Hostname: page-component-8448b6f56d-wq2xx Total loading time: 0 Render date: 2024-04-24T22:02:37.372Z Has data issue: false hasContentIssue false
  • English
  • Français

Controlling factors and the paleoenvironmental significance of chemical elements in Holocene calcareous root tubes in the Alashan Desert, Northwest China

Published online by Cambridge University Press:  10 October 2018

Youhong Gao ,
Zhuolun Li ,
Nai’ang Wang  and
Ruolan Li
Youhong Gao
Affiliation:
College of Earth and Environmental Sciences, Center for Glacier and Desert Research, Lanzhou University, Lanzhou 730000, China
Zhuolun Li*
Affiliation:
College of Earth and Environmental Sciences, Center for Glacier and Desert Research, Lanzhou University, Lanzhou 730000, China Shandong Provincial Key Laboratory of Depositional Mineralization and Sedimentary Mineral, Shandong University of Science and Technology, Qingdao 266590, China
Nai’ang Wang
Affiliation:
College of Earth and Environmental Sciences, Center for Glacier and Desert Research, Lanzhou University, Lanzhou 730000, China
Ruolan Li
Affiliation:
College of Earth and Environmental Sciences, Center for Glacier and Desert Research, Lanzhou University, Lanzhou 730000, China
*
*Corresponding author at: College of Earth and Environmental Sciences, Center for Glacier and Desert Research, Lanzhou University, Lanzhou 730000, China. E-mail address: lizhuolunlzl@163.com; zhll@lzu.edu.cn (Z. Li).
Get access Rights & Permissions [Opens in a new window]

Abstract

In the hinterland of the desert, valuable archives of paleoenvironmental evolution are scarce. Calcareous root tubes (CRTs) have a strong potential for reconstructing paleoenvironmental conditions. It is still unclear, however, whether chemical elements in the CRTs can provide insights into paleoenvironmental conditions. In this study, the major- and trace-element composition of 32 CRT samples from the Alashan Desert were analyzed by X-ray fluorescence spectrometry. Results showed that the elemental composition and content change were controlled by the parent material and climatic conditions at the time of CRT formation. Ca, Mg, and Sr were significantly affected by climate, whereas the enrichment of P is likely related to the growth of plants. Higher (lower) Mg/Ca and Sr/Ca ratios corresponded to higher (lower) effective moisture and a higher (lower) Mg/Sr ratio indicated a higher (lower) temperature during the middle Holocene (8–5 cal ka BP). The reconstruction results for effective moisture were consistent with those in the Asian monsoon margin of northwestern China, which were caused by higher monsoon precipitation and lower evaporation. Therefore, chemical elements in the CRTs can reflect changes in paleo-effective moisture and paleotemperature at a millennial resolution in this area.

Keywords

RhizolithsSecondary carbonatePaleoenvironmentHoloceneSand seaArid region
Type
Research Article
Information
Quaternary Research , Volume 91 , Issue 1 , January 2019 , pp. 149 - 162
Copyright
Copyright © University of Washington. Published by Cambridge University Press, 2018. 

