TY - JOUR
T1 - Nitrogen Incorporation in Potassic and Micro- and Meso-Porous Minerals
T2 - Potential Biogeochemical Records and Targets for Mars Sampling
AU - Nikitczuk, Matthew P.
AU - Bebout, Gray E.
AU - Geiger, Charles A.
AU - Ota, Tsutomu
AU - Kunihiro, Takuya
AU - Mustard, John F.
AU - Halldórsson, Sæmundur A.
AU - Nakamura, Eizo
N1 - Publisher Copyright:
© Matthew P. Nikitczuk et al., 2022; Published by Mary Ann Liebert, Inc. 2022.
PY - 2022/11
Y1 - 2022/11
N2 - We measured the N concentrations and isotopic compositions of 44 samples of terrestrial potassic and micro- and meso-porous minerals and a small number of whole-rocks to determine the extent to which N is incorporated and stored during weathering and low-temperature hydrothermal alteration in Mars surface/near-surface environments. The selection of these minerals and other materials was partly guided by the study of altered volcanic glass from Antarctica and Iceland, in which the incorporation of N as NH4+ in phyllosilicates is indicated by correlated concentrations of N and the LILEs (i.e., K, Ba, Rb, Cs), with scatter likely related to the presence of exchanged, occluded/trapped, or encapsulated organic/inorganic N occurring within structural cavities (e.g., in zeolites). The phyllosilicates, zeolites, and sulfates analyzed in this study contain between 0 and 99,120 ppm N and have δ15Nair values of -34‰ to +65‰. Most of these minerals, and the few siliceous hydrothermal deposits that were analyzed, have δ15N consistent with the incorporation of biologically processed N during low-temperature hydrothermal or weathering processes. Secondary ion mass spectrometry on altered hyaloclastites demonstrates the residency of N in smectites and zeolites, and silica. We suggest that geological materials known on Earth to incorporate and store N and known to be abundant at, or near, the surface of Mars should be considered targets for upcoming Mars sample return with the intent to identify any signs of ancient or modern life.
AB - We measured the N concentrations and isotopic compositions of 44 samples of terrestrial potassic and micro- and meso-porous minerals and a small number of whole-rocks to determine the extent to which N is incorporated and stored during weathering and low-temperature hydrothermal alteration in Mars surface/near-surface environments. The selection of these minerals and other materials was partly guided by the study of altered volcanic glass from Antarctica and Iceland, in which the incorporation of N as NH4+ in phyllosilicates is indicated by correlated concentrations of N and the LILEs (i.e., K, Ba, Rb, Cs), with scatter likely related to the presence of exchanged, occluded/trapped, or encapsulated organic/inorganic N occurring within structural cavities (e.g., in zeolites). The phyllosilicates, zeolites, and sulfates analyzed in this study contain between 0 and 99,120 ppm N and have δ15Nair values of -34‰ to +65‰. Most of these minerals, and the few siliceous hydrothermal deposits that were analyzed, have δ15N consistent with the incorporation of biologically processed N during low-temperature hydrothermal or weathering processes. Secondary ion mass spectrometry on altered hyaloclastites demonstrates the residency of N in smectites and zeolites, and silica. We suggest that geological materials known on Earth to incorporate and store N and known to be abundant at, or near, the surface of Mars should be considered targets for upcoming Mars sample return with the intent to identify any signs of ancient or modern life.
KW - Biogeochemistry
KW - Mars
KW - Planetary habitability and biosignatures
KW - Silicates. Astrobiology 22, 1293-1309
KW - Stable isotopes
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U2 - 10.1089/ast.2021.0158
DO - 10.1089/ast.2021.0158
M3 - Article
C2 - 36074082
AN - SCOPUS:85141888838
SN - 1531-1074
VL - 22
SP - 1293
EP - 1309
JO - Astrobiology
JF - Astrobiology
IS - 11
ER -