The purpose of the research is to combine experiments and Monte Carlo transport of neutrons through volume of soil in an attempt to model neutron leakage from planetary surfaces. Emphasis is given to the change of neutron spectra as a function of water content and location. During the first stage of effort, two experiments were conducted in which leakage of neutrons from a Pu-Be source through about 30 g/cm(exp 2) of soil were measured with several counters. A Monte Carlo code, MCNP, has been used to model many of the 100 individual runs of the experiment. Hydrogen is the element that has the most dramatic effect on the neutron spectrum and its effect on the neutron spectrum is almost the same whether it is in the form of water or polyethylene. In order to simulate various water configurations, sheets of polyethylene have been used between layers of soil as well as water in several concentrations up to 18%. Comparison of experimental results to theoretical predictions made with the MCNP code were disappointing for low concentrations of water. We have made extensive calculations to see if room return could be the cause of the discrepancies. Water concentrations of the 'dry' soil were measured by two different laboratories and differed only by 0.5%. We have made calculations to optimize the next experiment and are investigating other methods of determining the water content of 'dry' soil

Drake, Darrell M.

English

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NASA-CR-ZOSB21
//, /: /
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FINAL REPORT
Assay of the Martian Regolith with Neutrons
Second Year
Contract No: NASW-5030
Submitted to
NASA Center for Aerospace Information (CASI)
Attn: Accessioning Department
800 Elkridge Landing Road
Linthictium Heights, MD 21090-2934
Submitted by
Amparo Corporation
811 St. Michaels Dr., Suite 203
Santa Fe, NM 87505
(505) 982-6742
Dated: 2 September 1997
https://ntrs.nasa.gov/search.jsp?R=19970028017 2020-06-16T01:10:38+00:00Z
Final Report
Amparo Corporation
September 2, 1997
In this'Planetary Instrument Definition & Development Program, experimental and
computational modeling are to be combined to predict and measure neutron leakage flux
similar to that which would be emitted from a planetary surface. The general purpose of
this study is to see how well Monte Carlo calculations can reproduce the results of
experiments designed to determine the water content in a planet's regolith. The emphasis
of the program in this second year was placed on analyzing of the experiments done in the
first year.
In the first year experiments were done at the University of New Mexico
engineering department in a large room using their PuBe neutron source and several sets
of neutron counters. The set of detectors for which most of the experimental-
computational comparisons have been made consisted of a pair of 3He proportional
counters, one of which was covered with a thin layer of cadmium. The difference in
counting rates of these two detectors can be related to the water content of the soil.
The initial analyses of the experiments was done for spectra in which the soil was
"dry" (near 1% by weight). The comparison of experimental and computational results
was disappointing and considerable effort was made to understand why this difference
existed. Figures 1 and 2 show the ratio of experimental to calculated results for several of
the different arrangements as a function of theoretical counting rates. The counting rates
increase either as the water content is increased or polyethylene sheets are inserted to
simulate layers of water. Figure 1 is for the bare counter, and Figure 2 is for the cadmium
covered counter. The points in Figure 1 for low counting rates are considerably higher
than an ideal ratio of 1, indicating that there are more low energy neutrons than can be
accounted for in the calculations. For the higher counting rates the agreement is better
and settles to a value of about 0.8. In Figure 2, where the cadmium cover cuts out all
neutrons below about 0.4 eV, the agreement is much better for the low counting rates.
With these results we searched for possible causes of the excess low energy
neutrons.
2
SOIL COMPOSITION
We have investigated how the soil composition might effect the comparison of the
experimental results with the Monte Carlo calculations in two ways: A) By using two
different laboratories to analyze the soil and B) by an analytical investigation of how
sensitive the epithermal amplitude is to changes in the elemental composition.
A) Soil s,i_'nples were analyzed separately by LANL and Huffman Laboratory by x-ray
fluorescence. In the first analysis of Huffman the sum of weight percents for the
individual elements added to 110% and several discussions with them resulted in a
change in their standard calibration sample. Their second analysis and that of
LANL are listed as weight percent in the following table and the agreement is quite
satisfactory; "lost on ignition", loi, is assumed to be water that escapes when the
sample is heated.
element Huffman LANL
AI203 11.37 12.02
CaO 1.21 1.09
Fe203 2.80 2.42
MgO 0.41 0.40
MnO 2 0.08 0.07
P205 0.04 0.04
K20 3.47 3.65
SiO 2 75.3 75.1
Na20 3.57 3.44
TiO 2 0.25 0.25
loi 1.59 2.10
These analyses show that errors in the composition of the soil used in the
experiment are probably negligible.
