黏土矿物-微生物相互作用机理以及在环境领域中的应用

董海良, 曾强, 刘邓, 盛益之, 刘晓磊, 刘源, 胡景龙, 李扬, 夏庆银, 李润洁, 胡大福, 张冬磊, 张文慧, 郭东毅, 张晓文

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地学前缘 ›› 2024, Vol. 31 ›› Issue (1) : 467-485. DOI: 10.13745/j.esf.sf.2024.1.19
环境变化与生物圈层相互作用

黏土矿物-微生物相互作用机理以及在环境领域中的应用

作者信息 +

Interactions between clay minerals and microbes: Mechanisms and applications in environmental remediation

Author information +
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摘要

黏土矿物与微生物在自然环境中广泛共存。二者之间的相互作用影响着环境中的能量流动与元素循环。黏土矿物能够给微生物提供物理或化学保护,提高微生物对外界胁迫和干扰的抵抗能力。黏土矿物同时还能给微生物提供营养元素,促进其新陈代谢过程。黏土矿物中的结构铁是微生物铁氧化还原循环的重要电子供/受体。在氧化还原的环境中,多种铁还原/铁氧化细菌可以通过还原氧化黏土矿物中的结构Fe(III)/Fe(II),进而获得能量进行生长。在氧化还原过程中,微生物也可以通过溶解、转化、沉淀等作用改变黏土矿物的晶格结构及物相,或是产生新的次生矿物。黏土矿物-微生物相互作用在碳、氮、硅、磷等重要生命元素的地球化学循环中扮演着重要角色。黏土矿物可以通过吸附有机碳,降低有机碳的生物可利用性,减缓其矿化速率。在氧化还原波动的环境中,黏土矿物还可以通过活化分子氧,产生强氧化性自由基氧化降解有机质,提高其生物可利用性。黏土矿物还会吸附生物胞外酶,影响胞外酶降解有机质的效率。微生物通过耦合黏土矿物中铁氧化与硝酸盐还原,铁还原与氨氧化等过程影响氮循环。黏土矿物对磷的吸附以及风化过程中硅的释放影响着微生物的代谢活性。黏土矿物-微生物相互作用在重金属固化稳定、有机污染物降解、杀死病原菌等方面也有广泛的应用。

Abstract

Clay minerals and microbes co-exist in natural environments, and their interaction can influence energy flow and element cycling. Clay minerals provide microbes with physical/chemical protection against environmental stress, as well as nutrients boosting their metabolism. Structural iron in clay mineral is an important electron acceptor/donor for iron-reducing/oxidizing microbes, where in redox environment many iron-reducing/oxidizing bacteria can reduce/oxidize structural Fe(III)/Fe(II) in clay minerals as they gain energy from the redox process. During such process redox microbes can alter the atomic structure of clay minerals through dissolution, transformation and precipitation where secondary minerals are also produced. Clay mineral-microbe interaction plays important role in geochemical cycling of carbon, nitrogen, silicon and phosphorus. Clay mineral can reduce organic carbon bioavailability and mineralization rate through adsorption; whereas under fluctuating redox conditions it can activate molecular oxygen to produce reactive oxygen species to degrade organic matters thus increasing their bioavailability. Through adsorption clay mineral can also reduce extracellular enzyme activity in organic matter degradation. Microbes can affect nitrogen cycling in clays by coupling iron oxidation (reduction) with nitrate reduction (ammonia oxidation) in clay. Phosphorus adsorption on clays and silicon release during weathering can affect the metabolic activity of microbes. Clay mineral-microbe interaction can find a wide range of application in heavy metal stabilization, organic pollutant degradation and sterilization.

关键词

黏土矿物 / 微生物 / 相互作用 / 元素循环 / 能量 / 电子传递 / 氧化还原 / 环境治理

Key words

clay mineral / microbe / interaction / element cycling / energy / electron transfer / redox / environmental remediation

中图分类号

P57;P593;X172

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EndNote

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导出引用
董海良 , 曾强 , 刘邓 , . 黏土矿物-微生物相互作用机理以及在环境领域中的应用. 地学前缘. 2024, 31(1): 467-485 https://doi.org/10.13745/j.esf.sf.2024.1.19
Hailiang DONG, Qiang ZENG, Deng LIU, et al. Interactions between clay minerals and microbes: Mechanisms and applications in environmental remediation[J]. Earth Science Frontiers. 2024, 31(1): 467-485 https://doi.org/10.13745/j.esf.sf.2024.1.19

