TY - JOUR
T1 - Mars chronology
T2 - Assessing techniques for quantifying surficial processes
AU - Doran, Peter T.
AU - Clifford, Stephen M.
AU - Forman, Steven L.
AU - Nyquist, Larry
AU - Papanastassiou, Dimitri A.
AU - Stewart, Brian W.
AU - Sturchio, Neil C.
AU - Swindle, Timothy D.
AU - Cerling, Thure
AU - Kargel, Jeff
AU - McDonald, Gene
AU - Nishiizumi, Kunihiko
AU - Poreda, Robert
AU - Rice, James W.
AU - Tanaka, Ken
N1 - Funding Information: This paper is based on a workshop held at the University of Illinois at Chicago in July 2000. We would like to thank the other participants: P. Beauchamp, L. Borg, C. Budney, G. Cardell, F. Carsey, J. Christensen, J. Cutts, A. Davis, W. Davis, S. Guggenheim, D. Kossakovski, J. Lawson, K. Lepper, S. McKeever, C. McKay, R. Morris, M. Taylor and M. Wadhwa. The workshop was supported by the Mars Program Office, Jet Propulsion Laboratory (Contract #1215592). The writing of this paper was partially supported by the NASA Exobiology Program (NAG5-9427).
PY - 2004/10
Y1 - 2004/10
N2 - Currently, the absolute chronology of Martian rocks, deposits and events is based mainly on crater counting and remains highly imprecise with epoch boundary uncertainties in excess of 2 billion years. Answers to key questions concerning the comparative origin and evolution of Mars and Earth will not be forthcoming without a rigid Martian chronology, enabling the construction of a time scale comparable to Earth's. Priorities for exploration include calibration of the cratering rate, dating major volcanic and fluvial events and establishing chronology of the polar layered deposits. If extinct and/or extant life is discovered, the chronology of the biosphere will be of paramount importance. Many radiometric and cosmogenic techniques applicable on Earth and the Moon will apply to Mars after certain baselines (e.g. composition of the atmosphere, trace species, chemical and physical characteristics of Martian dust) are established. The high radiation regime may pose a problem for dosimetry-based techniques (e.g. luminescence). The unique isotopic composition of nitrogen in the Martian atmosphere may permit a Mars-specific chronometer for tracing the time-evolution of the atmosphere and of lithic phases with trapped atmospheric gases. Other Mars-specific chronometers include measurement of gas fluxes and accumulation of platinum group elements (PGE) in the regolith. Putting collected samples into geologic context is deemed essential, as is using multiple techniques on multiple samples. If in situ measurements are restricted to a single technique it must be shown to give consistent results on multiple samples, but in all cases, using two or more techniques (e.g. on the same lander) will reduce error. While there is no question that returned samples will yield the best ages, in situ techniques have the potential to be flown on multiple missions providing a larger data set and broader context in which to place the more accurate dates.
AB - Currently, the absolute chronology of Martian rocks, deposits and events is based mainly on crater counting and remains highly imprecise with epoch boundary uncertainties in excess of 2 billion years. Answers to key questions concerning the comparative origin and evolution of Mars and Earth will not be forthcoming without a rigid Martian chronology, enabling the construction of a time scale comparable to Earth's. Priorities for exploration include calibration of the cratering rate, dating major volcanic and fluvial events and establishing chronology of the polar layered deposits. If extinct and/or extant life is discovered, the chronology of the biosphere will be of paramount importance. Many radiometric and cosmogenic techniques applicable on Earth and the Moon will apply to Mars after certain baselines (e.g. composition of the atmosphere, trace species, chemical and physical characteristics of Martian dust) are established. The high radiation regime may pose a problem for dosimetry-based techniques (e.g. luminescence). The unique isotopic composition of nitrogen in the Martian atmosphere may permit a Mars-specific chronometer for tracing the time-evolution of the atmosphere and of lithic phases with trapped atmospheric gases. Other Mars-specific chronometers include measurement of gas fluxes and accumulation of platinum group elements (PGE) in the regolith. Putting collected samples into geologic context is deemed essential, as is using multiple techniques on multiple samples. If in situ measurements are restricted to a single technique it must be shown to give consistent results on multiple samples, but in all cases, using two or more techniques (e.g. on the same lander) will reduce error. While there is no question that returned samples will yield the best ages, in situ techniques have the potential to be flown on multiple missions providing a larger data set and broader context in which to place the more accurate dates.
KW - Chronology
KW - Dating
KW - Mars
KW - Surficial processes
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U2 - 10.1016/j.earscirev.2004.04.001
DO - 10.1016/j.earscirev.2004.04.001
M3 - Article
SN - 0012-8252
VL - 67
SP - 313
EP - 337
JO - Earth-Science Reviews
JF - Earth-Science Reviews
IS - 3-4
ER -