Hydrogen in magnetite from asteroid Ryugu

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Hydrogen in magnetite from asteroid Ryugu. / Aléon, J.; Mostefaoui, S.; Bureau, H.; Vangu, D.; Khodja, H.; Nagashima, K.; Kawasaki, N.; Abe, Y.; Alexander, C. M. O'D.; Amari, S.; Amelin, Y.; Bajo, K.; Bizzarro, M.; Bouvier, A.; Carlson, R. W.; Chaussidon, M.; Choi, B.-G.; Dauphas, N.; Davis, A. M.; Di Rocco, T.; Fujiya, W.; Fukai, R.; Gautam, I.; Haba, M. K.; Hibiya, Y.; Hidaka, H.; Homma, H.; Hoppe, P.; Huss, G. R.; Ichida, K.; Iizuka, T.; Ireland, T. R.; Ishikawa, A.; Itoh, S.; Kita, N. T.; Kitajima, K.; Kleine, T.; Komatani, S.; Krot, A. N.; Liu, M.-C.; Masuda, Y.; Morita, M.; Motomura, K.; Moynier, F.; Nakai, I.; Nguyen, A.; Nittler, L. R.; Onose, M.; Pack, A.; Park, C.; Piani, L.; Qin, L.; Russell, S. S.; Sakamoto, N.; Schönbächler, M.; Tafla, L.; Tang, H.; Terada, K.; Terada, Y.; Usui, T.; Wada, S.; Wadhwa, M.; Walker, R. J.; Yamashita, K.; Yin, Q.-Z.; Yokoyama, T.; Yoneda, S.; Young, E. D.; Yui, H.; Zhang, A.-C.; Nakamura, T.; Naraoka, H.; Noguchi, T.; Okazaki, R.; Sakamoto, K.; Yabuta, H.; Abe, M.; Miyazaki, A.; Nakato, A.; Nishimura, M.; Okada, T.; Yada, T.; Yogata, K.; Nakazawa, S.; Saiki, T.; Tanaka, S.; Terui, F.; Tsuda, Y.; Watanabe, S.; Yoshikawa, M.; Tachibana, S.; Yurimoto, H.

In: Meteoritics and Planetary Science, 2024.

Research output: Contribution to journal › Journal article › Research › peer-review

Harvard

Aléon, J, Mostefaoui, S, Bureau, H, Vangu, D, Khodja, H, Nagashima, K, Kawasaki, N, Abe, Y, Alexander, CMOD, Amari, S, Amelin, Y, Bajo, K, Bizzarro, M, Bouvier, A, Carlson, RW, Chaussidon, M, Choi, B-G, Dauphas, N, Davis, AM, Di Rocco, T, Fujiya, W, Fukai, R, Gautam, I, Haba, MK, Hibiya, Y, Hidaka, H, Homma, H, Hoppe, P, Huss, GR, Ichida, K, Iizuka, T, Ireland, TR, Ishikawa, A, Itoh, S, Kita, NT, Kitajima, K, Kleine, T, Komatani, S, Krot, AN, Liu, M-C, Masuda, Y, Morita, M, Motomura, K, Moynier, F, Nakai, I, Nguyen, A, Nittler, LR, Onose, M, Pack, A, Park, C, Piani, L, Qin, L, Russell, SS, Sakamoto, N, Schönbächler, M, Tafla, L, Tang, H, Terada, K, Terada, Y, Usui, T, Wada, S, Wadhwa, M, Walker, RJ, Yamashita, K, Yin, Q-Z, Yokoyama, T, Yoneda, S, Young, ED, Yui, H, Zhang, A-C, Nakamura, T, Naraoka, H, Noguchi, T, Okazaki, R, Sakamoto, K, Yabuta, H, Abe, M, Miyazaki, A, Nakato, A, Nishimura, M, Okada, T, Yada, T, Yogata, K, Nakazawa, S, Saiki, T, Tanaka, S, Terui, F, Tsuda, Y, Watanabe, S, Yoshikawa, M, Tachibana, S & Yurimoto, H 2024, 'Hydrogen in magnetite from asteroid Ryugu', Meteoritics and Planetary Science. https://doi.org/10.1111/maps.14139