参考文献

列表( 原文顺序 | 文献年度倒序 | 文中引用次数倒序 ) 可视化分析
[1]
CUADROS J. Clay minerals interaction with microorganisms: a review[J]. Clay Minerals, 2017, 52: 235-261.
本文引用 [7]
[2]
DONG H, HUANG L, ZHAO L, et al. A critical review of mineral-microbe interaction and co-evolution: mechanisms and applications[J]. National Science Review, 2022, 9(10): nwac128.
本文引用 [5]
[3]
王茂桢, 柳少波, 任拥军, 等. 页岩气储层黏土矿物孔隙特征及其甲烷吸附作用[J]. 地质论评, 2015, 61(1): 207-216.
本文引用 [2]
[4]
UROZ S, KELLY L C, TURPAULT M P, et al. The mineralosphere concept: mineralogical control of the distribution and function of mineral-associated bacterial communities[J]. Trends in Microbiology, 2015, 23: 751-762.
本文引用 [2]
[5]
BELNAP J. The world at your feet: desert biological soil crusts[J]. Frontiers in Ecology and the Environment, 2003, 1(5): 181-189.
本文引用 [1]
[6]
郭东毅, 夏庆银, 董海良, 等. 杀菌黏土矿物的研究进展与前景展望[J]. 地学前缘, 2022, 29(1): 470-485.
本文引用 [4]
[7]
徐建明. 土壤学[M]. 北京: 中国农业出版社, 2019.
本文引用 [2]
[8]
XU S, XING Y, LIU S, et al. Co-effect of minerals and Cd(ii) promoted the formation of bacterial biofilm and consequently enhanced the sorption of Cd(ii)[J]. Environmental Pollution, 2020, 258: 113774.
本文引用 [2]
[9]
FREEBAIRN D, LINTON D, HARKINJONES E, et al. Electrical methods of controlling bacterial adhesion and biofilm on device surfaces[J]. Expert Review of Medical Devices, 2013, 10(1): 85-103.
本文引用 [1]
[10]
FOMINA M, BURFORD E P, GADD G M. Toxic metals and fungal communities[M]. Boca Raton: CRC Press, 2005.
本文引用 [1]
[11]
JOHNSTON C T. Probing the nanoscale architecture of clay minerals[J]. Clay Minerals, 2010, 45(3): 245-279.
本文引用 [1]
[12]
ALIMOVA A, KATZ A, STEINER N, et al. Bacteria-clay interaction: structural changes in smectite induced during biofilm formation[J]. Clays and Clay Minerals, 2009, 57: 205-212.
本文引用 [1]
[13]
ZHANG D, LIU X, GUO D, et al. Cr(VI) reduction by siderophore alone and in combination with reduced clay minerals[J]. Environmental Science & Technology, 2022, 56(17): 12315-12324.
本文引用 [3]
[14]
XIA Q, JIN Q, CHEN Y, et al. Combined effects of Fe(III)-bearing nontronite and organic ligands on biogenic U(IV) oxidation[J]. Environmental science & Technology, 2022, 56(3): 1983-1993.
本文引用 [1]
[15]
DA FONSECA M G, DE OLIVERIA M M, ARAKAKI L N H, et al. Natural vermiculite as an exchanger support for heavy cations in aqueous solution[J]. Journal of Colloid and Interface Science, 2005, 285: 50-55.
本文引用 [1]
[16]
BISHOP M E, GLASSER P, DONG H, et al. Reduction and immobilization of hexavalent chromium by microbially reduced Fe-bearing clay minerals[J]. Geochimica et Cosmochimica Acta, 2014, 133: 186-203.
本文引用 [1]
[17]
HUANG L, LIU Z, DONG H, et al. Coupling quinoline degradation with Fe redox in clay minerals: a strategy integrating biological and physicochemical processes[J]. Applied Clay Science, 2020, 188: 105504.
本文引用 [1]
[18]
DONG H. Clay-microbe interactions and implications for environmental mitigation[J]. Elements, 2012, 8: 113-118.
本文引用 [4]
[19]
OLSON J M, PIERSON B K. Photosynthesis 3.5 thousand million years ago[J]. Photosynthesis Research, 1986, 9(1): 251-259.
本文引用 [1]
[20]
KUGLER A, DONG H. Phyllosilicates as protective habitats of filamentous cyanobacteria leptolyngbya against ultraviolet radiation[J]. Plos One, 2019, 14: e0219616.
本文引用 [1]
[21]
HAZELTON P, MURPHY B. Interpreting soil test results: what do all the numbers mean?[M]. Clayton South VIC 3169:CSIRO Publishing, 2016.
本文引用 [1]
[22]
STOTZKY G, REM L T. Influence of clay minerals on microorganisms: I. Montmorillonite and kaolinite on bacteria[J]. Canadian Journal of Microbiology, 1966, 12(3): 547-563.
本文引用 [2]
[23]
BROWN JR G E, FOSTER A L, OSTERGREN J D. Mineral surfaces and bioavailability of heavy metals: a molecular-scale perspective[J]. Proceedings of the National Academy of Sciences, 1999, 96: 3388-3395.
本文引用 [1]
[24]
DONG H, ZENG Q, SHENG Y, et al. Coupled iron cycling and organic matter transformation across redox interfaces[J]. Nature Reviews Earth & Environment, 2023, 4: 659-673.
本文引用 [7]
[25]
GADD G M. Metals, minerals and microbes: geomicrobiology and bioremediation[J]. Microbiology, 2010, 156: 609-643.
本文引用 [1]
[26]
ROGERS J R, BENNETT P C. Mineral stimulation of subsurface microorganisms: release of limiting nutrients from silicates[J]. Chemical Geology, 2004, 203(1/2): 91-108.
本文引用 [1]
[27]
SHI L, DONG H L, REGUERA G, et al. Extracellular electron transfer mechanisms between microorganisms and minerals[J]. Nature Reviews Microbiology, 2016, 14(10): 651-662.
本文引用 [2]
[28]
MOORE E K, JELEN B I, GIOVANNELLI D, et al. Metal availability and the expanding network of microbial metabolisms in the archaean eon[J]. Nature Geoscience, 2017, 10(9): 629-636.
本文引用 [1]
[29]
HU D, ZENG Q, LIU X, et al. Ligand enhanced bio-oxidation of structural Fe(II) in illite coupled with nitrate reduction[J]. Geochimica et Cosmochimica Acta, 2023, 357: 50-63.
本文引用 [3]
[30]
MURRAY H H. Traditional and new applications for kaolin, smectite, and palygorskite: a general overview[J]. Applied Clay Science, 2000, 17(5/6): 207-221.
本文引用 [1]
[31]
ZHANG D, ZHOU C H, LIN C X, et al. Synthesis of clay minerals[J]. Applied Clay Science, 2020, 50: 1-11.
本文引用 [1]
[32]