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

REFERENCES

Alonso-Zarza, A.M., Genise, J.F., Cabrera, M.C., Mangas, J., Martín-Pérez, A., Valdeolmillos, A., Dorado-Valiño, M., 2008. Megarhizoliths in Pleistocene aeolian deposits from Gran Canaria (Spain): ichnological and palaeoenvironmental significance. Palaeogeography, Palaeoclimatology, Palaeoecology 265, 3951.Google Scholar
An, Z., Porter, S.C., Kutzbach, J.E., Wu, X., Wang, S., Liu, X., Li, X., Zhou, W., 2000. Asynchronous Holocene optimum of the East Asian monsoon. Quaternary Science Reviews 19, 743762.Google Scholar
Braconnot, P., Harrison, S.P., Kageyama, M., Bartlein, P.J., Masson-Delmotte, V., Abe-Ouchi, A., Otto-Bliesner, B., Zhao, Y., 2012. Evaluation of climate models using palaeoclimatic data. Nature Climate Change 2, 417424.Google Scholar
Buggle, B., Glaser, B., Hambach, U., Gerasimenko, N., Marković, S., 2011. An evaluation of geochemical weathering indices in loess–paleosol studies. Quaternary International 240, 1221.Google Scholar
Burton, E.A., Walter, L.M., 1991. The effects of P CO 2 and temperature on magnesium incorporation in calcite in seawater and MgCl 2 -CaCl 2 solutions. Geochimica Et Cosmochimica Acta 55, 777785.Google Scholar
Cai, H.W., 1987. A tentative discussion on new tectonic movements in hexi corridor Gansu. [In Chinese with English abstract.] Gansu Geology 6, 98105.Google Scholar
Carroll, D., 1953. Weatherability of Zircon. Journal of Sedimentary Research 23, 106116.Google Scholar
Chang, H., An, Z., Wu, F., Jin, Z., Liu, W., Song, Y., 2013. A Rb/Sr record of the weathering response to environmental changes in westerly winds across the Tarim Basin in the late Miocene to the early Pleistocene. Palaeogeography, Palaeoclimatology, Palaeoecology 386, 364373.Google Scholar
Chen, F., Li, G., Zhao, H., Jin, M., Chen, X., Fan, Y., Liu, X., Wu, D., Madsen, D., 2014. Landscape evolution of the Ulan Buh Desert in northern China during the late Quaternary. Quaternary Research 81, 476487.Google Scholar
Chen, F., Yu, Z., Yang, M., Ito, E., Wang, S., Madsen, D.B., Huang, X., Zhao, Y., Sato, T., Birks, H.J.B., 2008. Holocene moisture evolution in arid central Asia and its out-of-phase relationship with Asian monsoon history. Quaternary Science Reviews 27, 351364.Google Scholar
Chen, J., Ji, J., Qiu, G., Lu, H., 1998. Geochemical studies on the intensity of chemical weathering in Luochuan loess-paleosol sequence, China. Science China Earth Sciences 41, 235241.Google Scholar
Cramer, M.D., Hawkins, H.J., 2009. A physiological mechanism for the formation of root casts. Palaeogeography, Palaeoclimatology, Palaeoecology 274, 125133.Google Scholar
Cruz, F.W.C. Jr, Burns, S.J., Jercinovic, M., Karmann, I., Sharp, W.D., Vuille, M., 2007. Evidence of rainfall variations in Southern Brazil from trace element ratios (Mg/Ca and Sr/Ca) in a Late Pleistocene stalagmite. Geochimica et Cosmochimica Acta 71, 22502263.Google Scholar
Day, C.C., Henderson, G.M., 2013. Controls on trace-element partitioning in cave-analogue calcite. Geochimica et Cosmochimica Acta 120, 612627.Google Scholar
Elderfield, H., Bertram, C.J., Erez, J., 1996. A biomineralization model for the incorporation of trace elements into foraminiferal calcium carbonate. Earth and Planetary Science Letters 142, 409423.Google Scholar
Fang, X., Hou, G., 2011. Synthetically Reconstructed Holocene Temperature Change in China. [In Chinese with English abstract.] Scientia Geographica Sinica 31, 385393.Google Scholar
Gallant, C.E., Candy, I., van den Bogaard, P., Silva, B.N., Turner, E., 2014. Stable isotopic evidence for Middle Pleistocene environmental change from a loess-paleosol sequence: Kärlich, Germany. Boreas 43, 818833.Google Scholar
Gallet, S., Jahn, B.M., Torii, M., 1996. Geochemical characterization of the Luochuan loess-paleosol sequence, China, and paleoclimatic implications. Chemical Geology 133, 6788.Google Scholar