APA

Aléon, J., Mostefaoui, S., Bureau, H., Vangu, D., Khodja, H., Nagashima, K., Kawasaki, N., Abe, Y., Alexander, C. M. OD., Amari, S., Amelin, Y., Bajo, K., Bizzarro, M., Bouvier, A., Carlson, R. W., Chaussidon, M., Choi, B-G., Dauphas, N., Davis, A. M., ... Yurimoto, H. (2024). Hydrogen in magnetite from asteroid Ryugu. Meteoritics and Planetary Science. https://doi.org/10.1111/maps.14139

Vancouver

Aléon J, Mostefaoui S, Bureau H, Vangu D, Khodja H, Nagashima K et al. Hydrogen in magnetite from asteroid Ryugu. Meteoritics and Planetary Science. 2024. https://doi.org/10.1111/maps.14139

Author

Aléon, J. ; Mostefaoui, S. ; Bureau, H. ; Vangu, D. ; Khodja, H. ; Nagashima, K. ; Kawasaki, N. ; Abe, Y. ; Alexander, C. M. O'D. ; Amari, S. ; Amelin, Y. ; Bajo, K. ; Bizzarro, M. ; Bouvier, A. ; Carlson, R. W. ; Chaussidon, M. ; Choi, B.-G. ; Dauphas, N. ; Davis, A. M. ; Di Rocco, T. ; Fujiya, W. ; Fukai, R. ; Gautam, I. ; Haba, M. K. ; Hibiya, Y. ; Hidaka, H. ; Homma, H. ; Hoppe, P. ; Huss, G. R. ; Ichida, K. ; Iizuka, T. ; Ireland, T. R. ; Ishikawa, A. ; Itoh, S. ; Kita, N. T. ; Kitajima, K. ; Kleine, T. ; Komatani, S. ; Krot, A. N. ; Liu, M.-C. ; Masuda, Y. ; Morita, M. ; Motomura, K. ; Moynier, F. ; Nakai, I. ; Nguyen, A. ; Nittler, L. R. ; Onose, M. ; Pack, A. ; Park, C. ; Piani, L. ; Qin, L. ; Russell, S. S. ; Sakamoto, N. ; Schönbächler, M. ; Tafla, L. ; Tang, H. ; Terada, K. ; Terada, Y. ; Usui, T. ; Wada, S. ; Wadhwa, M. ; Walker, R. J. ; Yamashita, K. ; Yin, Q.-Z. ; Yokoyama, T. ; Yoneda, S. ; Young, E. D. ; Yui, H. ; Zhang, A.-C. ; Nakamura, T. ; Naraoka, H. ; Noguchi, T. ; Okazaki, R. ; Sakamoto, K. ; Yabuta, H. ; Abe, M. ; Miyazaki, A. ; Nakato, A. ; Nishimura, M. ; Okada, T. ; Yada, T. ; Yogata, K. ; Nakazawa, S. ; Saiki, T. ; Tanaka, S. ; Terui, F. ; Tsuda, Y. ; Watanabe, S. ; Yoshikawa, M. ; Tachibana, S. ; Yurimoto, H. / Hydrogen in magnetite from asteroid Ryugu. In: Meteoritics and Planetary Science. 2024.

Bibtex

@article{a469b59d323a49bb9a7a8cf238acec9d,

title = "Hydrogen in magnetite from asteroid Ryugu",

abstract = "In order to gain insights on the conditions of aqueous alteration on asteroid Ryugu and the origin of water in the outer solar system, we developed the measurement of water content in magnetite at the micrometer scale by secondary ion mass spectrometry (NanoSIMS) and determined the H and Si content of coarse-grained euhedral magnetite grains (polyhedral magnetite) and coarse-grained fibrous (spherulitic) magnetite from the Ryugu polished section A0058-C1001. The hydrogen content in magnetite ranges between ~900 and ~3300 wt ppm equivalent water and is correlated with the Si content. Polyhedral magnetite has low and homogenous silicon and water content, whereas fibrous magnetite shows correlated Si and water excesses. These excesses can be explained by the presence of hydrous Si-rich amorphous nanoinclusions trapped during the precipitation of fibrous magnetite away from equilibrium and testify that fibrous magnetite formed from a hydrous gel with possibly more than 20 wt% water. An attempt to determine the water content in sub-μm framboids indicates that additional calibration and contamination issues must be addressed before a safe conclusion can be drawn, but hints at elevated water content as well. The high water content in fibrous magnetite, expected to be among the first minerals to crystallize at low water–rock ratio, points to the control of water content by local conditions of magnetite precipitation rather than large-scale alteration conditions. Systematic lithological variations associated with water-rich and water-poor magnetite suggest that the global context of alteration may be better understood if local water concentrations are compared with millimeter-scale distribution of the various morphologies of magnetite. Finally, the high water content in the magnetite precursor gel indicates that the initial O isotopic composition in alteration water must not have been very different from that of the earliest magnetite crystals.",

