339 research outputs found
Martian Eolian Dust Probed by ChemCam
The ubiquitous eolian dust on Mars plays important roles in the current sedimentary and atmospheric processes of the planet. The ChemCam instrument retrieves a consistent eolian dust composition at the submillimeter scale from every first laser shot on Mars targets. Its composition presents significant differences with the Aeolis Palus soils and the Bagnold dunes as it contains lower CaO and higher SiO_2. The dust FeO and TiO_2 contents are also higher, probably associated with nanophase oxide components. The dust spectra show the presence of volatile elements (S and Cl), and the hydrogen content is similar to Bagnold sands but lower than Aeolis Palus soils. Consequently, the dust may be a contributor to the amorphous component of soils, but differences in composition indicate that the two materials are not equivalent
Update on Automated Classification of Interplanetary Dust Particles
Every year, the Earth accretes about 40,000 tons of extraterrestrial material less than 1 mm in size on its surface. These dust particles originate from active comets, from impacts between asteroids and may also be coming from interstellar space for the very small particles. Since 1981, NASA Jonhson Space Center (JSC) has been systematically collecting the dust from Earth's strastosphere by airborne collectors and gathered them into "Cosmic Dust Catalogs". In those catalogs, a preliminary analysis of the dust particles based on SEM images, some geological characteristics and X-ray energy-dispersive spectrometry (EDS) composition is compiled. Based on those properties, the IDPs are classified into four main groups: C (Cosmic), TCN (Natural Terrestrial Contaminant), TCA (Artificial Terrestrial Contaminant) and AOS (Aluminium Oxide Sphere). Nevertheless, 20% of those particles remain ambiguously classified. Lasue et al. presented a methodology to help automatically classify the particles published in the catalog 15 based on their EDS spectra and nonlinear multivariate projections (as shown in Fig. 1). This work allowed to relabel 155 particles out of the 467 particles in catalog 15 and reclassify some contaminants as potential cosmic dusts. Further analyses of three such particles indicated their probable cosmic origin. The current work aims to bring complementary information to the automatic classification of IDPs to improve identification criteria
Martian Eolian Dust Probed by ChemCam
The ubiquitous eolian dust on Mars plays important roles in the current sedimentary and atmospheric processes of the planet. The ChemCam instrument retrieves a consistent eolian dust composition at the submillimeter scale from every first laser shot on Mars targets. Its composition presents significant differences with the Aeolis Palus soils and the Bagnold dunes as it contains lower CaO and higher SiO_2. The dust FeO and TiO_2 contents are also higher, probably associated with nanophase oxide components. The dust spectra show the presence of volatile elements (S and Cl), and the hydrogen content is similar to Bagnold sands but lower than Aeolis Palus soils. Consequently, the dust may be a contributor to the amorphous component of soils, but differences in composition indicate that the two materials are not equivalent
Scattering of light by a large, densely packed agglomerate of small silica spheres
We model the measured phase function and degree of linear polarization of a macroscopic agglomerate made of micrometer-scale silica spheres using the methodology of multiple scattering. In the laboratory work, the agglomerate is produced ballistically, characterized by scanning electron microscopy, and measured with the PROGRA(2) instrument to obtain the light scattering properties. The model phase function and degree of polarization are in satisfactory agreement with the experimental data. To our best knowledge, this is the first time the degree of linear polarization has been modeled well for a large, densely packed agglomerate composed of small particles with known sizes and shapes. The study emphasizes the relevance of the degree of linear polarization and gives insights into the effects of particle aggregation on the scattering characteristics. (C) 2020 Optical Society of AmericaPeer reviewe
Cometary dust collected by MIDAS on board Rosetta II. Particle shape descriptors and pristineness evaluation
The MIDAS (Micro-Imaging Dust Analysis System) atomic force microscope on
board the Rosetta comet orbiter investigated and measured the 3D topography of
a few hundred nm to tens of m sized dust particles of
67P/Churyumov-Gerasimenko with resolutions down to a few nanometers, giving
insights into the physical processes of our early Solar System. We analyze the
shapes of the cometary dust particles collected by MIDAS on the basis of a
recently updated particle catalog with the aim to determine which structural
properties remained pristine. We develop a set of shape descriptors and metrics
such as aspect ratio, elongation, circularity, convexity, and particle
surface/volume distribution, which can be used to describe the distribution of
particle shapes. Furthermore, we compare the structure of the MIDAS dust
particles and the clusters in which the particles were deposited to those found