Gascoyne, M., 1983. Trace-element partition coefficients in the calcite-water system and their paleoclimatic significance in cave studies. Journal of Hydrology 61, 213222.Google Scholar
Gerke, J., 1994. Kinetics of soil phosphate desorption as affected by citric acid. Journal of Plant Nutrition and Soil Science 157, 1722.Google Scholar
Gocke, M., Hambach, U., Eckmeier, E., Schwark, L., Zöller, L., Fuchs, M., Löscher, M., Wiesenberg, G.L.B., 2014. Introducing an improved multi-proxy approach for paleoenvironmental reconstruction of loess–paleosol archives applied on the Late Pleistocene Nussloch sequence (SW Germany). Palaeogeography, Palaeoclimatology, Palaeoecology 410, 300315.Google Scholar
Gocke, M., Pustovoytov, K., Kühn, P., Wiesenberg, G.L.B., Löscher, M., Kuzyakov, Y., 2011a. Carbonate rhizoliths in loess and their implications for paleoenvironmental reconstruction revealed by isotopic composition: δ13C, 14C. Chemical Geology 283, 251260.Google Scholar
Gocke, M., Pustovoytov, K., Kuzyakov, Y., 2011b. Carbonate recrystallization in root-free soil and rhizosphere of Triticum aestivum and Lolium perenne estimated by C-14 labeling. Biogeochemistry 103, 209222.Google Scholar
Hasiuk, F.J., Lohmann, K.C., 2010. Application of calcite Mg partitioning functions to the reconstruction of paleocean Mg/Ca. Geochimica et Cosmochimica Acta 74, 67516763.Google Scholar
Hearty, P.J., O’Leary, M.J., 2008. Carbonate eolianites, quartz sands, and Quaternary sea-level cycles, Western Australia: a chronostratigraphic approach. Quatemary Geochronology 3, 2655.Google Scholar
Herzschuh, U., 2006. Palaeo-moisture evolution in monsoonal Central Asia during the last 50,000 years. Quaternary Science Reviews 25, 163178.Google Scholar
Hodson, M.E., 2002. Experimental evidence for mobility of Zr and other trace elements in soils. Geochimica et Cosmochimica Acta 66, 819828.Google Scholar
Huang, Y., Fairchild, I.J., 2001. Partitioning of Sr2+ and Mg2+ into calcite under karst-analogue experimental conditions. Geochimica et Cosmochimica Acta 65, 4762.Google Scholar
Huang, Y.M., Fairchild, I.J., Borsato, A., Frisia, S., Cassidy, N.J., Mcdermott, F., Hawkesworth, C.J., 2001. Seasonal variations in Sr, Mg and P in modern speleothems (Grotta di Ernesto, Italy). Chemical Geology 175, 429448.Google Scholar
Huguet, A., Wiesenberg, G.L.B., Gocke, M., Fosse, C., Derenne, S., 2012. Branched tetraether membrane lipids associated with rhizoliths in loess: Rhizomicrobial overprinting of initial biomarker record. Organic Geochemistry 43, 1219.Google Scholar
Jin, Z., Cao, J., Wu, J., Wang, S., 2006. A Rb/Sr record of catchment weathering response to Holocene climate change in Inner Mongolia. Earth Surface Processes and Landforms 31, 285291.Google Scholar
Karmann, I., Cruz, F.W.C. Jr, Viana, O. Jr., Burns, S.J., 2007. Climate influence on geochemistry parameters of waters from Santana–Pérolas cave system, Brazil. Chemical Geology 244, 232247.Google Scholar
Klappa, C.F., 1980. Rhizoliths in terrestrial carbonates: classification, recognition, genesis and significance. Sedimentology 27, 613629.Google Scholar
Kraus, M.J., Hasiotis, S.T., 2006. Significance of different modes of rhizolith preservation to interpreting paleoenvironmental and paleohydrologic settings: examples from paleogene paleosols, Bighorn Basin, Wyoming, U.S.A. Journal of Sedimentary Research 76, 633646.Google Scholar
Kutzbach, J.E., Guetter, P.J., 1986. The Influence of Changing Orbital Parameters and Surface Boundary Conditions on Climate Simulations for the Past 18,000 Years. Journal of Atmospheric Sciences 43, 17261759.Google Scholar
Kuzyakov, Y., Shevtzova, E., Pustovoytov, K., 2006. Carbonate re-crystallization in soil revealed by C-14 labeling: experiment, model and significance for paleo-environmental reconstructions. Geoderma 131, 4558.Google Scholar
