Bibcode
Naranen, Jyri; Carpenter, James; Parviainen, Hannu; Muinonen, Karri
Referencia bibliográfica
37th COSPAR Scientific Assembly. Held 13-20 July 2008, in Montréal, Canada., p.2177
Fecha de publicación:
0
2008
Número de citas
0
Número de citas referidas
0
Descripción
Fluorescent X-rays from the surfaces of airless planetary bodies in the
inner solar system have been measured by instruments on several
spacecraft. X-ray emission follows photoionisation by incident solar
X-rays and charged particles and reveals the elemental composition of
the surface. Analyses of X-ray spectra obtained by orbiting spacecraft,
use the relative intensities of elemental emission lines (e.g., Ca/Si,
Fe/Si) to determine the geochemistry of the target body. Historically,
the analysis of X-ray spectra has assumed that surfaces can be
considered as homogeneous plane-parallel media. It has been shown,
however, that relative line intensities are affected by the physical
properties of the target surface (e.g. particle size distribution and
packing density of the regolith) and the viewing and illumination
geometry of observations. We describe experimental investigations into
the effects of regolith properties on the line ratios measured by a
nadir pointing (emergence angle 0° ) orbiting instrument, with with
solar illumination angles in the range 25-75° from zenith. The
planetary regolith analogue used in these experiments was a terrestrial,
olivine rich basalt, which has been used by previous authors as an
analogue to the lunar maria. The basalt samples were ground to powder
and sieved to discriminate particles in the ranges, <75µm,
75-250µm, and 250-500µm. These separate powders were then
pressed into solid pellets. The separation of particles with different
sizes allows some determination of the effects due to changes in
particle size. All measurements were made at pressures of less than 0.5
mbar to prevent absorption of fluorescent X-rays in air. The relative
fluorescent line ratios of several major rock forming elements (K, Ca,
Ti, Si) were measured. We find that for measurements made in a "nadir"
pointing geometry, the measured spectrum becomes increasingly hard as
illumination angle increases (i.e. X-ray lines at higher energies are
enhanced relative to those at lower energies). Some hardening of spectra
is predicted by the fundamental parameters equation (FPE) of X-ray
fluorescence, which assumes a smooth flat and homogeneous surface, but
we observe that spectral hardening is also a function of grain size. In
a nadir illumination geometry, the regolith effect works adverse to the
FPE induced softening of the spectrum, in effect rendering the observed
relative line intensity ratio almost constant over the measured phase
angles. In addition to experimental studies we have simulated the X-ray
emission from a regolith using a numerical Monte-Carlo ray-trace model.
This model simulates a regolith of spherical particles, with defined
physical properties (particle size distribution, packing density etc.).
We present a comparison of our latest results with those of previous
studies and discuss the importance of our work for present and future
missions, including Kaguya and Chandrayaan-1 at the Moon and MESSENGER
and BepiColombo at Mercury.