李倩瑋,博士���,副教授��,博士生導(dǎo)師���,校級(jí)青年拔尖人才。2016年畢業(yè)于英國(guó)鄧迪大學(xué)獲得環(huán)境微生物博士學(xué)位?,F(xiàn)任化學(xué)工程與環(huán)境學(xué)院副院長(zhǎng)��。主要從事環(huán)境微生物�、污染物遷移轉(zhuǎn)化等方面的教學(xué)與研究工作。主持國(guó)家自然科學(xué)基金�、科技部重點(diǎn)研發(fā)子課題、企業(yè)等多項(xiàng)項(xiàng)目�。以第一/通訊作者身份在Current Biology(Cell子刊)�、Water Research����、Environmental Sciences & Technology、Chemical Engineering Journal����、Nano Research、Environmental Microbiology�����、Environmental Sciences: Nano等環(huán)境化工領(lǐng)域期刊發(fā)表多篇論文�。
郵箱: [email protected] 辦公電話(huà):010-89739050
研究方向
[1] 微生物-礦物-水界面的反應(yīng)機(jī)理研究
[2] 重金屬污染物在環(huán)境中的遷移轉(zhuǎn)化行為
招生信息
課題組歡迎以下學(xué)生加入:
· 碩士研究生(環(huán)境科學(xué)與工程、環(huán)境工程��、化學(xué)工程����、工程管理)
· 博士研究生(化學(xué)工程與技術(shù)、環(huán)境工程)
· 對(duì)科研感興趣的本科生(科研訓(xùn)練/畢業(yè)設(shè)計(jì))
適合專(zhuān)業(yè)背景:
· 環(huán)境科學(xué)與工程
· 化學(xué)工程與技術(shù)
· 生物工程 / 微生物學(xué)
· 化學(xué)或材料相關(guān)專(zhuān)業(yè)
教育背景
2012-2016 英國(guó)鄧迪大學(xué) 環(huán)境微生物學(xué) 博士
2010-2012 哈爾濱工業(yè)大學(xué) 遺傳學(xué) 碩士
2006-2010 哈爾濱工業(yè)大學(xué) 生物工程 學(xué)士
工作經(jīng)歷
2024.08-至今 化學(xué)工程與環(huán)境學(xué)院 副院長(zhǎng)
2019.10-至今 環(huán)境科學(xué)與工程系 系支部書(shū)記
2017.06至今 副教授����,化學(xué)工程與環(huán)境學(xué)院,中國(guó)石油大學(xué)(北京)
2023.04-2024.01 校黨委宣傳部�,副部長(zhǎng)(掛職)
2016.11-2017.06 講師�,化學(xué)工程與環(huán)境學(xué)院���,中國(guó)石油大學(xué)(北京)
主講課程
本科課程:
· 生物化學(xué)
· 可持續(xù)發(fā)展概論
· 畢業(yè)實(shí)習(xí)
· 生物化學(xué)(全英文)
研究生課程:
· 環(huán)境分子生物學(xué)技術(shù)
· 環(huán)境科學(xué)與工程前沿講座
承擔(dān)項(xiàng)目
[1] 國(guó)家自然科學(xué)基金面上項(xiàng)目�, 生物礦化耦合自絮凝強(qiáng)化處理典型化工廢水的機(jī)理研究���,2025-2028�����,主持����,在研����。
[2] 國(guó)家自然科學(xué)基金青年項(xiàng)目,油田土壤環(huán)境中產(chǎn)脲酶真菌的多樣性及其對(duì)重金屬離子的礦化機(jī)制研究�,2018-2020,主持�����,已結(jié)題�����。
[3] 科技部外國(guó)專(zhuān)家項(xiàng)目�����,2023-2024�,主持,已結(jié)題���。
[4] 國(guó)家重點(diǎn)研發(fā)計(jì)劃子課題���,石油污染土壤熱脫附工藝系統(tǒng)設(shè)計(jì)研究 2019-2022,第二負(fù)責(zé)人�,已結(jié)題。
[5] 山西省科技合作專(zhuān)項(xiàng)�����,典型產(chǎn)煤區(qū)重金屬-多環(huán)芳烴復(fù)合污染場(chǎng)地治理關(guān)鍵技術(shù)研究���,2024-2026��,主持�����,在研����。
[6] 中國(guó)石油大學(xué)(北京)拔尖人才科研項(xiàng)目,煉化廢催化劑有價(jià)金屬生物定向轉(zhuǎn)化調(diào)控機(jī)制��,2023-2026�����,主持�,在研。
[7] 中國(guó)環(huán)境科學(xué)研究院環(huán)境技術(shù)工程有限公司服務(wù)項(xiàng)目�����,生物礦化協(xié)同滲濾液氮磷及抗生素去除的機(jī)理與應(yīng)用研究��,2025-2026��,主持����,在研。
[8] 國(guó)家管網(wǎng)集團(tuán)技術(shù)服務(wù)項(xiàng)目�����,復(fù)雜環(huán)境下腐蝕層結(jié)構(gòu)解析和失效特征分析��, 2023-2024�����,主持���,在研�����。
[9] 國(guó)家管網(wǎng)集團(tuán)技術(shù)服務(wù)項(xiàng)目�����,交直流混合干擾評(píng)價(jià)指標(biāo)及緩解方案驗(yàn)證實(shí)驗(yàn)�,2024-2025���,參與��,在研��。
[10] 國(guó)家管網(wǎng)集團(tuán)技術(shù)服務(wù)項(xiàng)目�,不同雜散電流干擾下排流器關(guān)鍵控制指標(biāo)驗(yàn)證實(shí)驗(yàn),2025-2026年���,主持����,在研��。
[11] 中石油安環(huán)院重點(diǎn)實(shí)驗(yàn)室開(kāi)放基金��,生物礦化復(fù)合材料處理鹵代烴有機(jī)廢水的研究��, 2020-2024��,主持����,在研。
[12] 國(guó)家管網(wǎng)集團(tuán)技術(shù)服務(wù)項(xiàng)目����,交直流混合干擾腐蝕風(fēng)險(xiǎn)邊界參數(shù)測(cè)試與分析項(xiàng)目���,222年,主持�,已結(jié)題��。
[13] 中國(guó)石油大學(xué)(北京)學(xué)院自主科研項(xiàng)目��,烴類(lèi)污染物對(duì)地質(zhì)微生物遷移轉(zhuǎn)化重金屬過(guò)程與機(jī)制的研究�,2020-2023,主持�����,已結(jié)題�����。
[14] 中國(guó)石油大學(xué)(北京)引進(jìn)人才科研項(xiàng)目����,電鍍廢水中產(chǎn)脲酶真菌的分離鑒定及其對(duì)重金屬的回收利用,2017-2019���,主持�����,已結(jié)題�����。
[15] 中石油安環(huán)院重點(diǎn)實(shí)驗(yàn)室開(kāi)放基金�,新型多孔碳/納米零價(jià)鐵復(fù)合材料的制備及其對(duì)鹵代烴降解機(jī)制的研究,2017-2018����,主持,已結(jié)題���。
代表性論文
[1] Li, Q., Zhang, M., Bian, Z., Liu, D.*, and Chen, C.* (2026). Enhancing Staphylococcus succinus tolerance via pre-mineralization for bioflocculation-based oilfield water treatment. Water Research 289, 124794.