Li, E.J., 2011. A Comparative Study of Sediments Characteristics Between the Badain Jaran Desert and Tengger Desert. [In Chinese with English abstract.] Shanxi Normal University.Google Scholar
Li, R., Li, Z., Ning, K., Wang, N., Cheng, H., Gao, Y., 2016a. Holocene millennial-scale effective moisture changes revealed by Sr/Ca ratios from calcareous root tubes in the Tengger Desert. [In Chinese with English abstract.] Quaternary Sciences 36, 379387.Google Scholar
Li, X., Jie, Z., Ji, S., Weng, C., Zhao, H., Sun, Q., 2004. Vegetation history and climatic variations during the last 14 ka BP inferred from a pollen record at Daihai Lake, north-central China. Review of Palaeobotany and Palynology 132, 195205.Google Scholar
Li, Y., Morrill, C., 2010. Multiple factors causing Holocene lake-level change in monsoonal and arid central Asia as identified by model experiments. Climate Dynamics 35, 1115–1128.Google Scholar
Li, Y., Wang, N.A., Li, Z., Zhou, X., Zhang, C., 2013. Climatic and environmental change in Yanchi Lake, Northwest China since the Late Glacial: a comprehensive analysis of lake sediments. Journal of Geographical Sciences 23, 932946.Google Scholar
Li, Y., Wang, N.A., Li, Z.L., Zhang, H.A., 2011. Holocene palynological records and their responses to the controversies of climate system in the Shiyang River drainage basin. Science Bulletin 56, 535546.Google Scholar
Li, Z., Gao, Y., Han, L., 2017. Holocene vegetation signals in the Alashan Desert of northwest China revealed by lipid molecular proxies from calcareous root tubes. Quaternary Research 88, 6070.Google Scholar
Li, Z., Pan, N., He, Y., Zhang, Q., 2016b. Evaluating the best evaporation estimate model for free water surface evaporation in hyper-arid regions: a case study in the Ejina basin, northwest China. Environmental Earth Sciences 75, 295.Google Scholar
Li, Z., Wang, N., Cheng, H., Li, Y., 2016c. Early–middle Holocene hydroclimate changes in the Asian monsoon margin of northwest China inferred from Huahai terminal lake records. Journal of Paleolimnology 55, 114.Google Scholar
Li, Z., Wang, N., Cheng, H., Ning, K., Zhao, L., Li, R., 2015a. Formation and environmental significance of Late Quaternary calcareous root tubes in the deserts of the Alashan Plateau, Northwest China. Quaternary International 372, 167174.Google Scholar
Li, Z., Wang, N., Li, R., Ning, K., Cheng, H., Zhao, L., 2015b. Indication of millennial-scale moisture changes by the temporal distribution of Holocene calcareous root tubes in the deserts of the Alashan Plateau, Northwest China. Palaeogeography, Palaeoclimatology, Palaeoecology 440, 496505.Google Scholar
Liu, B., Jin, H., Sun, L., Sun, Z., Niu, Q., Xie, S., Li, G., 2014. Holocene moisture change revealed by the Rb/Sr ratio of aeolian deposits in the southeastern Mu Us Desert, China. Aeolian Research 13, 109119.Google Scholar
Liutkus, C.M., 2009. Using petrography and geochemistry to determine the origin and formation mechanism of calcitic plant molds: rhizolith or tufa? Journal of Sedimentary Research 79, 906917.Google Scholar
Long, H., Lai, Z.P., Fuchs, M., Zhang, J.R., Yu, L., 2012. Timing of Late Quaternary palaeolake evolution in Tengger Desert of northern China and its possible forcing mechanisms. Global and Planetary Change 92–93, 119129.Google Scholar
Long, H., Lai, Z.P., Wang, N.A., Li, Y., 2010. Holocene climate variations from Zhuyeze terminal lake records in East Asian monsoon margin in arid northern China. Quaternary Research 74, 4656.Google Scholar
Ma, Y., 1989. The Flora of Inner Mongolia. Inner-Mongol People Publishing House, Hohhot.Google Scholar
Martínez-Botí, M.A., Foster, G.L., Chalk, T.B., Rohling, E.J., Sexton, P.F., Lunt, D.J., Pancost, R.D., Badger, M.P.S., Schmidt, D.N., 2015. Plio-Pleistocene climate sensitivity evaluated using high-resolution CO2 records. Nature 518, 49.Google Scholar