FOMINA M, GADD G M. Influence of clay minerals on the morphology of fungal pellets[J]. Mycological Research, 2002, 106: 107-117.
本文引用 [2]
[33]
DONG H, JAISI D P, KIM J, et al. Microbe-clay mineral interactions[J]. American Mineralogist, 2009, 94(11/12): 1505-1519.
本文引用 [5]
[34]
FOMINA M, SKOROCHOD I. Microbial interaction with clay minerals and its environmental and biotechnological implications[J]. Minerals, 2020, 10(10): 861.
本文引用 [4]
[35]
RANSOM B, BENNETT R H, BAERWALD R, et al. In situ conditions and interactions between microbes and minerals in fine-grained marine sediments: a TEM microfabric perspective[J]. American Mineralogist, 1999, 84(1/2): 183-192.
本文引用 [3]
[36]
JAISI D P, KUKKADAPU R K, EBERL D D, et al. Control of Fe(III) site occupancy on the rate and extent of microbial reduction of Fe(III) in nontronite[J]. Geochimica et Cosmochimica Acta, 2005, 69(23): 5429-5440.
本文引用 [3]
[37]
DONG H, LU A. Mineral-microbe interactions and implications for remediation[J]. Elements, 2012, 8(2): 95-100.
本文引用 [3]
[38]
VORHIES J S, GAINES R R. Microbial dissolution of clay minerals as a source of iron and silica in marine sediments[J]. Nature Geoscience, 2009, 2(3): 221-225.
本文引用 [2]
[39]
LIU D, DONG H, BISHOP M E, et al. Reduction of structural Fe(III) in nontronite by methanogen Methanosarcina barkeri[J]. Geochimica et Cosmochimica Acta, 2011, 75(4): 1057-1071.
本文引用 [4]
[40]
WEI J, HAO X, VAN LOOSDRECHT M C, et al. Feasibility analysis of anaerobic digestion of excess sludge enhanced by iron: a review[J]. Renewable and Sustainable Energy Reviews, 2018, 89: 16-26.
本文引用 [2]
[41]
XIAO B, LIAN B, SUN L, et al. Gene transcription response to weathering of K-bearing minerals by Aspergillus fumigatus[J]. Chemical Geology, 2012, 306: 1-9.
本文引用 [2]
[42]
MÜLLER B. Experimental interactions between clay minerals and bacteria: a review[J]. Pedosphere, 2015, 25(6): 799-810.
本文引用 [2]
[43]
MÜLLER B. Impact of the bacterium pseudomonas fluorescens and its genetic derivatives on vermiculite: effects on trace metals contents and clay mineralogical properties[J]. Geoderma, 2009, 153(1/2): 94-103.
本文引用 [2]
[44]
STUCKI J W. A review of the effects of iron redox cycles on smectite properties[J]. Comptes Rendus Geoscience, 2011, 343(2): 199-209.
本文引用 [2]
[45]
FAVRE F, STUCKI J W, BOIVIN P. Redox properties of structural Fe in ferruginous smectite. A discussion of the standard potential and its environmental implications[J]. Clays and Clay Minerals, 2006, 54(4): 466-472.
本文引用 [1]
[46]
KAPPLER A, BRYCE C, MANSOR M, et al. An evolving view on biogeochemical cycling of iron[J]. Nature Reviews Microbiology, 2021, 19(6): 360-374.
本文引用 [5]
[47]
LIU D, DONG H, ZHAO L, et al. Smectite reduction by Shewanella species as facilitated by cystine and cysteine[J]. Geomicrobiology Journal, 2014, 31(1): 53-63.
本文引用 [2]
[48]
YANG S, LIU D, ZHENG W, et al. Microbial reduction and alteration of Fe(III)-containing smectites in the presence of biochar-derived dissolved organic matter[J]. Applied Geochemistry, 2023, 152: 105661.
本文引用 [1]
[49]
ZHAO H, BHATTACHARJEE S, CHOW R, et al. Probing surface charge potentials of clay basal planes and edges by direct force measurements[J]. Langmuir, 2008, 24(22): 12899-12910.
本文引用 [1]
[50]
RIBEIRO F R, FABRIS J D, KOSTKA J E, et al. Comparisons of structural iron reduction in smectites by bacteria and dithionite: II. A variable-temperature Mössbauer spectroscopic study of Garfield nontronite[J]. Pure and Applied Chemistry, 2009, 81(8): 1499-1509.
本文引用 [1]
[51]
LUAN F, GORSKI C A, BURGOS W D. Thermodynamic controls on the microbial reduction of iron-bearing nontronite and uranium[J]. Environmental Science & Technology, 2014, 48(5): 2750-2758.
本文引用 [1]
[52]
ZUO H, HUANG L, CHU R K, et al. Reduction of structural Fe(III) in nontronite by humic substances in the absence and presence of Shewanella putrefaciens and accompanying secondary mineralization[J]. American Mineralogist, 2021, 106(12): 1957-1970.
本文引用 [4]
[53]
LIU Y, SHI S, ZENG Q, et al. Coupled reduction of structural Fe(III) in nontronite and oxidation of petroleum hydrocarbons[J]. Geochimica et Cosmochimica Acta, 2023, 344: 103-121.
本文引用 [1]
[54]
LI Y, VALI H, SEARS S K, et al. Iron reduction and alteration of nontronite NAu-2 by a sulfate-reducing bacterium[J]. Geochimica et Cosmochimica Acta, 2004, 68(15): 3251-3260.
本文引用 [2]
[55]
LIU D, DONG H, BISHOP M E, et al. Microbial reduction of structural iron in interstratified illite-smectite minerals by a sulfate-reducing bacterium[J]. Geobiology, 2012, 10(2): 150-162.
本文引用 [2]
[56]
ZHANG J, DONG H, LIU D, et al. Microbial reduction of Fe(III) in illite-smectite minerals by methanogen Methanosarcina mazei[J]. Chemical Geology, 2012, 292/293: 35-44.
本文引用 [1]
[57]
ZHANG J, DONG H, LIU D, et al. Microbial reduction of Fe(III) in smectite minerals by thermophilic methanogen Methanothermobacter thermautotrophicus[J]. Geochimica et Cosmochimica Acta, 2013, 106: 203-215.
本文引用 [1]
[58]
LIU D, DONG H, WANG H, et al. Low-temperature feldspar and illite formation through bioreduction of Fe(III)-bearing smectite by an alkaliphilic bacterium[J]. Chemical Geology, 2015, 406: 25-33.
本文引用 [4]
[59]
