劉鄧(中國地質大學(武漢)副教授)

劉鄧(中國地質大學(武漢)副教授)

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劉鄧,男,博士,中國地質大學(武漢)副教授。

基本介紹

  • 中文名:劉鄧
  • 學位/學歷:博士
  • 職業:教師
  • 專業方向:微生物-礦物相互作用及其地質意義
  • 任職院校:中國地質大學(武漢)
個人經歷,主講課程,研究方向,學術成果,

個人經歷

工作經歷:
2012.12-2016.1,中國地質大學(武漢)環境科學與工程博士後流動站,博士後
2013.5-2016.6,淋束重中國地質大學(武漢甩洪腳章)環境學院,特任副教授
2016.6-至今,中國地質大學(武漢)環境學院,副教授

主講課程

《普通生物學》、《生物地球化學》

研究方向

微生物員蘭承-礦物相互作用及其地質意義
基於微生物礦化的重金屬去除技術
微漿煮廈生物化石

學術成果

主持科研項目:
國家自然科學基金面上項目,埋藏成岩過程中生物成因原白雲石演化的模擬背厚束研究,2018-2021;
國家自然科學基金面上項目,硫酸鹽型鹽湖中好氧微生物介導的白雲石沉澱過程及其機理,2016;
國家自然科學基金青年基金項目,鹽湖嗜鹼菌作用下粘土礦物結構鐵的還原過程及其礦物轉變機理,2014-2016;
中央高校基本科研業務專項資金“搖籃計畫”,Na2SO4型鹽湖沉積物中自生白雲石的微生物成因研究,2015-2017;
中國博士後科學基金面上資助項目,靜水高壓條件下鐵還原微去套生物與蒙皂石相互作用,2013;
中央高校基本科研業務專項資金新青年教師科研啟動基金,0.1-20 MPa靜水壓力條件下微生物介導的蒙皂石結構鐵還原過程,2014-2015
發表論文:
第一作者和通訊作煉墓鴉想者論文 (*通訊作者)
[1] Liu, D.*, Fan, Q., Papineau, D., Yu, N., Chu, Y., Wang, H., Qiu, X., Wang, X., Precipitation of protodolomite facilitated by sulfate-reducing bacteria: The role of capsule extracellular polymeric substances. Chemical Geology, 2020, 533, 119415.
[2] Liu, D.*, Xu, Y., Yu, Q., Yu, N., Qiu, X., Wang, H., Papineau, D., Catalytic effect of microbially-derived carboxylic acids on the precipitation of Mg-calcite and disordered dolomite: Implications for sedimentary dolomite. Journal of Asian Earth Sciences, 2020, 193, 104301.
[3] Liu, D.*, Yu, N., Papineau, D., Fan, Q., Wang, H.*, Qiu, X., She, Z., Luo, G., The catalytic role of planktonic aerobic heterotrophic bacteria in protodolomite formation: Results from Lake Jibuhulangtu Nuur, Inner Mongolia, China. Geochimica et Cosmochimica Acta, 2019, 263, 31-49.
[4] Liu, D.*, Xu, Y., Papineau, D., Yu, N., Fan, Q., Qiu, X., Wang, H.*, Experimental evidence for abiotic formation of low-temperature proto-dolomite facilitated by clay minerals. Geochimica et Cosmochimica Acta, 2019, 247, 83-95. (ESI高被引論文)
[5] Liu, D.*, Zhang, Q., Wu, L., Zeng, Q., Dong, H., Bishop, M.E., Wang, H.*, Humic acid-enhanced illite and talc formation associated with microbial reduction of Fe(III) in nontronite. Chemical Geology, 2016, 447, 199-207.
[6] Liu, D.*, Wang F., Dong, H., Wang, H., Zhao, L., Huang, L., Wu, L., Biological reduction of structural Fe(III) in smectites by a marine bacterium at 0.1 and 20 MPa. Chemical Geology, 2016, 438, 1-10.
[7] Liu, D.*, Dong, H., Agrawal, A., Singh, R., Zhang, J., Wang, H., Inhibitory effect of clay mineral on methanogenesis by Methanosarcina mazei and Methanothermobacter thermautotrophicus, Applied Clay Science, 2016, 126, 25-32.
[8] Liu, D., Dong, H.*, Wang, H.*, Zhao, L., Low-temperature feldspar and illite formation through bioreduction of Fe(III)-bearing smectite by an alkaliphilic bacterium, Chemical Geology, 2015, 406, 25-33.
