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Recurrence Rate and Magma Effusion Rate for the Latest Volcanism on Arsia Mons, MarsMagmatism and volcanism have evolved the Martian lithosphere, surface, and climate throughout the history of Mars. Constraining the rates of magma generation and timing of volcanism on the surface clarifies the ways in which magma and volcanic activity have shaped these Martian systems. The ages of lava flows on other planets are often estimated using impact crater counts, assuming that the number and size-distribution of impact craters per unit area reflect the time the lava flow has been on the surface and exposed to potential impacts. Here we show that impact crater age model uncertainty is reduced by adding stratigraphic information observed at locations where neighboring lavas abut each other, and demonstrate the significance of this reduction in age uncertainty for understanding the history of a volcanic field comprising 29 vents in the 110-kilometer-diameter caldera of Arsia Mons, Mars. Each vent within this caldera produced lava flows several to tens of kilometers in length; these vents are likely among the youngest on Mars, since no impact craters in their lava flows are larger than 1 kilometer in diameter. First, we modeled the age of each vent with impact crater counts performed on their corresponding lava flows and found very large age uncertainties for the ages of individual vents, often spanning the estimated age for the entire volcanic field. The age model derived from impact crater counts alone is broad and unimodal, with estimated peak activity in the field around 130Ma (megaannum, 1 million years). Next we applied our volcano event age model (VEAM), which uses a directed graph of stratigraphic relationships and random sampling of the impact crater age determinations to create alternative age models. Monte Carlo simulation was used to create 10,000 possible vent age sets. The recurrence rate of volcanism is calculated for each possible age set, and these rates are combined to calculate the median recurrence rate of all simulations. Applying this approach to the 29 volcanic vents, volcanism likely began around 200-300Ma then first peaked around 150Ma, with an average production rate of 0.4 vents per Myr (million years). The recurrence rate estimated including stratigraphic data is distinctly bimodal, with a second, lower peak in activity around 100Ma. Volcanism then waned until the final vents were produced 10-90Ma. Based on this model, volume flux is also bimodal, reached a peak rate of 1-8 cubic kilometers per million years by 150Ma and remained above half this rate until about 90Ma, after which the volume flux diminished greatly. The onset of effusive volcanism from 200-150Ma might be due to a transition of volcanic style away from explosive volcanism that emplaced tephra on the western flank of Arsia Mons, while the waning of volcanism after the 150Ma peak might represent a larger-scale diminishing of volcanic activity at Arsia Mons related to the emplacement of flank apron lavas.
Document ID
20170002329
Document Type
Reprint (Version printed in journal)
Authors
Richardson, Jacob A. (University of South Florida Tampa, FL, United States)
Wilson, James A. (University of South Florida Tampa, FL, United States)
Connor, Charles B. (University of South Florida Tampa, FL, United States)
Bleacher, Jacob E. (NASA Goddard Space Flight Center Greenbelt, MD United States)
Kiyosugi, Koji (Kobe Univ. Japan)
Date Acquired
March 17, 2017
Publication Date
November 10, 2016
Publication Information
Publication: Earth and Planetary Science Letters
Volume: 458
ISSN: 0012-821X
Subject Category
Geophysics
Lunar and Planetary Science and Exploration
Report/Patent Number
GSFC-E-DAA-TN40012
Funding Number(s)
CONTRACT_GRANT: NSF-ACI-1339768
CONTRACT_GRANT: NASA-13-MDAP13-0026
CONTRACT_GRANT: NNH15CO48B
CONTRACT_GRANT: NNX14AN02G
Distribution Limits
Public
Copyright
Other