Red palaeosols development in response to the enhanced east asia summer monsoon since the mid-pleistocene in South China: Evidence derived from magnetic properties and molecular fossil records

Yansheng Gu; Xianyu Huang; Weiguo Zhang; Hanlie Hong; Yongtao Li

doi:10.1007/s12583-013-0331-4

Journal of Earth Science ›› 2013, Vol. 24 ›› Issue (3) : 382 -396. DOI: 10.1007/s12583-013-0331-4

Article

Red palaeosols development in response to the enhanced east asia summer monsoon since the mid-pleistocene in South China: Evidence derived from magnetic properties and molecular fossil records

Yansheng Gu ¹^,²^,^a
, Xianyu Huang ³^,⁴
, Weiguo Zhang ⁵
, Hanlie Hong ¹^,⁴
, Yongtao Li ⁶

Author information +

History +

PDF

Abstract

Although Pleistocene red paleosols are widely distributed in South China, paleoenvironmental interpretation has proved difficult because of intense weathering. Here we combine data from molecular fossil and magnetic properties to reconstruct a record of changes in pedogenic intensity for red paleosols in Southeast China. Depth distribution pattern of magnetic properties indicates that lower (higher) χ but higher (lower) values of HIRM (hard isothermal remanent magnetization) and SIRM (saturation isothermal remanent magnetization)/χ has tight relationship with the intensity of pedogenesis, especially the occurrence of well-developed net-like veins, which is absolutely responsible for the presence of anti-ferromagnetic minerals at the cost of fine-grained SP (superparamagnetic)/SD (single domain) ferrimagnetic minerals. The carbon distribution pattern of n-alkanes, n-alkanols, and n-alkanoic acids reflects the predominant contributions of microorganisms to the organic matter during pedogenesis, which provide direct evidence for strong microbial activities in response to the extremely hot-humid condition while white coarse net-like veins occurrence. Our results demonstrate that the presence of the enhanced East Asia summer monsoon has played a key role in the oxide-dominated weathering regime, and pedogenesis, and microbial activities. Changes in molecular ratios and magnetic properties are used to show that red paleosols have undergone three stages of soil formation in striking response to the evolution of the East Asia summer monsoon: (1) the most effective since the Middle Pleistocene; (2) moderately effective since 270 ka or so; (3) least effective since the last glacial. Our research provides important evidence to understand how red paleosols espond to global change since the Middle Pleistocene.

Keywords

red paleosols / magnetic property / molecular fossil / pedogenic intensity / East Asia summer monsoon / South China

Cite this article

Download citation ▾

Yansheng Gu, Xianyu Huang, Weiguo Zhang, Hanlie Hong, Yongtao Li. Red palaeosols development in response to the enhanced east asia summer monsoon since the mid-pleistocene in South China: Evidence derived from magnetic properties and molecular fossil records. Journal of Earth Science, 2013, 24(3): 382-396 DOI:10.1007/s12583-013-0331-4

登录浏览全文

4963

注册一个新账户忘记密码

References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	An Z S, Kukla G, Porter S C, . Magnetic Susceptibility Evidence of Monsoon Variation on the Loess Plateau of Central China during the Last 130 000 Years. Quaternary Research, 1991, 36: 29-36.

[2]	An Z S. The History and Variability of the East Asian Paleomonsoon Climate. Quaternary Science Reviews, 2000, 19: 171-187.

[3]	An Z S, Kutzbach J E, Prell W, . Evolution of Asian Monsoons and Phased Uplift of the Himalaya-Tibetan Plateau since Late Miocene Times. Nature, 2001, 411: 62-66.

[4]	Ao H, Deng C L, Dekkers M J, . Magnetic Mineral Dissolution in Pleistocene Fluvio-Lacustrine Sediments, Nihewan Basin (North China). Earth and Planetary Science Letters, 2010, 292: 191-200.

[5]	Banerjee S K, King J, Marvin J. A Rapid Method for Magnetic Granulometry with Applications to Environmental Studies. Geophysical Research Letters, 1981, 8: 333-336.

[6]	Bloemendal J, Liu X M. Rock Magnetism and Geochemistry of Two Plio-Pleistocene Chinese Loess-Palaeosol Sequences—Implications for Quantitative Palaeoprecipitation Reconstruction. Palaeogeography, Palaeoclimatology, Palaeoecology, 2005, 226: 149-166.

[7]	Cranwell P A. Chain-Length Distribution of n-Alkanes from Lake Sediments in Relation to Post-Glacial Environmental Change. Freshwater Biology, 1973, 3: 259-265.

[8]	Cranwell P A, Eglinton G, Robinson N. Lipids of Aquatic Organisms as Potential Contributors to Lacustrine Sediments. Organic Geochemistry, 1987, 11: 513-527.

[9]	Eglinton G, Hamilton R J. Leaf Epicuticular Waxes. Science, 1967, 156: 1322-1335.

[10]	Fang Y S, Yang D Y, Han H Y, . Taphonomic Study of Plaeolithic Site Group of Shuiyang River. Acta Anthropologica Sinica, 1992, 11: 134-142.