[9] Liu, D., Dong, H.*, Zhao, L., Wang, H.*, Smectite reduction by Shewanella species as facilitated by cystine and cysteine, Geomicrobiology Journal, 2014, 31, 53-63.
[10] Liu, D., Dong, H.*, Bishop, M., Zhang, J., Wang, H.*, Xie, S., Wang, S., Huang, L., Eberl, D., Microbial reduction of structural iron in interstratified illite-smectite minerals by a sulfate-reducing bacterium, Geobiology, 2012, 10(2), 150-162.
[11] Liu, D., Dong, H.*, Bishop, ME., Wang, H.*, Agrawal, A., Tritschler, S., Eberl, D., Xie, S., Reduction of structural Fe(III) in nontronite by methanogen Methanosarcina barkeri, Geochimica et Cosmochimica Acta, 2011, 75(4), 1057-1071.
[12] Liu, D., Wang, H.*, Dong, H.*, Qiu, X., Xie, S., Dong, X., Cravotta III, C., Mineral transformation associated with goethite reduction by Methanosarcina barkeri, Chemical Geology, 2011, 288(1-2), 53-60.
[13] Liu, D., Wang, H.*, Qiu, X., Dong, H.*, Comparison of reduction extent of Fe(III) in nontronite by Shewanella putrefaciens and Desulfovibrio vulgaris, Journal of Earth Science, 2010, 21(1), 297-299.
[14] Liu, D., Yang, X., Wang, H.*, Li, J., Su, N., Impact of montmorillonite and calcite on release and adsorption of cyanobacterial fatty acids at ambient temperature, Journal of China University of Geosciences, 2008, 19(5), 526-533.
[15] 許楊陽, 劉鄧*, 于娜, 邱軒, 王紅梅. 微生物(有機)白雲石成因模式研究進展與思考.地球科學, 2018, 43(S1),63-70.
[16] 于娜, 許楊陽, 劉鄧*, 邱軒, 范奇高, 王紅梅. 內蒙古吉布胡郎圖諾爾鹽湖厭氧菌對白雲石形成的催化作用. 地球科學, 2018, 43(S1),53-62.
[17] 張千帆, 曾強, 劉鄧*, 王紅梅. 腐殖酸對微生物還原綠脫石結構Fe(III)的促進作用. 地質科技情報, 2016, 35(6), 205-211.
其他合作論文
[1] Li, J., Pancost, R.D., Naffs, B.D.A., Yang, H., Liu, D., Gong, L., Xie, S., Multiple environmental and ecological controls on archael ether lipid distributions in saline ponds. Chemical Geology, 2019,529, 119293.
[2] Wang, C., Bendle, J.A., Zhang, H., Yang, Y., Liu, D., Huang, J., Cui, J., Xie, S., Holocene temperature and hydrological changes reconstructed by bacterial 3-hydroxy fatty acids in stalagmite from central China. Quaternary Science Reviews, 2018, 192, 97-105.
[3] Chen, R., Liu, H., Tong, M., Zhao, L., Zhang, P., Liu, D., Yuan, S., Impact of Fe(II) oxidation in the presence of iron-reducing bacteria on subsequent Fe(III) bio-reduction. Science of the Total Environment, 2018, 639, 1007-1014.
[4] Li, J., Naafs, B.D.A., Pancost, R.D., Yang, H., Liu, D., Xie, S., Distribution of branched tetraether lipids in ponds from Inner Mongolia, NE China: Insight into the source of brGDGTs, Organic Geochemistry, 2017, 112, 127-136.
[5] Liu, X., Yuan, S., Tong, M., Liu, D., Oxidation of trichloroethylene by the hydroxyl radicals produced from oxygenation of reduced nontronite, Water Research, 2017, 113, 72-79.
[6] Xie, S., Liu, D., Qiu, X., Huang, X., Algeo, T.J., Microbial roles equivalent to geological agents of high temperature and pressure in deep Earth, Science China Earth Sciences, 2016, 59(11), 2098-2104.