author = "J. Al{\'e}on and S. Mostefaoui and H. Bureau and D. Vangu and H. Khodja and K. Nagashima and N. Kawasaki and Y. Abe and Alexander, {C. M. O'D.} and S. Amari and Y. Amelin and K. Bajo and M. Bizzarro and A. Bouvier and Carlson, {R. W.} and M. Chaussidon and B.-G. Choi and N. Dauphas and Davis, {A. M.} and {Di Rocco}, T. and W. Fujiya and R. Fukai and I. Gautam and Haba, {M. K.} and Y. Hibiya and H. Hidaka and H. Homma and P. Hoppe and Huss, {G. R.} and K. Ichida and T. Iizuka and Ireland, {T. R.} and A. Ishikawa and S. Itoh and Kita, {N. T.} and K. Kitajima and T. Kleine and S. Komatani and Krot, {A. N.} and M.-C. Liu and Y. Masuda and M. Morita and K. Motomura and F. Moynier and I. Nakai and A. Nguyen and Nittler, {L. R.} and M. Onose and A. Pack and C. Park and L. Piani and L. Qin and Russell, {S. S.} and N. Sakamoto and M. Sch{\"o}nb{\"a}chler and L. Tafla and H. Tang and K. Terada and Y. Terada and T. Usui and S. Wada and M. Wadhwa and Walker, {R. J.} and K. Yamashita and Q.-Z. Yin and T. Yokoyama and S. Yoneda and Young, {E. D.} and H. Yui and A.-C. Zhang and T. Nakamura and H. Naraoka and T. Noguchi and R. Okazaki and K. Sakamoto and H. Yabuta and M. Abe and A. Miyazaki and A. Nakato and M. Nishimura and T. Okada and T. Yada and K. Yogata and S. Nakazawa and T. Saiki and S. Tanaka and F. Terui and Y. Tsuda and S. Watanabe and M. Yoshikawa and S. Tachibana and H. Yurimoto",

note = "Publisher Copyright: {\textcopyright} 2024 The Authors. Meteoritics & Planetary Science published by Wiley Periodicals LLC on behalf of The Meteoritical Society.",

year = "2024",

doi = "10.1111/maps.14139",

language = "English",

journal = "Meteoritics and Planetary Science",

issn = "1086-9379",

publisher = "JohnWiley & Sons, Inc.",

}

RIS

TY - JOUR

T1 - Hydrogen in magnetite from asteroid Ryugu

AU - Aléon, J.

AU - Mostefaoui, S.

AU - Bureau, H.

AU - Vangu, D.

AU - Khodja, H.

AU - Nagashima, K.

AU - Kawasaki, N.

AU - Abe, Y.

AU - Alexander, C. M. O'D.

AU - Amari, S.

AU - Amelin, Y.

AU - Bajo, K.

AU - Bizzarro, M.

AU - Bouvier, A.

AU - Carlson, R. W.

AU - Chaussidon, M.

AU - Choi, B.-G.

AU - Dauphas, N.

AU - Davis, A. M.

AU - Di Rocco, T.

AU - Fujiya, W.

AU - Fukai, R.

AU - Gautam, I.

AU - Haba, M. K.

AU - Hibiya, Y.

AU - Hidaka, H.

AU - Homma, H.

AU - Hoppe, P.

AU - Huss, G. R.

AU - Ichida, K.

AU - Iizuka, T.

AU - Ireland, T. R.

AU - Ishikawa, A.

AU - Itoh, S.

AU - Kita, N. T.

AU - Kitajima, K.

AU - Kleine, T.

AU - Komatani, S.

AU - Krot, A. N.

AU - Liu, M.-C.

AU - Masuda, Y.

AU - Morita, M.

AU - Motomura, K.

AU - Moynier, F.

AU - Nakai, I.

AU - Nguyen, A.

AU - Nittler, L. R.

AU - Onose, M.

AU - Pack, A.

AU - Park, C.

AU - Piani, L.

AU - Qin, L.

AU - Russell, S. S.

AU - Sakamoto, N.

AU - Schönbächler, M.

AU - Tafla, L.

AU - Tang, H.

AU - Terada, K.

AU - Terada, Y.

AU - Usui, T.

AU - Wada, S.