[11]	Gong Z T. Red Soils in China, 1983 Beijing: Science Press

[12]	Gu Y S, Li C A, Zhang Z J. Analysis of Phytolith for the Quaternary Environment Reconstruction. Geological Science and Technology Information, 1997, 16: 55-58.

[13]	Guo Z T, Biscaye P, Wei L Y, . Summer Monsoon Variations over the Last 1.2 Ma from the Weathering of Loess-Soil Sequences in China. Geophysical Research Letters, 2000, 27: 1751-1754.

[14]	Guo Z T, Berger A, Yin Q Z, . Strong Asymmetry of Hemispheric Climates during MIS-13 Inferred from Correlating China Loess and Antarctica Ice Records. Climate of the Past, 2009, 5: 21-31.

[15]	Hong H L, Gu Y S, Li R B, . Clay Mineralogy and Geochemistry and Their Palaeoclimatic Interpretation of the Pleistocene Deposits in the Xuancheng Section, Southern China. Journal of Quaternary Science, 2010, 25: 662-674.

[16]	Hou Y M, Pottes R, Yuan B Y, . Mid-Pleistocene Acheulean-like Stone Technology of the Bose Basin, Southeast China. Science, 2000, 287: 1622-1626.

[17]	Hu X F, Cheng T F, Wu H X. Do Multiple Cycles of Eolian Deposit-Pedogenesis Exist in the Reticulate Red Clay Sections in Southern China?. Chinese Science Bulletin, 2003, 48: 1251-1258.

[18]	Hu X F, Zhu Y, Shen M N. Size Analysis, Evidence for Multiple Origin of the Reticulate Red Clay in Southern China. Chinese Science Bulletin, 2005, 50: 918-925.

[19]	Huang J N, Fang J H, Shao J J, . Study on the Sediment Age of the Xiashu Loess of the Nanjing. Review of Geology, 1988, 3: 240-247.

[20]	Huang Y S, Lockheart M, Collister J W, . Molecular and Isotopic Biogeochemistry of the Miocene Clarkia Formation, Hydrocarbons and Alcohols. Organic Geochemistry, 1995, 23: 785-801.

[21]	Huang Y S, Street-Perrott F A, Perrott F A, . Glacial-Interglacial Environmental Changes Inferred from the Molecular and Compound-Specific δ¹³C Analyses of Sediments from Sacred Lake, Mt Kenya. Geochimica et Cosmochimica Acta, 1999, 63: 1383-1404.

[22]	Huang Z G, Zhang W Q, Chen J H, . The Red Weathering Crust in Southern China, 1996 Beijing: Ocean Press

[23]	Huang Z G, Zhang W Q, Chen J H. The Change of Natural Zones and the Evolution of Red Earth in China. Acta Geographica Sinica, 1999, 54: 203-211.

[24]	Huang Z G, Zhang W Q. Coupling Relationship between the Red Earth Evolution, Climate Change and Tectonic Movement in China. Acta Geographica Sinica, 2000, 55: 200-208.

[25]	Li C A, Gu Y S. Stratigraphic Study on the Vermicular Red Earth at Xiushui County in Jiangxi Province. Journal of Stratigraphy, 1997, 21: 226-232.

[26]	Li X Y, Gu Y S, Huang X Y, . An Optimized Alkaline Hydrolysis Method to Extract Lipid Biomarkers from Pleistocene Vermicular Red Paleosols: An Example from Xuancheng, Anhui Province. Earth Science—Journal of China University of Geosciences, 2009, 34(4): 623-628.

[27]	Liang B, Xie S C, Gu Y S, . Distribution of n-Alkanes as of Indicative of Paleovegetation Change in Pleistocene Red Earth in Xuancheng, Anhui. Earth Science—Journal of China University of Geosciences, 2005, 30(2): 129-132.

[28]	Liu C C, Deng C L, Liu Q S, . Mineral Magnetism to Probe into the Nature of Palaeomagnetic Signals of Subtropical Red Soil Sequences in Southern China. Geophysical Journal International, 2010, 181: 1395-1410.

[29]	Liu L W, Gong Z T. Characteristics of Development of Quaternary Red Clay in Xuancheng, Anhui Province. Quaternary Sciences, 2000, 20: 464-468.

[30]	Liu Q S, Deng C L, Torrent J, . Review of Recent Developments in Mineral Magnetism of the Chinese Loess. Quaternary Science Reviews, 2007, 26: 368-385.

[31]	Liu T S. Loess and the Environment, 1985 Beijing: Science Press

[32]	Liu X M, Hesse P, Rolph T. Origin of Maghemite in Chinese Loess Deposits, Aeolian or Pedogenic?. Physics of the Earth and Planetary Interiors, 1999, 112: 191-201.

[33]	Lu S G, Dong R B, Yu J Y, . Magnetic Measurement Characterization of Red Earth Profile in Eastern China and Its Environmental Implications. Chinese Journal of Geophysics, 1999, 42: 764-771.

