for 25% of the lunar cycle. Under those conditions, the central near side
receives less than 30% of the fluence that the central far side receives, and only about 35% of the
fluence received by the limbs. A map of the relative fluence is given in Figure 1. Changing the
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NEAR SIDE
FAR SIDE
Figure 1: Relative fluence of solar wind incident on various lunar locations. The maximum fluence -
(defined as 100%) is received at the equator on the far side.
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details of the shielding (i.e., changing the amount of time shielded, or including partial shielding for
the whole duration of the magnetosheath passage, rather than total shielding for part of the
duration) will change the details of the map, but not the overall pattern. For elements for which soil
chemistry is not important (probably all the elements of interest except He), a global abundance
map should be look nearly the same (except for local variations in Impact history), unless saturation
effects are Important. If saturation Is Important, the volatile abundances of high-solarowlnd-fluence
sites would still be expected to be higher than Iow-solar-wtnd-fluence sites, although there might be
a saturation abundance which would be approached.
For 3He, we must include soil chemistry to estimate abundances. Jordan (1989) has shown that the
abundance of 3He inApollo (central nearside) samples is proportionalto the product of a parameter
called Is/FeO (which measures duration of surface exposure, and will be discussed in more detail
below) and Ti content. This is reasonable, sincethe first factor should be proportional to the amount
of solar wind received, and the second is proportional to the fraction retained (since Umenite retains
far more than other minerals). Generalizing to consider fluence variations, we would expect the
abundance to be proportional to the product of the fluence and the Ti content. We have generated
a map of estimated 3He abundance based on that assumption, using the fluence variations
calculated as described above, and maps of estimated Ti abundance based on spectrophotometry
of the Moon (Johnson et al. 1991) and on the Apollo gamma-ray spectrometer Ti results (Davis
1980). These maps are shown in Figure 2.
Since the highest Ti abundances are concentrated in the central near side, where the solar wind
fluence is lowest, the two effects tend to cancel each other. Mare Tranquillitatis, with its very high
Ti content, but low longitude, is still one of the best places to look for 3He, but some other areas
with moderate Ti content but higher longitudes (e.g., western Oceanus Procellarum, Mare
Fecunditatis, Mare Smythii) are potentially as promising. W'_ha few exceptions (most notably in and
around Mare Smythii on the eastern limb), there are few promising sites on the far side, despite the
higher solar wind fluence.
Testinq the import_nce of saturation effects
We have noted that we can convert solar wind fluence to estimated volatile abundance only if
saturation effects are not important. In the lunar sample literature, the question of whether or not
some grain surfaces are saturated is not settled. The best solar-wind simulation studies were
performed recently by Futugami et al. (1990), who bombarded pure mineral samples with He ions.
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-o
HELIUM-3 (PPO|
NORTH
I10 150 tZO <)0 _1
i .....PO
60 90 120 150
- ZO
SOUTH
Figure 2: 3He abundance at various lunar locations, based on the correlation of Jordan (1989),
the relative fluence shown in Fig. 1, and estimates of Ti content. Top map uses estimates from
visible and near-infrared spectroscopy (Johnson et al., 1991), bottom map uses estimates from
Apollo gamma-ray spectrometry (Davis, 1980). Note that these assume that saturation does not
occur.
III-23
They concluded that saturation of a free grain in space could occur in about 10 years of completely
unshielded exposure (cdr_ponding to a few decades of exposure on the Moon). Under these
conditions, saturation of He, at least, would be expected to be important. In a study of actual lunar
samples, Wieler et al. (1980) concluded that He saturation of grain surfaces occurs for "a
considerable fraction" of the grains they analyzed. However, they also concluded that saturation of
Ar occurs for few samples. Since Ar abundances correlate well with abundances of C and N (and,
with poorer data, H), even at high abundances, it seems likely that these species are not saturated
either.
To test for saturation effects, we should compare volatile abundances In samples from locations
which we would predict to have a range of solar wind fluences. The Apollo samples all come from
a limited geographic range on the central near side. The location with the highest estimated fluence
(Apollo 17) would have only 50% more than the location with the lowest fluence (Apollo 15), and
only 15% more than the mean of the Apollo samples. The ideal samples would be ones from
documented locations on the central farside, but such samples are, of course, not available. The
best samples, then, are the Russian Luna samples, which come from closer to the eastern limb of
the nearside, and hence would be expected to have about twice the solar wind fluence as the
average Apollo sample, and more than 60% more than even Apollo 17.
We acquired samples of two soils each from Luna 16 and Luna 20 ferromagnetic resonance (FMR)
and noble gas analyses. The FMR analyses, which were performed by R. V. Morris of NASA
Johnson Space Center, are essential to determining the ratio of reduced to oxidized iron (IdFeO),
a widely-used, probably impact-driven, measure of "maturity" or exposure history (Morris 1976).