AU - Wadhwa, M.

AU - Walker, R. J.

AU - Yamashita, K.

AU - Yin, Q.-Z.

AU - Yokoyama, T.

AU - Yoneda, S.

AU - Young, E. D.

AU - Yui, H.

AU - Zhang, A.-C.

AU - Nakamura, T.

AU - Naraoka, H.

AU - Noguchi, T.

AU - Okazaki, R.

AU - Sakamoto, K.

AU - Yabuta, H.

AU - Abe, M.

AU - Miyazaki, A.

AU - Nakato, A.

AU - Nishimura, M.

AU - Okada, T.

AU - Yada, T.

AU - Yogata, K.

AU - Nakazawa, S.

AU - Saiki, T.

AU - Tanaka, S.

AU - Terui, F.

AU - Tsuda, Y.

AU - Watanabe, S.

AU - Yoshikawa, M.

AU - Tachibana, S.

AU - Yurimoto, H.

PY - 2024

Y1 - 2024

N2 - In order to gain insights on the conditions of aqueous alteration on asteroid Ryugu and the origin of water in the outer solar system, we developed the measurement of water content in magnetite at the micrometer scale by secondary ion mass spectrometry (NanoSIMS) and determined the H and Si content of coarse-grained euhedral magnetite grains (polyhedral magnetite) and coarse-grained fibrous (spherulitic) magnetite from the Ryugu polished section A0058-C1001. The hydrogen content in magnetite ranges between ~900 and ~3300 wt ppm equivalent water and is correlated with the Si content. Polyhedral magnetite has low and homogenous silicon and water content, whereas fibrous magnetite shows correlated Si and water excesses. These excesses can be explained by the presence of hydrous Si-rich amorphous nanoinclusions trapped during the precipitation of fibrous magnetite away from equilibrium and testify that fibrous magnetite formed from a hydrous gel with possibly more than 20 wt% water. An attempt to determine the water content in sub-μm framboids indicates that additional calibration and contamination issues must be addressed before a safe conclusion can be drawn, but hints at elevated water content as well. The high water content in fibrous magnetite, expected to be among the first minerals to crystallize at low water–rock ratio, points to the control of water content by local conditions of magnetite precipitation rather than large-scale alteration conditions. Systematic lithological variations associated with water-rich and water-poor magnetite suggest that the global context of alteration may be better understood if local water concentrations are compared with millimeter-scale distribution of the various morphologies of magnetite. Finally, the high water content in the magnetite precursor gel indicates that the initial O isotopic composition in alteration water must not have been very different from that of the earliest magnetite crystals.

AB - In order to gain insights on the conditions of aqueous alteration on asteroid Ryugu and the origin of water in the outer solar system, we developed the measurement of water content in magnetite at the micrometer scale by secondary ion mass spectrometry (NanoSIMS) and determined the H and Si content of coarse-grained euhedral magnetite grains (polyhedral magnetite) and coarse-grained fibrous (spherulitic) magnetite from the Ryugu polished section A0058-C1001. The hydrogen content in magnetite ranges between ~900 and ~3300 wt ppm equivalent water and is correlated with the Si content. Polyhedral magnetite has low and homogenous silicon and water content, whereas fibrous magnetite shows correlated Si and water excesses. These excesses can be explained by the presence of hydrous Si-rich amorphous nanoinclusions trapped during the precipitation of fibrous magnetite away from equilibrium and testify that fibrous magnetite formed from a hydrous gel with possibly more than 20 wt% water. An attempt to determine the water content in sub-μm framboids indicates that additional calibration and contamination issues must be addressed before a safe conclusion can be drawn, but hints at elevated water content as well. The high water content in fibrous magnetite, expected to be among the first minerals to crystallize at low water–rock ratio, points to the control of water content by local conditions of magnetite precipitation rather than large-scale alteration conditions. Systematic lithological variations associated with water-rich and water-poor magnetite suggest that the global context of alteration may be better understood if local water concentrations are compared with millimeter-scale distribution of the various morphologies of magnetite. Finally, the high water content in the magnetite precursor gel indicates that the initial O isotopic composition in alteration water must not have been very different from that of the earliest magnetite crystals.

U2 - 10.1111/maps.14139

DO - 10.1111/maps.14139

M3 - Journal article

AN - SCOPUS:85183638891

JO - Meteoritics and Planetary Science

JF - Meteoritics and Planetary Science

SN - 1086-9379

ER -

ID: 383707680

Globe Institute