[7] Tong, M., Yuan, S., Ma, S., Jin, M., Liu, D., Cheng, D., Liu, X., Gan, Y., Wang, Y., Production of abundant hydroxyl radicals from oxygenation of subsurface sediments, Environmental Science & Technology, 2016, 50(1), 214-221.
[8] Singh, R., Dong, H., Liu, D., Zhao, L., Marts, AR., Farquhar, E., Tierney, DL., Almquist, CB., Briggs, BR., Reduction of hexacalent chromium by the thermophilic methanogen Methanothermobacter thermautotrophicus, Geochimica et Cosmochimica Acta, 2015, 148, 442-456.
[9] Singh, R., Dong, H., Liu, D., Marts, A.R., Tierney, D.L., Almquist, C.B., [Cobalt(III)-EDTA] reduction by thermophilic methanogen Methanothermobacter thermautotrophicus, Chemical Geology, 2015, 411, 49-56.
[10] Luo, G., Xie, S., Liu, D., Algeo, TJ., Microbial influences on paleoenvironmental changes during the Permian-Triassic boundary crisis, Science China Earth Sciences, 2014, 57, 965-975.
[11] Zhao, L., Dong, H., Kukkadapu, R., Agrawal, A., Liu, D., Zhang, J., Edelmann, RE., Biological oxidation of Fe(II) in reduced nontronite coupled with nitrate reduction byPseudogulbenkiania sp. strain 2002, Geochimica et Cosmochimica Acta, 2013, 119, 231-247.
[12] Zhang, J., Dong, H., Liu, D., Agrawal, A., Microbial reduction of Fe(III) in smectite minerals by thermophilic methanogen Methanothermobacter thermautotrophicus, Geochimica et Cosmochimica Acta, 2013, 106, 203-215.
[13] Zhang, J., Dong, H., Liu, D., Fisher, TB., Wang, S., Huang, L., Microbial reduction of Fe(III) in smectite-illite minerals by methanogen Methanosarcina mazei, Chemical Geology, 2012, 292-293, 35-44.
[14] Qiu, X., Wang, H., Liu, D., Gong, L., Wu, X., Xiang, X., The physiological response of Synechococcus elongatus to salinity: A potential biomarker for ancient salinity in evaporative environments, Geomicrobiology Journal, 2012, 29(5), 477-483.
[15] Xie, S., Yang, H., Luo, G., Huang, X., Liu, D., Wang, Y., Gong, Y., Xu, R., Geomicrobial functional groups: A window to the interaction between life and environments, Chinese Science Bulletin, 2012, 57, 2-19.
[16] Wang, S., Dong, RM., Dong, CZ., Huang, L., Jiang, H., Wei, Y., Feng, L., Liu, D., Yang, G., Zhang, C., Dong, H., Diversity of microbial plankton across the Three Gorges Dams of the Yangtze River, China, Geoscience Frontiers, 2012, 3, 335-349.
[17] Li, J., Yang, H., Liu, D., Huang, J., Comparative analysis of lipids in Funaria hygrometrica Hdew from different habitats, Journal of Earth Science, 2010, 21(1), 247-249.
[18] Wang, H., Zeng, C., Liu, Q., Liu, D., Qiu, X., Gong, L., Calcium carbonate precipitation induced by a bacterium strain isolated from an oligotrophic cave in Central China, Frontiers of Earth Science in China, 2010, 4(2), 148-151.
