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Evolution of Clay Minerals on the Surface of Mars. Introduction Clays Oldest material that are products of interactions with water (Poulet et al., 2005) May be responsible for Mars’ red color (Weldon et al., 1982) Can support organic material. Clays. Future Experiments.
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Evolution of Clay Minerals on the Surface of Mars • Introduction • Clays • Oldest material that are products of interactions with water (Poulet et al., 2005) • May be responsible for Mars’ red color (Weldon et al., 1982) • Can support organic material Clays Future Experiments In the Andromeda Vacuum Chamber: • We first want to replicate previous experiments and compare the results, then conduct new ones. We will do two experiments in the Chamber: • Record the desorption rate of water through a layer of wet clay. • 2. Measure the sublimation rate of ice under a layer of clay. • Both of these experiments will be conducted in martian atmospheric conditions, with varying temperatures. Hydrological Experiments Figure 1: The blue area maps out where aluminum-rich clays are found. (Image taken from Poulet et al., 2005.) In the High-Temperature Ovens: This sample of montmorillonite was placed in a desiccator over night so that it absorbed as much water as possible. Then we heated it to 50oC, and weighed it at regular intervals. We found a correlation of time heated with mass loss. This mass loss is due to the loss of absorbed water in the montmorillonite. • We will, again, replicate previous experiments, then conduct new ones. • Heat one-gram samples of different types of clays to 750oC to 1000oC, and compare results to those of previous experiments. These experiments will be conducted in air (Earth atmosphere). • Heat one-gram samples to the same temperatures in CO2. This experiment has never been done before and is anticipated to give interesting results. Figure 2: (a) and (b) are infrared images taken by THEMIS. (c) and (d) are enlarged optical images taken by the Mars Orbiter Camera. The blue area is a superimposed map of iron-rich clays. Lava appears brighter in infrared than the surrounding clays due to its higher temperature, a result of its lower albedo. (Image taken from Poulet et al., 2005.) MineralogicalExperiments (a) (b) Acknowledgements • Dr. Vincent Chevrier – Mentor, for his guidance through these experiments • Walter Graupner - Lab Manager, for finding all the right parts and helping us assemble those parts for each experiment • University of Arkansas – for allowing us to use their superior facilities in conducting these experiments Figure 3: Nili Fossae (Images taken from Mustard et al., 2006.) (a) Green – Low-Calcium pyroxene Blue – Phyllosilicates Pink – Olivine (b) “O” indicates location of olivine-bearing rocks Figure 4: Two samples of nontronite. The samples on the left are non-treated nontronite. The sample on the right in the upper image was heated in air to 750oC for 6 hours. The sample on the right in the lower image was heated in air to 1000oC for 6 hours. Note the color change as the clay’s molecular structure changes during heating. Patricia Gavin – Florida Institute of Technology Dr. Vincent Chevrier – University of Arkansas