ZHAO L, DONG H, KUKKADAPU R, et al. Biological oxidation of Fe(II) in reduced nontronite coupled with nitrate reduction by Pseudogulbenkiania sp. Strain 2002[J]. Geochimica et Cosmochimica Acta, 2013, 119: 231-247.
本文引用 [5]
[60]
ZHAO L, DONG H, KUKKADAPU R K, et al. Biological redox cycling of iron in nontronite and its potential application in nitrate removal[J]. Environmental Science & Technology, 2015, 49(9): 5493-5501.
本文引用 [4]
[61]
ZHAO L, DONG H, EDELMANN R E, et al. Coupling of Fe(II) oxidation in illite with nitrate reduction and its role in clay mineral transformation[J]. Geochimica et Cosmochimica Acta, 2017, 200: 353-366.
本文引用 [4]
[62]
BRYCE C, BLACKWELL N, SCHMIDT C, et al. Microbial anaerobic Fe(II) oxidation-ecology, mechanisms and environmental implications[J]. Environmental Microbiology, 2018, 20(10): 3462-3483.
本文引用 [2]
[63]
BYRNE J M, KLUEGLEIN N, PEARCE C, et al. Redox cycling of Fe(II) and Fe(III) in magnetite by Fe-metabolizing bacteria[J]. Science, 2015, 347(6229): 1473-1476.
本文引用 [1]
[64]
DONG H, KOSTKA J E, KIM J. Microscopic evidence for microbial dissolution of smectite[J]. Clays and Clay Minerals, 2003, 51(5): 502-512.
本文引用 [2]
[65]
ZHANG G, KIM J, DONG H, et al. Microbial effects in promoting the smectite to illite reaction: role of organic matter intercalated in the interlayer[J]. American Mineralogist, 2007, 92(8/9): 1401-1410.
本文引用 [3]
[66]
DONG H, PEACOR D R, FREED R L. Phase relations among smectite, R1 illite-smectite, and illite[J]. American Mineralogist, 1997, 82(3/4): 379-391.
本文引用 [1]
[67]
PEVEAR D R. Illite and hydrocarbon exploration[J]. Proceedings of the National Academy of Sciences, 1999, 96(7): 3440-3446.
本文引用 [2]
[68]
KIM J, DONG H, SEABAUGH J, et al. Role of microbes in the smectite-to-illite reaction[J]. Science, 2004, 303(5659): 830-832.
本文引用 [1]
[69]
ZHANG G, DONG H, KIM J, et al. Microbial reduction of structural Fe3+ in nontronite by a thermophilic bacterium and its role in promoting the smectite to illite reaction[J]. American Mineralogist, 2007, 92(8/9): 1411-1419.
本文引用 [1]
[70]
KIM J, DONG H, YANG K, et al. Naturally occurring, microbially induced smectite-to-illite reaction[J]. Geology, 2019, 47(6): 535-539.
本文引用 [1]
[71]
LIU D, ZHANG Q, WU L, et al. Humic acid-enhanced illite and talc formation associated with microbial reduction of Fe(III) in nontronite[J]. Chemical Geology, 2016, 447: 199-207.
本文引用 [1]
[72]
KASTNER M, SIEVER R. Low temperature feldspars in sedimentary rocks[J]. American Journal of Science, 1979, 279: 435-479.
本文引用 [1]
[73]
RAIS P, LOUIS-SCHMID B, BERNASCONI S M, et al. Distribution of authigenic albites in a limestone succession of the Helvetic Domain, eastern Switzerland[J]. Swiss Journal of Geosciences, 2008, 101(1): 99-106.
本文引用 [1]
[74]
YANG X, LI Y, LI Y, et al. Microbially induced clay weathering: smectite-to-kaolinite transformation[J]. American Mineralogist, 2023, 108(10): 1940-1947.
本文引用 [1]
[75]
KEIL R G, TSAMAKIS E, FUH C B, et al. Mineralogical and textural controls on the organic composition of coastal marine sediments: hydrodynamic separation using splitt-fractionation[J]. Geochimica et Cosmochimica Acta, 1994, 58(2): 879-893.
本文引用 [1]
[76]
KEIL R G, MONTLUÇON D B, PRAHL F G, et al. Sorptive preservation of labile organic matter in marine sediments[J]. Nature, 1994, 370(6490): 549-552.
本文引用 [1]
[77]
KEIL R G, MAYER L M. 12.12 - mineral matrices and organic matter[M]//HOLLAND H D, TUREKIAN K K. Treatise on geochemistry. 2nd ed. Oxford: Elsevier, 2014: 337-359.
本文引用 [2]
[78]
KLEBER M, EUSTERHUES K, KEILUWEIT M, et al. Mineral-organic associations: formation, properties, and relevance in soil environments[J]. Advances in Agronomy, 2015, 130: 1-140.
本文引用 [1]
[79]
ZENG Q, DONG H, ZHAO L, et al. Preservation of organic matter in nontronite against iron redox cycling[J]. American Mineralogist, 2016, 101(1): 120-133.
本文引用 [1]
[80]
KENNEDY M J, PEVEAR D R, HILL R J. Mineral surface control of organic carbon in black shale[J]. Science, 2002, 295(5555): 657-660.
本文引用 [1]
[81]
KENNEDY M, DROSER M, MAYER L M, et al. Late Precambrian oxygenation: inception of the clay mineral factory[J]. Science, 2006, 311(5766): 1446-1449.
本文引用 [1]
[82]
CAI C, CAI J, LIU H, et al. Occurrence of organic matter in argillaceous sediments and rocks and its geological significance: a review[J]. Chemical Geology, 2023, 639: 121737.
本文引用 [1]
[83]
DUBINSKY E A, SILVER W L, FIRESTONE M K. Tropical forest soil microbial communities couple iron and carbon biogeochemistry[J]. Ecology, 2010, 91(9): 2604-2612.
本文引用 [1]
[84]
TAN J, LUO M, TAN F, et al. Iron reduction controls carbon mineralization in aquaculture shrimp pond sediments in subtropical estuaries[J]. Journal of Geophysical Research: Biogeosciences, 2022, 127(12): e2022JG007081.
本文引用 [1]
[85]
YUAN Y, DING C, WU H, et al. Dissimilatory iron reduction contributes to anaerobic mineralization of sediment in a shallow transboundary lake[J]. Fundamental Research, 2022, 3(6): 844-851.
本文引用 [1]
[86]
WARDMAN P. Reduction potentials of one-electron couples involving free radicals in aqueous solution[J]. Journal of Physical and Chemical Reference Data, 1989, 18(4): 1637-1755.
本文引用 [1]
[87]
