Physical abrasion of mafic minerals and basalt grains: Application to martian aeolian deposits

• Published in: Icarus (New York, N.Y. 1962) Vol. 256; pp. 13 - 21
• Main Authors: Cornwall, C., Bandfield, J.L., Titus, T.N., Schreiber, B.C., Montgomery, D.R.
• Format: Journal Article
• Language: English
• Published: Elsevier Inc 01.08.2015
• Subjects: Abrasion; Abrasion resistance; Aeolian processes; Basalt; Deposition; Earth; Mars; Mars, surface; Mineralogy; Sands; Sediments; Weathering; Mars; Aeolian processes; Mars, surface; Mineralogy
• ISSN: 0019-1035; 1090-2643
• DOI: 10.1016/j.icarus.2015.04.020

•We explore the mechanical durability of mafic minerals and volcanic materials.•Polycrystalline materials were found to be the most durable during abrasion.•Terrestrial samples are compared to abraded samples using SEM imagery.•We propose a mafic mineral maturity index for martian aeolian environments. Sediment maturity, or the mineralogical and physical characterization of sedimentary deposits, has been used to identify sediment sources, transport medium and distance, weathering processes, and paleoenvironments on Earth. Mature terrestrial sands are dominated by quartz, which is abundant in source lithologies on Earth and is physically and chemically stable under a wide range of conditions. Immature sands, such as those rich in feldspars or mafic minerals, are composed of grains that are easily physically weathered and highly susceptible to chemical weathering. On Mars, which is predominately mafic in composition, terrestrial standards of sediment maturity are not applicable. In addition, the martian climate today is cold and dry and sediments are likely to be heavily influenced by physical weathering rather than chemical weathering. Due to these large differences in weathering processes and composition, martian sediments require an alternate maturity index. This paper reports the results of abrasion tests conducted on a variety of mafic materials and results suggest that mature martian sediments may be composed of well sorted, well rounded, spherical polycrystalline materials, such as basalt. Volcanic glass is also likely to persist in a mechanical weathering environment while more fragile and chemically altered products are likely to be winnowed away. A modified sediment maturity index is proposed that can be used in future studies to constrain sediment source, paleoclimate, mechanisms for sediment production, and surface evolution. This maturity index may also provide insights into erosional and sediment transport systems and preservation processes of layered deposits.