[19] Wang, H., Ma, X., Liu, D., Yang, X., and Li, J., Chemical variation from biolipids to sedimentary organic matter in modern oceans and its implication to the geobiological evaluation of ancient hydrocarbon source rocks, Frontiers of Earth Science in China, 2007, 1(4), 399-404.
[20] 張蔚, 胡小麗, 邱軒, 劉鄧, 馮亮, 馬麗媛, 胡婧, 王紅梅. 山東勝利油田沾3油藏微生物組特徵. 科學通報, 2019, 64(18), 1930-1942.
[21] 胡小麗, 張蔚, 劉鄧, 邱軒, 王紅梅. 油藏嗜熱菌與膨潤土的相互作用及其對儲層防膨的意義. 微生物學報, 2019, 59(6), 1197-1208.
[22] 謝樹成, 殷鴻福, 劉鄧, 邱軒. 再談古生物學向地球生物學的發展. 地球科學, 2018, 43(11), 3823-3836.
[23] 王紅梅, 劉爍, 劉鄧. 硫酸鹽還原菌及異化鐵還原菌對黃鉀鐵礬還原作用的對比. 地球科學, 2015, 40(2),305-316.
[24] 王紅梅, 吳曉萍, 邱軒, 劉鄧. 微生物成因的碳酸鹽礦物研究進展. 微生物學通報, 2013, 40(1), 180-189.
[25] 王紅梅, 馬相如, 劉鄧, 楊小芬, 李繼紅. 從生物脂類化合物到沉積有機質的變化及其對正演烴源岩有機質形成的啟示. 地球科學, 2007, 32(6), 748-754.
[4] Liu, D.*, Xu, Y., Papineau, D., Yu, N., Fan, Q., Qiu, X., Wang, H.*, Experimental evidence for abiotic formation of low-temperature proto-dolomite facilitated by clay minerals. Geochimica et Cosmochimica Acta, 2019, 247, 83-95. (ESI高被引論文)
[5] Liu, D.*, Zhang, Q., Wu, L., Zeng, Q., Dong, H., Bishop, M.E., Wang, H.*, Humic acid-enhanced illite and talc formation associated with microbial reduction of Fe(III) in nontronite. Chemical Geology, 2016, 447, 199-207.
[6] Liu, D.*, Wang F., Dong, H., Wang, H., Zhao, L., Huang, L., Wu, L., Biological reduction of structural Fe(III) in smectites by a marine bacterium at 0.1 and 20 MPa. Chemical Geology, 2016, 438, 1-10.
[7] Liu, D.*, Dong, H., Agrawal, A., Singh, R., Zhang, J., Wang, H., Inhibitory effect of clay mineral on methanogenesis by Methanosarcina mazei and Methanothermobacter thermautotrophicus, Applied Clay Science, 2016, 126, 25-32.
[8] Liu, D., Dong, H.*, Wang, H.*, Zhao, L., Low-temperature feldspar and illite formation through bioreduction of Fe(III)-bearing smectite by an alkaliphilic bacterium, Chemical Geology, 2015, 406, 25-33.
[9] Liu, D., Dong, H.*, Zhao, L., Wang, H.*, Smectite reduction by Shewanella species as facilitated by cystine and cysteine, Geomicrobiology Journal, 2014, 31, 53-63.
[10] Liu, D., Dong, H.*, Bishop, M., Zhang, J., Wang, H.*, Xie, S., Wang, S., Huang, L., Eberl, D., Microbial reduction of structural iron in interstratified illite-smectite minerals by a sulfate-reducing bacterium, Geobiology, 2012, 10(2), 150-162.
[11] Liu, D., Dong, H.*, Bishop, ME., Wang, H.*, Agrawal, A., Tritschler, S., Eberl, D., Xie, S., Reduction of structural Fe(III) in nontronite by methanogen Methanosarcina barkeri, Geochimica et Cosmochimica Acta, 2011, 75(4), 1057-1071.
[12] Liu, D., Wang, H.*, Dong, H.*, Qiu, X., Xie, S., Dong, X., Cravotta III, C., Mineral transformation associated with goethite reduction by Methanosarcina barkeri, Chemical Geology, 2011, 288(1-2), 53-60.