VAN BODEGOM P M, BROEKMAN R, VAN DIJK J, et al. Ferrous iron stimulates phenol oxidase activity and organic matter decomposition in waterlogged wetlands[J]. Biogeochemistry, 2005, 76(1): 69-83.
本文引用 [3]
[88]
NAUGHTON H R, TOLAR B B, DEWEY C, et al. Reactive iron, not fungal community, drives organic carbon oxidation potential in floodplain soils[J]. Soil Biology and Biochemistry, 2023, 178: 108962.
本文引用 [1]
[89]
VAN ERK M R, BOURCEAU O M, MONCADA C, et al. Reactive oxygen species affect the potential for mineralization processes in permeable intertidal flats[J]. Nature Communications, 2023, 14(1): 938.
本文引用 [1]
[90]
CHEN N, FU Q, WU T, et al. Active iron phases regulate the abiotic transformation of organic carbon during redox fluctuation cycles of paddy soil[J]. Environmental Science & Technology, 2021, 55(20): 14281-14293.
本文引用 [1]
[91]
HALL S J, SILVER W L. Iron oxidation stimulates organic matter decomposition in humid tropical forest soils[J]. Global Change Biology, 2013, 19(9): 2804-2813.
本文引用 [1]
[92]
JONES M E, LACROIX R E, ZEIGLER J, et al. Enzymes, manganese, or iron? Drivers of oxidative organic matter decomposition in soils[J]. Environmental Science & Technology, 2020, 54(21): 14114-14123.
本文引用 [1]
[93]
ZENG Q, WANG X, LIU X, et al. Mutual interactions between reduced Fe-bearing clay minerals and humic acids under dark, oxygenated conditions: hydroxyl radical generation and humic acid transformation[J]. Environmental Science & Technology, 2020, 54(23): 15013-15023.
本文引用 [1]
[94]
HU D, ZENG Q, ZHU J, et al. Promotion of humic acid transformation by abiotic and biotic Fe redox cycling in nontronite[J]. Environmental Science & Technology, 2023, 57(48): 19760-19771.
本文引用 [1]
[95]
ZIMMERMAN A R, AHN M Y. Organo-mineral-enzyme interaction and soil enzyme activity[M]. Soil Enzymology: Springer, 2010: 271-292.
本文引用 [2]
[96]
ALLISON S D. Cheaters, diffusion and nutrients constrain decomposition by microbial enzymes in spatially structured environments[J]. Ecology Letters, 2005, 8(6): 626-635.
本文引用 [1]
[97]
SINSABAUGH R L. Phenol oxidase, peroxidase and organic matter dynamics of soil[J]. Soil Biology and Biochemistry, 2010, 42(3): 391-404.
本文引用 [1]
[98]
BURNS R G, DEFOREST J L, MARXSEN J, et al. Soil enzymes in a changing environment: current knowledge and future directions[J]. Soil Biology & Biochemistry, 2013, 58: 216-234.
本文引用 [1]
[99]
LUO L, MENG H, GU J D. Microbial extracellular enzymes in biogeochemical cycling of ecosystems[J]. Journal of Environmental Management, 2017, 197: 539-549.
本文引用 [1]
[100]
LAMMIRATO C, MILTNER A, WICK L Y, et al. Hydrolysis of cellobiose by beta-glucosidase in the presence of soil minerals - interactions at solid-liquid interfaces and effects on enzyme activity levels[J]. Soil Biology & Biochemistry, 2010, 42(12): 2203-2210.
本文引用 [1]
[101]
KLEBER M, BOURG I C, COWARD E K, et al. Dynamic interactions at the mineral-organic matter interface[J]. Nature Reviews Earth & Environment, 2021, 2(6): 402-421.
本文引用 [1]
[102]
SCHIMEL J, BECERRA C A, BLANKINSHIP J. Estimating decay dynamics for enzyme activities in soils from different ecosystems[J]. Soil Biology Biochemistry, 2017, 114: 5-11.
本文引用 [1]
[103]
SHENG Y, DONG H, COFFIN E, et al. The important role of enzyme adsorbing capacity of soil minerals in regulating β-glucosidase activity[J]. Geophysical Research Letters, 2022, 49(6): e2021GL097556.
本文引用 [5]
[104]
FREEMAN C, OSTLE N, KANG H. An enzymic ‘latch’ on a global carbon store[J]. Nature, 2001, 409(6817): 149-149.
本文引用 [1]
[105]
WANG Y, WANG H, HE J S, et al. Iron-mediated soil carbon response to water-table decline in an alpine wetland[J]. Nature Communications, 2017, 8(1): 15972.
本文引用 [1]
[106]
MERINO C, MATUS F, KUZYAKOV Y, et al. Contribution of the fenton reaction and ligninolytic enzymes to soil organic matter mineralisation under anoxic conditions[J]. Science of The Total Environment, 2021, 760: 143397.
本文引用 [2]
[107]
ZHAO Y, XIANG W, HUANG C, et al. Production of hydroxyl radicals following water-level drawdown in peatlands: a new induction mechanism for enhancing laccase activity in carbon cycling[J]. Soil Biology and Biochemistry, 2021, 156: 108241.
本文引用 [1]
[108]
SHENG Y, HU J, KUKKADAPU R, et al. Inhibition of extracellular enzyme activity by reactive oxygen species upon oxygenation of reduced iron-bearing minerals[J]. Environmental Science & Technology, 2023, 57(8): 3425-3433.
本文引用 [5]
[109]
WANG C, BLAGODATSKAYA E, DIPPOLD M A, et al. Keep oxygen in check: contrasting effects of short-term aeration on hydrolytic versus oxidative enzymes in paddy soils[J]. Soil Biology and Biochemistry, 2022, 169: 108690.
本文引用 [1]
[110]
EGLI C M, STRAVS M A, JANSSEN E M L. Inactivation and site-specific oxidation of aquatic extracellular bacterial leucine aminopeptidase by singlet oxygen[J]. Environmental Science & Technology, 2020, 54(22): 14403-14412.
本文引用 [1]
[111]
GARWOOD G, MORTLAND M, PINNAVAIA T. Immobilization of glucose oxidase on montmorillonite clay: hydrophobic and ionic modes of binding[J]. Journal of Molecular Catalysis, 1983, 22(2): 153-163.
本文引用 [1]
[112]
SEREFOGLOU E, LITINA K, GOURNIS D, et al. Smectite clays as solid supports for immobilization of beta-glucosidase: synthesis, characterization, and biochemical properties[J]. Chemistry of Materials, 2008, 20(12): 4106-4115.