B) The relative sensitivity of the epithermal part of the neutron spectrum to different
elements can be written analytically. We start with the epithermal amplitude of an
equilibrium spectrum:
1) A oc I
Ei ni °i _i
where n is the atom density, o is the scattering cross section, _ is a down
scattering parameter, and i designates the element. Partial differentiation gives
2) _A_A =-&n i_ (nioi_,i)A ni 2i ni cri _,i
The following table shows the fractional change in the epithermal amplitude due to an
error of 10% in the assay of the elements of the below table.
Element Fractional Change
Si
Ti
AI
Fe
Mr]
Mg
Ca
Na
V
P
0
H
0.0036
0.000013
0.000045
0.00016
0.0000002
0.000044
0.00005
O.O005g
O.O001g
0.000002
0.027
0.067
The point of this table is to show that the epithermal portion of the spectrum is
mainly sensitive to hydrogen. A 10% change in water content is almost 3 times more
effective than a 10% change in the oxygen concentration even though there are about 20
times more oxygen atoms as there are hydrogen atoms. The 0.5 weight percent difference
in the two measured values of water can cause an almost 17% difference in the epithermal
amplitude. This result just reinforces the power of neutron measurements in searching for
water. MCNP was run for "dry" soil using the LANL and Huffman values for water
content. Counting rate as a function of neutron energy is shown in Figure 3 for both
calculations. It is clear that knowing the initial water content is important and that the
27% difference in the LANL and Huffman water measurements is larger than we would
like.
INITIAL ENERGY SPECTRUM
We investigated the effect that a difference in the energy spectrum of the initial
neutron source would have on the leakage flux of out experiment. Five calculations were
made with a PuBe source, a PuBe source shifted to lower energies, a monoenergetic 3
MeV source, a monoenergetic 6 MeV source, and a 252Cf spontaneous fission source.
Figure 4 shows the relative counting rates as a function of neutron energy for the 6 MeV,
3 MeV, and 252 Cfsources. Since the counting rates as a function of neutron energy have
about the same shape, even though the magnitudes vary by factors of about 10, this figure
shows that high energy neutrons escape our experiment.
Figure 5 shows the relative shape of two neutron source spectra that could be used
in the experiment along with a LAHET calculation that shows a calculated neutron
spectrum produced in a Martian type regolith. The latter curve represents neutrons,
produced by cosmic-ray interactions with the soil components that have been born with or
scattered to energies below 20 MeV.
ROOM RETURN
Although the experimental room at UNM is quite large, we remodeled our
experiment so as to include approximate wall, ceiling, and floor composition and
dimensions. These calculations showed that the source of the extra low energy neutrons
could be moderation and back scattering from the room. Several other modifications to
these calculations were done in order to optimize the next experiment and eliminate as
much back scattering as possible. These calculations show that a 252Cf neutron source is
better than the PuBe source and that the addition of soil under the source improves the
counting rate by about a factor of 10 for either source.
Similar calculations were made for the LANL trailer that we plan to use for the
next experiment, and to the extent the model represents the trailer there is very little back
scatter.
We presented a poster at the June NASA PIDDP workshop held in Pasadena and
have prepared an abstract for the November In Situ Resource Utilization Technical
Interchange Meeting II in Houston.
Although calculations show that use of a 238U ion chamber to measure fast
neutron flux for our experiment or on the martian surface would be marginal, we have
acquired a 4" diameter chamber for use in the next experiment.
We have also obtained a pair of silicon counters with 6LiF deposits and even
though these devices are also rather inefficient, they provide much more definitive
information, and we will use these also in the next experiment. This counter is the subject
of the abstract for the In Situ Resource Utilization Technical Interchange meeting.
We have done the paper work necessary to use the LANL sources and trailer for
the next experiment.
FIGURE 1
. RATIO (EXPERIMENT/THEORY)
FOR BARE COUNTER
4
O
n,.,
3.5
3
2.5
2
1.5
0.5
0
0
I I I I I
500 1000 1500 2000 2500
THEORETICAL COUNTING RATE
A plot of the ratio of the experimental counting rate divided by the computed counting
rate for several experimental conditions ranging from dry soil to 1.27 cm of polyethylene
under the counter. This plot is for the 2" diameter by 8" long 3He proportional counter.
The points at low counting rates are high and could be caused by either neutron room
return and/or more water in the soil sample than estimated.
6
FIGURE 2
D
O
RATIO (EXPERIMENT/THEORY) FOR
CADMIUM COVERED COUNTER
O
m
I-"
<
0
• • • •
I I I
0 200 400 600 800
THEORETICAL COUNTING RATE
This is the sample plot as Figure 1, except the counter was covered by a thin sheet of
cadmium. The low counting rate points are closer to a ratio of one than those in Figure 1
indicating that the extra neutrons are mostly below 0.4 eV.
