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Magnetic Enhancement and Iron Oxides in the Upper Luochuan Loess–Paleosol Sequence, Chinese Loess Plateau

Magnetic Enhancement and Iron Oxides in the Upper Luochuan Loess–Paleosol Sequence, Chinese Loess Plateau
Magnetic Enhancement and Iron Oxides in the Upper Luochuan Loess–Paleosol Sequence, Chinese Loess Plateau
Variations in the low-field magnetic susceptibility of the wind-blown Chinese Loess Plateau (CLP) loess–paleosol sequences reflect changes in the global paleoclimate on different time scales. Magnetic enhancement in paleosols has been ascribed to the neoformation of fine-grained maghemite; however, little is known about the pathway through which this mineral was formed in the CLP paleosols, its relationships with the other pedogenic Fe oxides (viz. hematite and goethite), and the pedoclimatic significance of such relationships. In this work, we characterized various magnetic, chemical, and mineralogical properties of the loess–paleosol units at depths from about 23 to 55 m in the Upper Luochuan section, central CLP. The concentration of pedogenic hematite (Hm) and the frequency-dependent magnetic susceptibility (FD), which is used as a proxy for the concentration of fine-grained pedogenic maghemite, were found to be linearly correlated (R2 = 0.825, P < 0.001). This supports the idea that these two minerals were formed concomitantly during pedogenesis, which is consistent with the results of previous in vitro experiments showing that the ferrihydrite maghemite hematite transformation takes place under aerobic conditions. By contrast, the concentration of pedogenic goethite (Gt) was only weakly correlated with either FD or Hm, which suggests that goethite formed through an alternative pathway. The paleosols above 40 m (S4, S5, corresponding to marine isotope stages 9 and 11, respectively) exhibit a higher degree of weathering and higher Hm/(Hm + Gt) ratio than those below such a depth (S6–S8). This was ascribed to differences in paleoclimatic conditions, which are moister and warmer in the former paleosols than in the latter, rather than to differences in pedogenesis duration.
0361-5995
1570-1578
Torrent, J.
730f8893-1fec-4c12-a001-d2c8b642dd52
Liu, Q-S.
e94c4753-4337-4495-8812-9f5af2514dd4
Bloemendal, J.
5ae09dd4-c89b-47f8-a7e6-f3f1ed4c5ddb
Barron, V.
d80a09f8-4337-415e-9c15-183ec34d703b
Torrent, J.
730f8893-1fec-4c12-a001-d2c8b642dd52
Liu, Q-S.
e94c4753-4337-4495-8812-9f5af2514dd4
Bloemendal, J.
5ae09dd4-c89b-47f8-a7e6-f3f1ed4c5ddb
Barron, V.
d80a09f8-4337-415e-9c15-183ec34d703b

Torrent, J., Liu, Q-S., Bloemendal, J. and Barron, V. (2007) Magnetic Enhancement and Iron Oxides in the Upper Luochuan Loess–Paleosol Sequence, Chinese Loess Plateau. SSSAJ Soil Science Society of America Journal, 71 (5), 1570-1578. (doi:10.2136/sssaj2006.0328).

Record type: Article

Abstract

Variations in the low-field magnetic susceptibility of the wind-blown Chinese Loess Plateau (CLP) loess–paleosol sequences reflect changes in the global paleoclimate on different time scales. Magnetic enhancement in paleosols has been ascribed to the neoformation of fine-grained maghemite; however, little is known about the pathway through which this mineral was formed in the CLP paleosols, its relationships with the other pedogenic Fe oxides (viz. hematite and goethite), and the pedoclimatic significance of such relationships. In this work, we characterized various magnetic, chemical, and mineralogical properties of the loess–paleosol units at depths from about 23 to 55 m in the Upper Luochuan section, central CLP. The concentration of pedogenic hematite (Hm) and the frequency-dependent magnetic susceptibility (FD), which is used as a proxy for the concentration of fine-grained pedogenic maghemite, were found to be linearly correlated (R2 = 0.825, P < 0.001). This supports the idea that these two minerals were formed concomitantly during pedogenesis, which is consistent with the results of previous in vitro experiments showing that the ferrihydrite maghemite hematite transformation takes place under aerobic conditions. By contrast, the concentration of pedogenic goethite (Gt) was only weakly correlated with either FD or Hm, which suggests that goethite formed through an alternative pathway. The paleosols above 40 m (S4, S5, corresponding to marine isotope stages 9 and 11, respectively) exhibit a higher degree of weathering and higher Hm/(Hm + Gt) ratio than those below such a depth (S6–S8). This was ascribed to differences in paleoclimatic conditions, which are moister and warmer in the former paleosols than in the latter, rather than to differences in pedogenesis duration.

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Published date: September 2007

Identifiers

Local EPrints ID: 49886
URI: http://eprints.soton.ac.uk/id/eprint/49886
ISSN: 0361-5995
PURE UUID: 43963edd-6eaa-49bd-9ecb-e2b7d2d17c09

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Date deposited: 10 Dec 2007
Last modified: 15 Mar 2024 10:00

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Contributors

Author: J. Torrent
Author: Q-S. Liu
Author: J. Bloemendal
Author: V. Barron

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