本文引用 [1]
[113]
GOPINATH S, SUGUNAN S. Enzymes immobilized on montmorillonite K 10: effect of adsorption and grafting on the surface properties and the enzyme activity[J]. Applied Clay Science, 2007, 35(1/2): 67-75.
本文引用 [1]
[114]
YANG Z M, LIAO Y J, FU X, et al. Temperature sensitivity of mineral-enzyme interactions on the hydrolysis of cellobiose and indican by beta-glucosidase[J]. Science of The Total Environment, 2019, 686: 1194-1201.
本文引用 [1]
[115]
TEN HAVE R, TEUNISSEN P J. Oxidative mechanisms involved in lignin degradation by white-rot fungi[J]. Chemical Reviews, 2001, 101(11): 3397-3414.
本文引用 [1]
[116]
GUILLÉN F, GÓMEZ-TORIBIO V, JESÚS MARTI NEZ M, et al. Production of hydroxyl radical by the synergistic action of fungal laccase and aryl alcohol oxidase[J]. Archives of Biochemistry and Biophysics, 2000, 383(1): 142-147.
本文引用 [1]
[117]
PERNA V, MEYER A S, HOLCK J, et al. Laccase-catalyzed oxidation of lignin induces production of H2O2[J]. ACS Sustainable Chemistry & Engineering, 2019, 8(2): 831-841.
本文引用 [1]
[118]
DASHTBAN M, SCHRAFT H, SYED T A, et al. Fungal biodegradation and enzymatic modification of lignin[J]. International Journal of Biochemistry and Molecular Biology, 2010, 1(1): 36.
本文引用 [1]
[119]
WEI D, HOUTMAN C J, KAPICH A N, et al. Laccase and its role in production of extracellular reactive oxygen species during wood decay by the brown rot basidiomycete Postia placenta[J]. Applied and Environmental Microbiology, 2010, 76(7): 2091-2097.
本文引用 [1]
[120]
ZHAO S, JIN Q, SHENG Y, et al. Promotion of microbial oxidation of structural Fe(II) in nontronite by oxalate and NTA[J]. Environmental Science & Technology, 2020, 54(20): 13026-13035.
本文引用 [2]
[121]
SHELOBOLINA E S, VANPRAAGH C G, LOVLEY D R. Use of ferric and ferrous iron containing minerals for respiration by Desulfitobacterium frappieri[J]. Geomicrobiology Journal, 2003, 20(2): 143-156.
本文引用 [2]
[122]
SHELOBOLINA E, KONISHI H, XU H, et al. Isolation of phyllosilicate-iron redox cycling microorganisms from an illite-smectite rich hydromorphic soil[J]. Frontiers in Microbiology, 2012, 3: 134.
本文引用 [3]
[123]
YANG J, KUKKADAPU R K, DONG H, et al. Effects of redox cycling of iron in nontronite on reduction of technetium[J]. Chemical Geology, 2012, 291: 206-216.
本文引用 [1]
[124]
SAWAYAMA S. Possibility of anoxic ferric ammonium oxidation[J]. Journal of Bioscience and Bioengineering, 2006, 101(1): 70-72.
本文引用 [1]
[125]
CLÉMENT J C, SHRESTHA J, EHRENFELD J G, et al. Ammonium oxidation coupled to dissimilatory reduction of iron under anaerobic conditions in wetland soils[J]. Soil Biology and Biochemistry, 2005, 37(12): 2323-2328.
本文引用 [1]
[126]
LI X, HOU L, LIU M, et al. Evidence of nitrogen loss from anaerobic ammonium oxidation coupled with ferric iron reduction in an intertidal wetland[J]. Environmental Science & Technology, 2015, 49(19): 11560-11568.
本文引用 [1]
[127]
DING L J, AN X L, LI S, et al. Nitrogen loss through anaerobic ammonium oxidation coupled to iron reduction from paddy soils in a chronosequence[J]. Environmental Science & Technology, 2014, 48(18): 10641-10647.
本文引用 [1]
[128]
ZHOU G W, YANG X R, LI H, et al. Electron shuttles enhance anaerobic ammonium oxidation coupled to iron (III) reduction[J]. Environmental Science & Technology, 2016, 50(17): 9298-9307.
本文引用 [1]
[129]
KIRIAZIS N A. Evidence for iron-dependent anaerobic ammonium oxidation to nitrate (feammox) in deep-sea sediments[D]. Atlanta: Georgia Institute of Technology, 2015.
本文引用 [1]
[130]
罗珺月, 冯杰, 罗阳, 等. 微生物厌氧氨氧化耦合铁还原的研究进展及展望[J]. 微生物学报, 2023, 63(6): 2031-2046.
本文引用 [1]
[131]
YANG W H, WEBER K A, SILVER W L. Nitrogen loss from soil through anaerobic ammonium oxidation coupled to iron reduction[J]. Nature Geoscience, 2012, 5(8): 538-541.
本文引用 [1]
[132]
GILSON E R, HUANG S, JAFFÉ P R. Biological reduction of uranium coupled with oxidation of ammonium by Acidimicrobiaceae bacterium A6 under iron reducing conditions[J]. Biodegradation, 2015, 26: 475-482.
本文引用 [1]
[133]
RUIZ-URIGÜEN M, JAFFE P R. Microbial anaerobic ammonium oxidation under iron reducing conditions, alternative electron acceptors[C]// Proceedings of the AGU Fall Meeting Abstracts. Washington: American Geophysical Union, 2015: BBC-0639.
本文引用 [1]
[134]
马晓田, 常保璇, 黄柳琴, 等. Shewanella putrefaciens CN32 对黏土附着态铵氮释放的影响[J]. 微生物学报, 2020, 60(6): 1192-1205.
本文引用 [2]
[135]
FAN T, WANG M, WANG X, et al. Experimental study of the adsorption of nitrogen and phosphorus by natural clay minerals[J]. Adsorption Science & Technology, 2021, Volume 2021: 1-14. article ID 4158151.
本文引用 [1]
[136]
HANWAY J J, SCOTT A, STANFORD G. Replaceability of ammonium fixed in clay minerals as influenced by ammonium or potassium in the extracting solution[J]. Soil Science Society of America Journal, 1957, 21(1): 29-34.
本文引用 [1]
[137]
SCHERER H, FEILS E, BEUTERS P. Ammonium fixation and release by clay minerals as influenced by potassium[J]. Plant, Soil and Environment, 2014, 60(7): 325-331.
本文引用 [1]
[138]
YIN H, YUN Y, ZHANG Y, et al. Phosphate removal from wastewaters by a naturally occurring, calcium-rich sepiolite[J]. Journal of Hazardous Materials, 2011, 198: 362-369.
本文引用 [1]