in previous laboratory experiments and by Rosetta/COSIMA. Finally, we combine
our findings to calculate a pristineness score for MIDAS particles and
determine the most pristine particles and their properties. We find that the
morphological properties of all cometary dust particles at the micrometer scale
are surprisingly homogeneous despite originating from diverse cometary
environments (e.g., different collection targets that are associated with
cometary activities/source regions and collection velocities/periods). We next
find that the types of clusters found by MIDAS show good agreement with those
defined by previous laboratory experiments, however, there are some differences
to those found by Rosetta/COSIMA. Based on our result, we rate 19 out of 1082
MIDAS particles at least moderately pristine, i.e., they are not substantially
flattened by impact, not fragmented, and/or not part of a fragmentation
cluster.Comment: 40 pages, 31 figures, 1 online tabl
The Composition of Comets
This paper is the result of the International Cometary Workshop, held in
Toulouse, France in April 2014, where the participants came together to assess
our knowledge of comets prior to the ESA Rosetta Mission. In this paper, we
look at the composition of the gas and dust from the comae of comets. With the
gas, we cover the various taxonomic studies that have broken comets into groups
and compare what is seen at all wavelengths. We also discuss what has been
learned from mass spectrometers during flybys. A few caveats for our
interpretation are discussed. With dust, much of our information comes from
flybys. They include {\it in situ} analyses as well as samples returned to
Earth for laboratory measurements. Remote sensing IR observations and
polarimetry are also discussed. For both gas and dust, we discuss what
instruments the Rosetta spacecraft and Philae lander will bring to bear to
improve our understanding of comet 67P/Churyumov-Gerasimenko as "ground-truth"
for our previous comprehensive studies. Finally, we summarize some of the
initial Rosetta Mission findings.Comment: To appear in Space Science Review
Assessing Gale Crater as an Exploration Zone for the First Human Mission to Mars
Mars is the "horizon goal" for human space flight [1]. Towards that endeavor, one must consider several factors in regards to choosing a landing site suitable for a human-rated mission including: entry, descent, and landing (EDL) characteristics, scientific diversity, and possible insitu resources [2]. Selecting any one place is a careful balance of reducing risks and increasing scientific return for the mission
Apatites in Gale Crater
ChemCam is an active remote sensing instrument suite that has operated successfully on MSL since landing Aug. 6th, 2012. It uses laser pulses to remove dust and to analyze rocks up to 7 m away. Laser-induced breakdown spectroscopy (LIBS) obtains emission spectra of materials ablated from the samples in electronically excited states. The intensities of the emission lines scale with the abundances of the related element. ChemCam is sensitive to most major rock-forming elements as well as to a set of minor and trace elements such as F, Cl, Li, P, Sr, Ba, and Rb. The measured chemical composition can then be used to infer the mineralogical composition of the ablated material. Here, we report a summary of inferred apatite detections along the MSL traverse at Gale Crater. We present the geologic settings of these findings and derive some interpretations about the formation conditions of apatite in time and space
The potassic sedimentary rocks in Gale Crater, Mars, as seen by ChemCam on board Curiosity
The Mars Science Laboratory rover Curiosity encountered potassium-rich clastic sedimentary rocks at two sites in Gale Crater, the waypoints Cooperstown and Kimberley. These rocks include several distinct meters thick sedimentary outcrops ranging from fine sandstone to conglomerate, interpreted to record an ancient fluvial or fluvio-deltaic depositional system. From ChemCam Laser-Induced Breakdown Spectroscopy (LIBS) chemical analyses, this suite of sedimentary rocks has an overall mean K2O abundance that is more than 5 times higher than that of the average Martian crust. The combined analysis of ChemCam data with stratigraphic and geographic locations reveals that the mean K2O abundance increases upward through the stratigraphic section. Chemical analyses across each unit can be represented as mixtures of several distinct chemical components, i.e., mineral phases, including K-bearing minerals, mafic silicates, Fe-oxides, and Fe-hydroxide/oxyhydroxides. Possible K-bearing minerals include alkali feldspar (including anorthoclase and sanidine) and K-bearing phyllosilicate such as illite. Mixtures of different source rocks, including a potassium-rich rock located on the rim and walls of Gale Crater, are the likely origin of observed chemical variations within each unit. Physical sorting may have also played a role in the enrichment in K in the Kimberley formation. The occurrence of these potassic sedimentary rocks provides additional evidence for the chemical diversity of the crust exposed at Gale Crater
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