McDonald, J., Drysdale, R., Hill, D., 2004. The 2002–2003 El Niño recorded in Australian cave drip waters: implications for reconstructing rainfall histories using stalagmites. Geophysical Research Letters 312, L22202. http://dx.doi.org/10.1029/2004GL020859.Google Scholar
Morse, J.W., Bender, M.L., 1990. Partition coefficients in calcite: examination of factors influencing the validity of experimental results and their application to natural systems. Chemical Geology 82, 265277.Google Scholar
Mulvaney, R., Abram, N.J., Hindmarsh, R.C.A., Arrowsmith, C., Fleet, L., Triest, J., Sime, L.C., Alemany, O., Foord, S., 2012. Recent Antarctic Peninsula warming relative to Holocene climate and ice-shelf history. Nature 489, 141U204.Google Scholar
Nottebaum, V., Lehmkuhl, F., Stauch, G., Lu, H., Yi, S., 2015. Late Quaternary aeolian sand deposition sustained by fluvial reworking and sediment supply in the Hexi Corridor — an example from northern Chinese drylands. Geomorphology 250, 113127.Google Scholar
Pustovoytov, K., Schmidt, K., Parzinger, H., 2007. Radiocarbon dating of thin pedogenic carbonate laminae from Holocene archaeological sites. Holocene 17, 835843.Google Scholar
Qiao, Y., Hao, Q., Peng, S., Wang, Y., Li, J., Liu, Z., 2011. Geochemical characteristics of the eolian deposits in southern China, and their implications for provenance and weathering intensity. Palaeogeography, Palaeoclimatology, Palaeoecology 308, 513523.Google Scholar
Ren, X., Yang, X., Wang, Z., Zhu, B., Zhang, D., Rioual, P., 2014. Geochemical evidence of the sources of aeolian sands and their transport pathways in the Minqin Oasis, northwestern China. Quaternary International 334–335, 165178.Google Scholar
Tang, J., Köhler, S.J., Dietzel, M., 2008. Sr 2+ /Ca 2+ and 44 Ca/ 40 Ca fractionation during inorganic calcite formation: I. Sr incorporation. Geochimica et Cosmochimica Acta 72, 37183732.Google Scholar
Újvári, G., Varga, A., Balogh-Brunstad, Z., 2008. Origin, weathering, and geochemical composition of loess in southwestern Hungary. Quaternary Research 69, 421437.Google Scholar
Wang, H., Liu, L., Feng, Z., 2008. Spatiotemporal variations of Zr/Rb ratio in three last interglacial paleosol profiles across the Chinese Loess Plateau and its implications for climatic interpretation. [In Chinese with English abstract.] Chinese Science Bulletin 53, 238246.Google Scholar
Wang, M., Dong, Z., Lu, J., Li, J., Luo, W., Cui, X., Zhang, Y., Liu, Z., Jiao, Y. 2015. Vegetation characteristics and species diversity around the Badain Jaran Desert. [In Chinese with English abstract.] Journal of Desert Research 35, 12261233.Google Scholar
Wang, N., Li, Z., Cheng, H., Li, Y., Huang, Y., 2011. High lake levels on Alxa Plateau during the Late Quaternary. Chinese Science Bulletin 56, 17991808.Google Scholar
Wang, N., Li, Z., Li, Y., Cheng, H., 2013. Millennial-scale environmental changes in the Asian monsoon margin during the Holocene, implicated by the lake evolution of Huahai Lake in the Hexi Corridor of northwest China. Quaternary International 313–314, 100109.Google Scholar
Wang, N., Li, Z., Li, Y., Cheng, H., Huang, R., 2012. Younger Dryas event recorded by the mirabilite deposition in Huahai lake, Hexi Corridor, NW China. Quaternary International 250, 9399.Google Scholar
Wang, P., Wang, Z.G., 1997. Division of the Alxa block and its attribution. [In Chinese with English abstract.] Earthquake 17, 103112.Google Scholar
Wang, Y., Cao, J., Zhang, X., Shen, Z., Mei, F., 2004. Carbonate content and carbon and oxygen isotopic composition of surface soil in the dust source regions of china. [In Chinese with English abstract.] Marine Geology and Quaternary . Geology 24, 113117.Google Scholar
Wang, Y.J., Cheng, H., Edwards, R.L., An, Z.S., Wu, J.Y., Shen, C.-C., Dorale, J.A., 2001. A high-resolution absolute-dated late Pleistocene monsoon record from Hulu Cave, China. Science 294, 23452348.Google Scholar