[139]
FANG H, CUI Z, HE G, et al. Phosphorus adsorption onto clay minerals and iron oxide with consideration of heterogeneous particle morphology[J]. Science of The Total Environment, 2017, 605/606: 357-367.
本文引用 [1]
[140]
PERASSI I, BORGNINO L. Adsorption and surface precipitation of phosphate onto CaCO3-montmorillonite: effect of pH, ionic strength and competition with humic acid[J]. Geoderma, 2014, 232/234: 600-608.
本文引用 [1]
[141]
GEELHOED J S, VAN RIEMSDIJK W H, FINDENEGG G R. Simulation of the effect of citrate exudation from roots on the plant availability of phosphate adsorbed on goethite[J]. European Journal of Soil Science, 1999, 50(3): 379-390.
本文引用 [1]
[142]
HINSINGER P. Bioavailability of soil inorganic P in the rhizosphere as affected by root-induced chemical changes: a review[J]. Plant and Soil, 2001, 237(2): 173-195.
本文引用 [2]
[143]
BINNER I, DULTZ S, SCHENK M K A. Phosphorus buffering capacity of substrate clays and its significance for plant cultivation[J]. Journal of Plant Nutrition and Soil Science, 2015, 178: 155-164.
本文引用 [1]
[144]
ZHANG L, HU Y, HAN F, et al. Influences of multiple clay minerals on the phosphorus transport driven by Aspergillus niger[J]. Applied Clay Science, 2019, 177: 12-18.
本文引用 [2]
[145]
TAZAKI K. Microbial formation of a halloysite-like mineral[J]. Clays and Clay Minerals, 2005, 53(3): 224-233.
本文引用 [1]
[146]
YANG X, LI Y, LU A, et al. Effect of bacillus Mucilaginosus D4B1 on the structure and soil-conservation-related properties of montmorillonite[J]. Applied Clay Science, 2016, 119: 141-145.
本文引用 [1]
[147]
POORNI S, NATARAJAN K A. Microbially induced selective flocculation of hematite from kaolinite[J]. International Journal of Mineral Processing, 2013, 125: 92-100.
本文引用 [1]
[148]
SONG X, QIU G, WANG H, et al. Bio-desilication of rutile concentrate and analysis of community structure in bio-desilication reactor[J]. Transactions of Nonferrous Metals Society of China, 2015, 25(7): 2398-2406.
本文引用 [1]
[149]
HUANG J, JONES A, WAITE T D, et al. Fe(II) redox chemistry in the environment[J]. Chemical Reviews, 2021, 121(13): 8161-8233.
本文引用 [2]
[150]
QU C, CHEN W, HU X, et al. Heavy metal behaviour at mineral-organo interfaces: Mechanisms, modelling and influence factors[J]. Environment International, 2019, 131: 104995.
本文引用 [2]
[151]
刘洵, 赖潘民旺, 张敏, 等. 微生物-矿物相互作用: 机制与重金属固定效应[J]. 环境化学, 2024, 43(2): 1-16.
本文引用 [1]
[152]
FANG L, CAI P, LI P, et al. Microcalorimetric and potentiometric titration studies on the adsorption of copper by P. putida and B. thuringiensis and their composites with minerals[J]. Journal of Hazardous Materials, 2010, 181(1/2/3): 1031-1038.
本文引用 [1]
[153]
LIU X, DONG H, YANG X, et al. Effects of citrate on hexavalent chromium reduction by structural Fe(II) in nontronite[J]. Journal of Hazardous Materials, 2018, 343: 245-254.
本文引用 [1]
[154]
LIU X, DONG H, ZENG Q, et al. Synergistic effects of reduced nontronite and organic ligands on Cr(VI) reduction[J]. Environmental Science & Technology, 2019, 53(23): 13732-13741.
本文引用 [2]
[155]
DENG L, LIU F, DING Z, et al. Effect of natural organic matter on Cr(VI) reduction by reduced nontronite[J]. Chemical Geology, 2023, 615: 121198.
本文引用 [1]
[156]
ZHANG L, CHEN Y, XIA Q, et al. Combined effects of Fe(III)-bearing clay minerals and organic ligands on U(VI) bioreduction and U(IV) speciation[J]. Environmental Science & Technology, 2021, 55(9): 5929-5938.
本文引用 [1]
[157]
CERVINI-SILVA J, LARSON R A, WU J, et al. Transformation of chlorinated aliphatic compounds by ferruginous smectite[J]. Environmental Science & Technology, 2001, 35(4): 805-809.
本文引用 [1]
[158]
CERVINI-SILVA J, LARSON R A, WU J, et al. Dechlorination of pentachloroethane by commercial Fe and ferruginous smectite[J]. Chemosphere, 2002, 47(9): 971-976.
本文引用 [1]
[159]
LEE W, BATCHELOR B. Abiotic reductive dechlorination of chlorinated ethylenes by iron-bearing phyllosilicates[J]. Chemosphere, 2004, 56(10): 999-1009.
本文引用 [1]
[160]
ENTWISTLE J, LATTA D E, SCHERER M M, et al. Abiotic degradation of chlorinated solvents by clay minerals and Fe(II): evidence for reactive mineral intermediates[J]. Environmental Science & Technology, 2019, 53(24): 14308-14318.
本文引用 [1]
[161]
HOFSTETTER T B, NEUMANN A, SCHWARZENBACH R P. Reduction of nitroaromatic compounds by Fe(II) species associated with iron-rich smectites[J]. Environmental Science & Technology, 2006, 40(1): 235-242.
本文引用 [1]
[162]
LUAN F, GORSKI C A, BURGOS W D. Linear free energy relationships for the biotic and abiotic reduction of nitroaromatic compounds[J]. Environmental Science & Technology, 2015, 49(6): 3557-3565.
本文引用 [1]
[163]
HOFSTETTER T B, SCHWARZENBACH R P, HADERLEIN S B. Reactivity of Fe(II) species associated with clay minerals[J]. Environmental Science & Technology, 2003, 37(3): 519-528.
本文引用 [1]
[164]
ROTHWELL K A, PENTRAK M P, PENTRAK L A, et al. Reduction pathway-dependent formation of reactive Fe(II) sites in clay minerals[J]. Environmental Science & Technology, 2023, 57(28): 10231-10241.
本文引用 [1]
[165]
TONG M, YUAN S, MA S, et al. Production of abundant hydroxyl radicals from oxygenation of subsurface sediments[J]. Environmental Science & Technology, 2016, 50(1): 214-221.
本文引用 [1]