FIGURE 3
HUF.FMAN VS LANL DRY SOIL
o
10
C/)
I---
Z
0
U
1
0
0.1
1.0E-8
[]
O
[] []
[]
[]
0
• II
[Cl
• • •
[]
[]
• • •
ooo
1.0E-7 1.0E-6 1.0E-5 1.0E-4
NEUTRON ENERGY (MEV)
1.0E-3
El- 1
m- 2
A plot of counting rates for "dry soil" versus neutron energy. The two plots correspond
to: 1 - soil with the average of two measurements of water content and to: 2 - soil with an
additional amount of water equal to the difference between the measurements.
FIGURE 4
COl_TS VS NEUTRON ENERGY FOR
DIFFERENT SOURCE SPECTRA
I.-
z
D
0
to
1.0e+ 1
1.Oe+O
1.0e- 1
1.Oe-2
I0e-3
n
[] []
[]
i"
o00
T1 O0 o°o[
o
I-I_I-i° I
I00 rlOrlo0 [
i •
II I
-l-l-l-l-l-_i- I
• t •
O
0000 nO I
-i-I-i -I-
I_ • _00
1.Oe-8 1.Oe-6 1.Oe-4 1.Oe-2 l.Oe+O
• 3MEV
o 252Cf
• 6MEV
i i
NEUTRON ENERGY (MEV)
A plot of relative counting rates as a function of neutron energy for three different initial
neutron spectra, monoenergetic neutrons of 3 and 6 MeV and a 252Cf spontaneous fission
spectrum.
FIGURE 5
BO
SOURCE ENERGY COMPARISON
>
ILl
5"
Z
0
n,.,
i.u
z
IL
0
L,IJ
m
;E
Z
2
1.8
1.6
1.4
1.2
0.8
Q6
0.4
0.2
0
•\is. .-
4)@
I1• • •
I,ii
III I'1 I°1 • l.l I.I
l I I I I
0 2 4 6 8 10
NEUTRON ENERGY
--•-- 252Cf •
----o--- MARS
--'-- PU-BE
A plot of the energy spectrum of two possible neutron sources, PuBe and 252Cf, along
with a computed spectrum of neutrons produced by cosmic rays in the Martian regolith.
10
l, AGENCY US1[ QNLY ({e$.,# Ol_nl¢)
4. nTLI[ A#6 SU$1fltL!
Assay of the Martian Regolith
With Neutrons
7,
,_. R[PORT DATE |,11. MEPORT TYPI[ ANO OAT(S COVIA|O
9-2-97 , IFinal Report 9/I I /96 -9/I/97
Darrell M. Drake
B
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Suite 203
Amparo Corporation
811 St. Michael's Drive,
Santa Fe, MM 87505
$. fUNDING NUMS£R$
NASW-5030
I. PI[AFORMING ORGANIZATION
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NASA Headquarters
Acquisition Division
Code CW
Washington, D.C. 20546-0001
11._P_MEN;AAY NOTES
STAI'I_MINT i2b. OISTXIBUTIONCODE
The purpose of the research is to combine experiments and Monte Carlo transport of neutrons
through volume of soil in an attempt to model neutron leakage from planetary surfaces. Emphasis is
given to the change of neutron spectra as a function of water content and location. During the first
stage of effort, two experiments were conducted in which leakage of neutrons from a Pu-Be source
through about 30 g/cm 2 of soil were measured with several counters. A Monte Carlo code, MCNP,
has been used to model many of the 100 individual runs of the experiment. Hydrogen is the element
that has the most dramatic effect on the neutron spectrum and its effect on the neutron spectrum is
almost the same whether it is in the form of water or polyethylene. In order to simulate various water
configurations, sheets of polyethylene have been used between layers of soil as well as water in
several concentrations up to 18%. Comparison of experimental results to theoretical predictions
made with the MCNP code were disappointing for low concentrations of water. We have made
extensive calculations to see if room return could be the cause of the discrepancies. Water
concentrations of the "dry" soil were meaured by two different laboratories and differed only by 0.5%.
We have made calculations to optimize the next experiment and are invstigating other methods of
determining the water content of "dry" soil.
i_. _Ul_Ct Tupu_s
Neutron Leakage, Water Content,
RIJ_, @ THISPA(I!
Unclassified Unclassi fled
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Regolith Assay
off/gestlu_
Unclassified
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Assay of the Martian Regolith with Neutrons

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