Your search keyword '"Pamela G. Conrad"' showing total 3 results

1. Mars methane detection and variability at Gale crater

Author

Susanne P. Schwenzer, Christopher R. Webster, Tobias Owen, Mark T. Lemmon, Javier Martin-Torres, Sushil K. Atreya, Michael A. Mischna, John Bridges, P. Douglas Archer, G. Flesch, Patrice Coll, Kenneth A. Farley, Ralf Gellert, Alexander A. Pavlov, Daniel P. Glavin, Christopher P. McKay, Andrew Steele, Jennifer L. Eigenbrode, Paul R. Mahaffy, Timothy H. McConnochie, Rafael Navarro-González, John E. Moores, Charles Malespin, Pamela G. Conrad, Brad Sutter, Caroline Freissinet, María Paz Zorzano, Lance E. Christensen, and Pierre-Yves Meslin

Subjects

Multidisciplinary, Spectrometer, Atmospheric methane, Mars, methane detection, Mars Exploration Program, Atmosphere of Mars, Gale crater, Methane, Astrobiology, chemistry.chemical_compound, Interplanetary dust cloud, Curiosity, chemistry, Carbonaceous chondrite, Sample Analysis at Mars, Environmental science

Abstract

Of water and methane on Mars The Curiosity rover has been collecting data for the past 2 years, since its delivery to Mars (see the Perspective by Zahnle). Many studies now suggest that many millions of years ago, Mars was warmer and wetter than it is today. But those conditions required an atmosphere that seems to have vanished. Using the Curiosity rover, Mahaffy et al. measured the ratio of deuterium to hydrogen in clays that were formed 3.0 to 3.7 billion years ago. Hydrogen escapes more readily than deuterium, so this ratio offers a snapshot measure of the ancient atmosphere that can help constrain when and how it disappeared. Most methane on Earth has a biological origin, so planetary scientists have keenly pursued its detection in the martian atmosphere as well. Now, Webster et al. have precisely confirmed the presence of methane in the martian atmosphere with the instruments aboard the Curiosity rover at Gale crater. Science , this issue p. 412 , p. 415 ; see also p. 370

Published

2015

2. A Reduced Organic Carbon Component in Martian Basalts

Author

L. Kater, Hans E. F. Amundsen, R. Bowden, Edward P. Vicenzi, Pamela G. Conrad, Francis M. McCubbin, Steven B. Shirey, Allan H. Treiman, Sandra Siljeström, Richard N. Zare, Nabil Z. Boctor, Marc Fries, Mihaela Glamoclija, Maegan K. Spencer, Christopher D. K. Herd, Andrew Steele, Matthew R. Hammond, Marilyn L. Fogel, A. J. T. Jull, Emma S. Bullock, Amy L. Morrow, and Bjorn O. Mysen

Subjects

Total organic carbon, Martian, Basalt, Multidisciplinary, Extraterrestrial Environment, Chemistry, Silicates, Mars, chemistry.chemical_element, Mineralogy, Oxides, Meteoroids, Mars Exploration Program, Spectrum Analysis, Raman, Carbon, Astrobiology, Carbon cycle, Meteorite, Sample Analysis at Mars, Organic Chemicals, Polycyclic Aromatic Hydrocarbons, Crystallization, Oxidation-Reduction

Abstract

Abiotic Martian Organics Understanding the sources and the formation mechanisms of organic carbon compounds on Mars has implications for our understanding of the martian carbon cycle. Steele et al. (p. 212 , published online 24 May) present measurements of organic material in 11 martian meteorites, including the Tissint meteorite, which fell in the Moroccan desert in July 2011. Ten of the meteorites contain complex hydrocarbons encased within igneous minerals. The results imply that the organics formed as the magma melt crystallized and are thus of abiotic origin.

Published

2012

3. Scratching the surface of martian habitability

Author

Pamela G. Conrad

Subjects

Earth analog, Mars rover, Martian, Multidisciplinary, Planetary habitability, Planetary surface, Planet, Habitability, Mars Exploration Program, Astrobiology

Abstract

Earth and Mars, though formed at the same time from the same materials, look very different today. Early in their histories they evolved through some of the same processes, but at some point their evolutionary paths diverged, sending them in perhaps irrevocably different directions. Knowledge of the factors that contributed to such different outcomes will help to determine how planets become habitable and how common habitable planets may be. The Mars surface environment is harsh today, but in situ measurements of ancient sedimentary rock by Mars Science Laboratory reveal chemical and mineralogical evidence of past conditions that might have been more favorable for life to exist. But chemistry is only part of what is required to make an environment habitable. Physical conditions constrain the chemical reactions that underlie life processes; the chemical and physical characteristics that make planets habitable are thus entangled.

Published

2014