[166]
LIU X, YUAN S, TONG M, et al. Oxidation of trichloroethylene by the hydroxyl radicals produced from oxygenation of reduced nontronite[J]. Water Research, 2017, 113: 72-79.
本文引用 [1]
[167]
ZENG Q, DONG H, WANG X, et al. Degradation of 1, 4-dioxane by hydroxyl radicals produced from clay minerals[J]. Journal of Hazardous Materials, 2017, 331: 88-98.
本文引用 [2]
[168]
ZHOU Z, ZENG Q, LI G, et al. Oxidative degradation of commingled trichloroethylene and 1, 4-dioxane by hydroxyl radicals produced upon oxygenation of a reduced clay mineral[J]. Chemosphere, 2022, 290: 133265.
本文引用 [1]
[169]
ZHOU Z, YU T, DONG H, et al. Chemical oxygen demand (COD) removal from bio-treated coking wastewater by hydroxyl radicals produced from a reduced clay mineral[J]. Applied Clay Science, 2019, 180: 105199.
本文引用 [1]
[170]
SEKAR R, DICHRISTINA T J. Microbially driven fenton reaction for degradation of the widespread environmental contaminant 1,4-dioxane[J]. Environmental Science & Technology, 2014, 48(21): 12858-12867.
本文引用 [2]
[171]
HAN R, LV J, HUANG Z, et al. Pathway for the production of hydroxyl radicals during the microbially mediated redox transformation of iron (oxyhydr)oxides[J]. Environmental Science & Technology, 2020, 54(2): 902-910.
本文引用 [1]
[172]
ZENG Q, DONG H, WANG X. Effect of ligands on the production of oxidants from oxygenation of reduced Fe-bearing clay mineral nontronite[J]. Geochimica et Cosmochimica Acta, 2019, 251: 136-156.
本文引用 [2]
[173]
CARRETERO M, GOMES C, TATEO F. Clays and human health[J]. Developments in Clay Science, 2006, 1: 717-741.
本文引用 [1]
[174]
AWAD M E, LÓPEZ-GALINDO A, SETTI M, et al. Kaolinite in pharmaceutics and biomedicine[J]. International Journal of Pharmaceutics, 2017, 533(1): 34-48.
本文引用 [1]
[175]
FINKELMAN R B. The influence of clays on human health: a medical geology perspective[J]. Clays and Clay Minerals, 2019, 67(1): 1-6.
本文引用 [1]
[176]
VISERAS C, CARAZO E, BORREGO-SÁNCHEZ A, et al. Clay minerals in skin drug delivery[J]. Clays and Clay Minerals, 2019, 67(1): 59-71.
本文引用 [1]
[177]
HAYDEL S E, REMENIH C M, WILLIAMS L B. Broad-spectrum in vitro antibacterial activities of clay minerals against antibiotic-susceptible and antibiotic-resistant bacterial pathogens[J]. Journal of Antimicrobial Chemotherapy, 2008, 61(2): 353.
本文引用 [1]
[178]
OTTO C C, KOEHL J L, SOLANKY D, et al. Metal ions, not metal-catalyzed oxidative stress, cause clay leachate antibacterial activity[J]. PLoS One, 2014, 9(12): e115172.
本文引用 [1]
[179]
MORRISON K D, MISRA R, WILLIAMS L B. Unearthing the antibacterial mechanism of medicinal clay: a geochemical approach to combating antibiotic resistance[J]. Scientific Reports, 2016, 6: 19043.
本文引用 [4]
[180]
LONDONO S C, HARTNETT H E, WILLIAMS L B. The antibacterial activity of aluminum in clay from the colombian amazon[J]. Environmental Science & Technology, 2017, 51(4): 2401-2408.
本文引用 [2]
[181]
CAFLISCH K M, SCHMIDT-MALAN S M, MANDREKAR J N, et al. Antibacterial activity of reduced iron clay against pathogenic bacteria associated with wound infections[J]. International Journal of Antimicrobial Agents, 2018, 52(5): 692-696.
本文引用 [1]
[182]
KONHAUSER K O, URRUTIA M M. Bacterial clay authigenesis: a common biogeochemical process[J]. Chemical Geology, 1999, 161(4): 399-413.
本文引用 [2]
[183]
LONDONO S C, WILLIAMS L B. Unraveling the antibacterial mode of action of a clay from the colombian amazon[J]. Environmental Geochemistry & Health, 2015, 38(2): 363-379.
本文引用 [1]
[184]
XIA Q, WANG X, ZENG Q, et al. Mechanisms of enhanced antibacterial activity by reduced chitosan-intercalated nontronite[J]. Environmental Science & Technology, 2020, 54(8): 5207-5217.
本文引用 [5]
[185]
WANG X, DONG H, ZENG Q, et al. Reduced iron-containing clay minerals as antibacterial agents[J]. Environmental Science & Technology, 2017, 51(13): 7639-7647.
本文引用 [4]
[186]
GUO D, XIA Q, ZENG Q, et al. Antibacterial mechanisms of reduced iron-containing smectite-illite clay minerals[J]. Environmental Science & Technology, 2021, 55(22): 15256-15265.
本文引用 [1]
[187]
XIA Q, CHEN J, DONG H. Effects of organic ligands on the antibacterial activity of reduced iron-containing clay minerals: higher extracellular hydroxyl radical production yet lower bactericidal activity[J]. Environmental Science & Technology, 2023, 57(17): 6888-6897.
本文引用 [3]
[188]
YUAN S, LIU X, LIAO W, et al. Mechanisms of electron transfer from structrual Fe(II) in reduced nontronite to oxygen for production of hydroxyl radicals[J]. Geochimica et Cosmochimica Acta, 2018, 223: 422-436.
本文引用 [1]
[189]
WILLIAMS L B. Natural antibacterial clay: historical uses and modern advances[J]. Clays and Clay Minerals, 2019, 67(1): 7-24.
本文引用 [1]
[190]
ZATTA P, KISS T, SUWALSKY M, et al. Aluminium (III) as a promoter of cellular oxidation[J]. Coordination Chemistry Reviews, 2002, 228(2): 271-284.
本文引用 [1]
[191]
OTEIZA P I, VERSTRAETEN S V. Interactions of Al and related metals with membrane phospholipids: consequences on membrane physical properties[J]. Advances in Planar Lipid Bilayers and Liposomes, 2006, 4: 79-106.
本文引用 [1]
[192]
夏庆银. 还原态壳聚糖插层改性绿脱石的高效抗菌机理研究[D]. 北京: 中国地质大学(北京), 2020.
本文引用 [1]

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