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Discussion of High Thermal Inertia Craters on Mars in the Isidis and Syrtis Major Regions Jordana Friedman Arizona State University.

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Presentation on theme: "Discussion of High Thermal Inertia Craters on Mars in the Isidis and Syrtis Major Regions Jordana Friedman Arizona State University."— Presentation transcript:

1 Discussion of High Thermal Inertia Craters on Mars in the Isidis and Syrtis Major Regions Jordana Friedman Arizona State University

2 Background Why the Isidis and Syrtis Major regions? – Volcanic history/diversity – Large impact basin Why moderate-high thermal inertia? – Lower than bedrock, higher than unconsolidated material Looking to distinguish between in situ bedrock vs. cemented finer grains – Primary martian magma composition – Alteration products, chemical weathering, and cementation

3 Methods Used THEMIS database to locate high TI (800-1200 JK -1 m -2 s -1/2 ) craters Examined each instance (87 total) for: – Albedo – Depth – Diameter – Floor diameter – Thermal inertia – Latitude/longitude – Morphology

4 Crater Examples THEMIS day image THEMIS night image Low thermal inertia High thermal inertia floor High thermal inertia walls Central peak Flat floored

5 High Resolution CTX Images High thermal inertia Low thermal inertia

6 Results The craters have different albedo, with similar thermal inertias: Bimodal albedo distribution Relatively low average thermal inertia

7 Dust Cover Index The red areas are dustier, and the blue areas are less dusty. There are craters in each area that have elevated thermal inertia.

8 Conclusions It was not possible to differentiate between in situ rock and cemented rock in this study However, it may be possible that there is a thin layer of dust on some surfaces – Enough to affect the albedo of these surfaces, but not enough to affect thermal inertia

9 Future Studies Study the composition of these craters using TES, THEMIS and CRISM – Better constrain the nature/formation mechanism of the surfaces Study larger and other areas, potentially global – Areas where other weathering products identified – Look for global trends

10 Thank You! A special thanks to Chris Edwards, my advisor Thanks to the NASA Space Grant Program for this opportunity! Thanks to my family and friends for their support 2001 Mars Odyssey/THEMIS Project and support staff

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