[13] Liu, D., Wang, H.*, Qiu, X., Dong, H.*, Comparison of reduction extent of Fe(III) in nontronite by Shewanella putrefaciens and Desulfovibrio vulgaris, Journal of Earth Science, 2010, 21(1), 297-299.
[14] Liu, D., Yang, X., Wang, H.*, Li, J., Su, N., Impact of montmorillonite and calcite on release and adsorption of cyanobacterial fatty acids at ambient temperature, Journal of China University of Geosciences, 2008, 19(5), 526-533.
[15] 許楊陽, 劉鄧*, 于娜, 邱軒, 王紅梅. 微生物(有機)白雲石成因模式研究進展與思考.地球科學, 2018, 43(S1),63-70.
[16] 于娜, 許楊陽, 劉鄧*, 邱軒, 范奇高, 王紅梅. 內蒙古吉布胡郎圖諾爾鹽湖厭氧菌對白雲石形成的催化作用. 地球科學, 2018, 43(S1),53-62.
[17] 張千帆, 曾強, 劉鄧*, 王紅梅. 腐殖酸對微生物還原綠脫石結構Fe(III)的促進作用. 地質科技情報, 2016, 35(6), 205-211.
其他合作論文
[1] Li, J., Pancost, R.D., Naffs, B.D.A., Yang, H., Liu, D., Gong, L., Xie, S., Multiple environmental and ecological controls on archael ether lipid distributions in saline ponds. Chemical Geology, 2019,529, 119293.
[2] Wang, C., Bendle, J.A., Zhang, H., Yang, Y., Liu, D., Huang, J., Cui, J., Xie, S., Holocene temperature and hydrological changes reconstructed by bacterial 3-hydroxy fatty acids in stalagmite from central China. Quaternary Science Reviews, 2018, 192, 97-105.
[3] Chen, R., Liu, H., Tong, M., Zhao, L., Zhang, P., Liu, D., Yuan, S., Impact of Fe(II) oxidation in the presence of iron-reducing bacteria on subsequent Fe(III) bio-reduction. Science of the Total Environment, 2018, 639, 1007-1014.
[4] Li, J., Naafs, B.D.A., Pancost, R.D., Yang, H., Liu, D., Xie, S., Distribution of branched tetraether lipids in ponds from Inner Mongolia, NE China: Insight into the source of brGDGTs, Organic Geochemistry, 2017, 112, 127-136.
[5] Liu, X., Yuan, S., Tong, M., Liu, D., Oxidation of trichloroethylene by the hydroxyl radicals produced from oxygenation of reduced nontronite, Water Research, 2017, 113, 72-79.
[6] Xie, S., Liu, D., Qiu, X., Huang, X., Algeo, T.J., Microbial roles equivalent to geological agents of high temperature and pressure in deep Earth, Science China Earth Sciences, 2016, 59(11), 2098-2104.
[7] Tong, M., Yuan, S., Ma, S., Jin, M., Liu, D., Cheng, D., Liu, X., Gan, Y., Wang, Y., Production of abundant hydroxyl radicals from oxygenation of subsurface sediments, Environmental Science & Technology, 2016, 50(1), 214-221.
[8] Singh, R., Dong, H., Liu, D., Zhao, L., Marts, AR., Farquhar, E., Tierney, DL., Almquist, CB., Briggs, BR., Reduction of hexacalent chromium by the thermophilic methanogen Methanothermobacter thermautotrophicus, Geochimica et Cosmochimica Acta, 2015, 148, 442-456.
[9] Singh, R., Dong, H., Liu, D., Marts, A.R., Tierney, D.L., Almquist, C.B., [Cobalt(III)-EDTA] reduction by thermophilic methanogen Methanothermobacter thermautotrophicus, Chemical Geology, 2015, 411, 49-56.