[34]	Lu S G. Environmental Magnetism of Quaternary Red Paleosols in Southern China. Quaternary Sciences, 2007, 27: 1016-1022.

[35]	Maher B A. Magnetic Properties of Some Synthetic Submicron Magnetites. Geophysical Journal, 1988, 94: 83-96.

[36]	Meyers A, Ishiwatari R. Lacustrine Organic Geochemistry—An Overview of Indicators of Organic Matter Sources and Diagenesis in Lake Sediments. Organic Geochemistry, 1993, 20: 867-900.

[37]	Meyers P A. Application of Organic Geochemistry to Paleolimnological Reconstructions: A Summary of Examples from the Laurentian Great Lakes. Organic Geochemistry, 2003, 34: 261-289.

[38]	Qiao Y S, Guo Z T, Hao Q Z, . Study on Magnetostratigraph of Aeolian Products Soil Sequence and Its Implication of Paleoenvironment in the Southern Anhui Province. Chinese Science Bulletin, 2003, 48: 1465-1469.

[39]	Teilhard de Chardin P, Yong C C, Pei W Z. On the Cenozoic Formations of Kwangsi and Kwangtung. Bulle tin of the Geological Society of China, 1935, 14: 179-205.

[40]	Thompson R, Oldfield F. Environmental Magnetism, 1986 London: Allen and Unwin

[41]	Volkman J K, Barrett S M, Blackburn S I. Eustigmatophyte Microalgae are Potential Sources of C₂₉ Sterrol, nC₂₃-nC₂₈ n-Alkanols and C₂₈-C₃₂ n-Alkyldiols in Freshwater Environment. Organic Geochemistry, 1999, 30: 307-318.

[42]	Wang W M, Yu Z Y, Yang H. A Study on Phytoliths and Palynomorphs of Quanternary Red Paleosols in Xingzi County, Jiangxi Province and Its Significance. Acta Micropalaeontologica Sinica, 1997, 14: 41-48.

[43]	Xi C F. Studying on the Red Weathering Crusts of Southern China. Quaternary Sciences, 1991, 1-7.

[44]	Xie S C, Chen F H, Wang Z Y, . Lipid Distributions in Loess-Paleosol Sequences in Northwest China. Organic Geochemistry, 2003, 34: 1071-1079.

[45]	Xie S C, Lai X L, Yi Y, . Molecular Fossils in a Pleistocene River Terrace in Southern China Related to Paleoclimate Variation. Organic Geochemistry, 2003, 34: 789-797.

[46]	Xie S C, Guo J Q, Huang J H, . Restricted Utility of δ13C of Bulk Organic Matter as a Record of Paleovegetation in Some Loess-Paleosol Sequences in the Chinese Loess Plateau. Quaternary Research, 2004, 62: 86-93.

[47]	Xiong Y. Study on Quaternary Climate Based on Colloid Minerals in Pleistocene Sediments. Acta Geologica Sinica, 1952, 32: 26-41.

[48]	Xiong S F, Ding Z L, Liu T S. The Comparison of Particle Characteristics among Laterite in Northern Jiangxi Province, Loess near Beijing and Sand of Desert. Chinese Science Bulletin, 1999, 44: 1216-1219.

[49]	Xiong S F, Sun D H, Ding Z L. Aeolian Origin of the Red Earth in Southeast China. Journal of Quaternary Science, 2002, 17: 181-191.

[50]	Yang X Q, Zhu Z Y, Zhang Y N, . Rock Magnetic Properties and Palaeomagnetic Results of Sediments from a Stone Implement Layer in the Bose Basin, Guangxi. Science in China Series D: Earth Sciences, 2008, 51: 441-450.

[51]	Yin Q Z, Guo Z T. Mid-Pleistocene Vermiculated Red Soils in Southern China as an Indication of Unusually Strengthened East Asian Monsoon. Chinese Science Bulletin, 2006, 51: 213-220.

[52]	Yin Q Z, Guo Z T. Strong Summer Monsoon during the Cool MIS-13. Climate of the Past, 2008, 4: 29-34.

[53]	Yuan B Y, Xia Z K, Li B S, . Chronostratigraphy and Stratigraphic Division of Red Soil in Southern China. Quaternary Sciences, 2008, 24: 160-166.

[54]	Zhao Q G, Yang H. A Preliminary Study on Red Earth and Changes of Quaternary Environment in Southeast China. Quaternary Sciences, 1995, 2: 107-116.

[55]	Zhang W G, Yu L Z, Lu M, . Magnetic Properties and Geochemistry of the Xiashu Loess in the Present Subtropical Area of China, and Their Implications for Pedogenic Intensity. Earth and Planetary Science Letters, 2007, 260: 86-97.

[56]	Zheng L P, Hu X F, Fang X M. A Review of the Study on the Origin of Xiashu Loess in the Middle and Lower Reaches of Yangtze River. Bulletin of Mineralogy, Petrology and Geochemistry, 2002, 21: 54-57.