These measurements, the first Is/FeO measurements on Luna 16 or Luna 20 samples, suggest that
both are quite mature. The few previous noble gas analyses on Luna samples scatter by more than
would be expected from heterogeneity (i.e., some of the calibrations were probably incorrect), so
we are in the process of measuring the noble gas abundances In these four Luna soils. The He
analyses are obviously relevant to the question of 3He abundances, while the analyses of the heavier
noble gases (Ar, Kr and Xe), whose abundances are not affected by the chemistry of the soil,
provide a good analog for volatiles such as C and N. At the time of submission of the progress
report, instrument calibration for these measurements is underway, and the measurements should
be completed during the final weeks of the grant.
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Well-calibrated measurements are essential to answering the question of saturation. The previous
He measurements of Luna 16 and Luna 20 soils, when combined with TI abundances and the new
Is/FeO results, scatter enough to overlap predictions based on either no saturation or complete
saturation, although the mean is more consistent with complete saturation. For Xe, the scatter In
abundances measurements is even larger, although the mean is considerably higher than predicted
based on Is/FeO. Although it would not be surprising if saturation effects were stronger for the more
abundant gas, He, our conclusions will have to await our own analyses.
Bibliooraohv
Cameron E. N. Mining for helium - site selection and evaluation. In Lunar Helium-3 and Fusion
Power (NASA Conference Pub. 10018) 1988: 35-63.
Cameron E. N. (1991) Helium resources of Mare Tranquillitatis. In Resources of Near-Earth Space
(Abstracts). UA/NASA Space Engineering Research Center AIS/A-90 (1991): 16.
Davis P. A. Jr. Iron and titanium distribution on the Moon from orbital gamma ray spectrometry with
Implications for crustal evolutionary models. J. Geophys. Res. 85 (1980): 3209°3224.
Fegley B. Jr., and T.D. Swindle. 3He and other lunar volatiles. Resources of Near-Earth Space (J.
S. Lewis and M. S. Matthews, eds.). Tucson: University of Arizona Press. In press.
Futugami T., M. Ozima, and Y. Nakamura. Helium Ion Implantation into minerals. Earth P/anet. Sci.
Lett. 101 (1990): 63-67.
Haskin L A. The Moon as a practical source of hydrogen and other volatile elements (abstract).
Lunar Planet. Sci. XX (1989): 387-88.
Johnson J. R., S.M Larson, and R.B. Singer. Remote sensing of potential lunar resources: I. Near-
side compositional properties. J. Geophys. Res. 98 (1991): 18,861-18,862.
Jordan J. L. Predictions of the He distribution at the lunar surface. In Space Mining and
Manufacturing (abstracts of papers submitted to the 1989 Annual Invitational Symposium of the
UA/NASA SERC, Tucson).
Morris R. V. Surface exposure indices of lunar soils: A comparative FMR study. Proc. Lunar Sci.
Conf. 7th (1976): 315-35.
Swindle T. D., C.E. Glass, and M.M. Poulton. Mining lunar soils for 3He. UA/NASA Space
Engineering Research Center TM 90/1 (1990).
Taylor L. A. Helium abundances on the Moon: Assumptions and estimates. In Resources of Near-
Earth Space(Abstracts) UA/NASA Space Engineering Research Center AIS/A-90 (1991): 40.
Wieler R., Ph. Etique, P. Slgner, and G. Poupeau. Record of the solar corpuscular radiation in
minerals from lunar soils: A comparative study of noble gases and tracks. Proc. Lunar P/anet. Sci.
Conf. 1lth (1980): 1369-1393.
111-25
Wittenberg L. J., J.F. Santadus, and G.L Kulcinski. Lunar source of 3He for commercial fusion
power. Fusion Technology 10 (1986): 167-78. .......
P_lblicatlons suD_:_rtedbv the current arant (November 1 -- September 15)
Boynton W., W. Feldman, and T. Swindle. A lunar penetrator to determine solar wind-implanted
resources at depth in the lunar regolith. In Joint Workshop on New Technologies for Lunar
Resource Assessment, Santa Fe, NM (1902): 6-7.
Fegley B. H. Jr. and T.D. Swindle. 3He and other lunar volatiles. Resources of Near-Earth Space (J.
S. Lewis and M. S. Matthews, eds.). Tucson: University of Arizona Press. In press.
Johnson J. R., T.D. Swindle, S.M. Larson, and R.B. Singer. Systematic variations in solar wind
fluence with lunar location: Implications for resource utilization. Bulletin American Astron. Soc. 23
(1991): 1201.
Swindle T. D., M.K. Burkland, J.R. Johnson, S.M. Larson, R.V. Morris, B. Rizk, and R.B. Singer.
Systematic variations in solar wind fluence with lunar location: Implications for abundances of solar-
wind-implanted volatiles. Lunar Planet. Sci. XXIII (1992): 1395-1396.
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Abundance of He-3 and other solar-wind-derived volatiles in lunar soil

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