[10] Luo, G., Xie, S., Liu, D., Algeo, TJ., Microbial influences on paleoenvironmental changes during the Permian-Triassic boundary crisis, Science China Earth Sciences, 2014, 57, 965-975.
[11] Zhao, L., Dong, H., Kukkadapu, R., Agrawal, A., Liu, D., Zhang, J., Edelmann, RE., Biological oxidation of Fe(II) in reduced nontronite coupled with nitrate reduction byPseudogulbenkiania sp. strain 2002, Geochimica et Cosmochimica Acta, 2013, 119, 231-247.
[12] Zhang, J., Dong, H., Liu, D., Agrawal, A., Microbial reduction of Fe(III) in smectite minerals by thermophilic methanogen Methanothermobacter thermautotrophicus, Geochimica et Cosmochimica Acta, 2013, 106, 203-215.
[13] Zhang, J., Dong, H., Liu, D., Fisher, TB., Wang, S., Huang, L., Microbial reduction of Fe(III) in smectite-illite minerals by methanogen Methanosarcina mazei, Chemical Geology, 2012, 292-293, 35-44.
[14] Qiu, X., Wang, H., Liu, D., Gong, L., Wu, X., Xiang, X., The physiological response of Synechococcus elongatus to salinity: A potential biomarker for ancient salinity in evaporative environments, Geomicrobiology Journal, 2012, 29(5), 477-483.
[15] Xie, S., Yang, H., Luo, G., Huang, X., Liu, D., Wang, Y., Gong, Y., Xu, R., Geomicrobial functional groups: A window to the interaction between life and environments, Chinese Science Bulletin, 2012, 57, 2-19.
[16] Wang, S., Dong, RM., Dong, CZ., Huang, L., Jiang, H., Wei, Y., Feng, L., Liu, D., Yang, G., Zhang, C., Dong, H., Diversity of microbial plankton across the Three Gorges Dams of the Yangtze River, China, Geoscience Frontiers, 2012, 3, 335-349.
[17] Li, J., Yang, H., Liu, D., Huang, J., Comparative analysis of lipids in Funaria hygrometrica Hdew from different habitats, Journal of Earth Science, 2010, 21(1), 247-249.
[18] Wang, H., Zeng, C., Liu, Q., Liu, D., Qiu, X., Gong, L., Calcium carbonate precipitation induced by a bacterium strain isolated from an oligotrophic cave in Central China, Frontiers of Earth Science in China, 2010, 4(2), 148-151.
[19] Wang, H., Ma, X., Liu, D., Yang, X., and Li, J., Chemical variation from biolipids to sedimentary organic matter in modern oceans and its implication to the geobiological evaluation of ancient hydrocarbon source rocks, Frontiers of Earth Science in China, 2007, 1(4), 399-404.
[20] 張蔚, 胡小麗, 邱軒, 劉鄧, 馮亮, 馬麗媛, 胡婧, 王紅梅. 山東勝利油田沾3油藏微生物組特徵. 科學通報, 2019, 64(18), 1930-1942.
[21] 胡小麗, 張蔚, 劉鄧, 邱軒, 王紅梅. 油藏嗜熱菌與膨潤土的相互作用及其對儲層防膨的意義. 微生物學報, 2019, 59(6), 1197-1208.
[22] 謝樹成, 殷鴻福, 劉鄧, 邱軒. 再談古生物學向地球生物學的發展. 地球科學, 2018, 43(11), 3823-3836.
[23] 王紅梅, 劉爍, 劉鄧. 硫酸鹽還原菌及異化鐵還原菌對黃鉀鐵礬還原作用的對比. 地球科學, 2015, 40(2),305-316.
[24] 王紅梅, 吳曉萍, 邱軒, 劉鄧. 微生物成因的碳酸鹽礦物研究進展. 微生物學通報, 2013, 40(1), 180-189.
[25] 王紅梅, 馬相如, 劉鄧, 楊小芬, 李繼紅. 從生物脂類化合物到沉積有機質的變化及其對正演烴源岩有機質形成的啟示. 地球科學, 2007, 32(6), 748-754.

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