Wen, R., Xiao, J., Chang, Z., Zhai, D., 2011. Holocene precipitation and temperature variations in the East Asian monsoonal margin from pollen data from Hulun Lake in northeastern Inner Mongolia,China. Boreas 39, 262272.Google Scholar
Xiong, S., Ding, Z., Zhu, Y., Zhou, R., Lu, H., 2010. A ∼6 Ma chemical weathering history, the grain size dependence of chemical weathering intensity, and its implications for provenance change of the Chinese loess–red clay deposit. Quaternary Science Reviews 29, 19111922.Google Scholar
Yan, M.C., Wang, G.Q., Li, B.S., Dong, G.R., 2001. Formation and Growth of High Megadunes in Badain Jaran Desert. [In Chinese with English abstract.] Acta Geographica Sinica 56, 8391.Google Scholar
Yang, X., Ma, N., Dong, J., Zhu, B., Xu, B., Ma, Z., Liu, J., 2010. Recharge to the inter-dune lakes and Holocene climatic changes in the Badain Jaran Desert, western China. Quaternary Research 73, 1019.Google Scholar
Yang, X.P., 2000. Landscape evolution and precipitation changes in the Badain Jaran Desert during the last 30 000 years. Chinese Science Bulletin 45, 10421047.Google Scholar
Yang, X.P., Scuderi, L., Paillou, P., Liu, Z.T., Li, H.W., Ren, X.Z., 2011. Quaternary environmental changes in the drylands of China - aA critical review. Quaternary Science Reviews 30, 32193233.Google Scholar
Yang, X.P., Scuderi, L.A., 2010. Hydrological and climatic changes in deserts of China since the late Pleistocene. Quaternary Research 73, 19.Google Scholar
Yang, Y., Li, B.S., Li, Y.Z., Liu, Y.F., Ouyang, C.T., Wen, X.H., Ou, X.J., Zeng, L.H., 2007. Palaeo-Climate Change Indicated from Fluctuations of Trace Elements since 150 ka BP in Chagelebu Stratigraphical Section, Badain Jaran Desert. [In Chinese with English abstract.] Journal of Desert Research 27, 18.Google Scholar
Zamanian, K., Pustovoytov, K., Kuzyakov, Y., 2016. Pedogenic carbonates: forms and formation processes. Earth-Science Reviews 157, 117.Google Scholar
Zhang, H.C., Ma, Y., Wünnemann, B., Pachur, H.J., 2000. A Holocene climatic record from arid northwestern China. Palaeogeography, Palaeoclimatology, Palaeoecology 162, 389401.Google Scholar
Zhang, H.C., Ming, Q., Lei, G., Zhang, W., Fan, H., Chang, F., Wünnemann, B., Hartmann, K., 2006. Dilemma of dating on lacustrine deposits in an hyperarid inland basin of NW China. Radiocarbon 48, 219226.Google Scholar
Zhang, J., Ma, X., Qiang, M., Huang, X., Li, S., Guo, X., Henderson, A.C.G., Holmes, J.A., Chen, F., 2016. Developing inorganic carbon-based radiocarbon chronologies for Holocene lake sediments in arid NW China. Quaternary Science Reviews 144, 6682.Google Scholar
Zhao, H., Li, G., Sheng, Y., Jin, M., Chen, F., 2012. Early–middle Holocene lake-desert evolution in northern Ulan Buh Desert, China. Palaeogeography, Palaeoclimatology, Palaeoecology 331–332, 3138.Google Scholar
Zhao, Y., Yu, Z.C., 2012. Vegetation response to Holocene climate change in East Asian monsoon-margin region. Earth-Science Reviews 113, 110.Google Scholar
Zheng, H., 2007. General Geochemistry. Peking University Press.Google Scholar
Zhu, B., Yang, X., Rioual, P., Liu, Z., Li, C., Xiong, H., 2011. Composition of soluble salts in aeolian sands from sandy deserts of northern china and their environmental implications. [In Chinese with English abstract.] Quaternary . Sciences 31, 10291044.Google Scholar
Zhu, J.F., Wang, N.A., Chen, H.B., Dong, C.Y., Zhang, H.A., 2010. Study on the boundary and the area of Badain Jaran Desert based on the remote sensing imagery. [In Chinese with English abstract.] Progress in . Geography 29, 10871094.Google Scholar
Zhu, Z.D., Wu, Z., Liu, S., 1980. An Outline of Chinese Desert. [In Chinese.] Science Press, Beijing.Google Scholar
Supplementary material: File

Gao et al. supplementary material

Table S1

Download Gao et al. supplementary material(File)
File 14.7 KB
Supplementary material: File

Gao et al. supplementary material

Table S2

Download Gao et al. supplementary material(File)
File 30 KB