[2] Li, Q.*, Ma, H., Zhang, M., Wei, B., and Liu, D*. (2026). Synergistic effects of protein coronas and heavy metals on ROS generation: Implications for microplastic-microbe interactions. International Biodeterioration & Biodegradation 207, 106225.
[3] Li, Q., Liu, D.*, Wei, B., Yan, W., and Chen, C. (2026). Manganese oxide activation of peroxydisulfate: Evaluation via redox potential difference (ΔE) index. Water Research 289, 124913.
[4] Li, Q., Liu, D., Yan, W., Liu, H., Chen, C. (2026) Comparative insights into the role of oxygen vacancies in α-MnO 2 for activating peroxymonosulfate and peroxydisulfate. Inorganic Chemistry Frontiers.
[5] Li Q., Ma, H., Zhang, M. Wei, B., Liu, D. (2026) Synergistic effects of protein coronas and heavy metals on ROS generation: Implications for microplastic-microbe interactions. International Biodeterioration & Biodegradation 207, 106225.
[6] Li, Q., Zhang, M., Liu, H., Wang, H., Liu, D., Chen, C. (2026) Integrating indigenous petroleum-degrading bacteria into soil washing for enhanced remediation efficiency. Journal of Cleaner Production 546, 147813.
[7] Wei, B., Liu, D., Wu, Q., Li, Q., Chen, C. (2026) Forward osmosis-induced hydrovoltaic electricity generation using polyaniline-modified carbon mesh electrodes. Journal of Membrane Science 745, 125270
[8] Zhang, M., Wei, B., Liu, H., Liu, D., Gadd, G.M., Li, Q.*, and Chen, C. (2025). Simultaneous removal of hardness and organic matter from oilfield-produced water by microbially induced calcite precipitation. Water Research 276, 123252.
[9] Wei, B., Zhang, M., Liu, H., Li, Q.*, and Liu, D*. (2025). Capacitive deionization coupled with electro-activated persulfate for simultaneous removal of salt and organic pollutants from water. Separation and Purification Technology 373, 133577.
[10] Wei, B., Liu, D., Peng, R., Zhou, Y., Li, Q.*, and Zhao, H.* (2025). Enhanced electron transfer in Fe–N–C catalysts for nitrobenzene reduction: from electrodes to functional materials. Frontiers of Environmental Science & Engineering 19, 158.
[11] Liu, D., Wei, B., Zhang, C., and Li, Q.* (2025). Phosphate recovery through the redox cycling process using cerium-based adsorbents: High capacity and high stability. Journal of Environmental Chemical Engineering 13, 116167.
[12] Liu, D., Wei, B., Zhang, C., and Li, Q.* (2025). Electrochemically regulated cerium-based electrode for enhanced phosphate adsorption and desorption process. Separation and Purification Technology 360, 131025.
[13] Liu, D., Wang, Q., Wei, B., Yang, S., Li, Q., and Zhao, H.* (2025). Simultaneous removal of phosphate and hydroquinone using Fe3Ce1Ox(CA)/H2O2 Fenton-like system. Process Safety and Environmental Protection 199, 107322.
[14] Li, Q., Liu, D.*, Hou, J., Liu, H., and Chen, C. (2025). ZrO2 modified MnO2 catalysts for efficient peroxydisulfate activation and wide pH-range pollutant removal. New Journal of Chemistry 49, 20828-20837.
[15] Li, Q.*, Gong, L., Chen, X., Gadd, G.M., and Liu, D.* (2025). Dual role of microorganisms in metal corrosion: a review of mechanisms of corrosion promotion and inhibition. Frontiers in Microbiology Volume 16 - 2025.
[16] Lan, W., Wei, B., Li, Q., Feng, B., Wang, F., Bi, W., and Liu, D.* (2025). Corrosion mechanisms of pipelines with adjacent coating defects under AC interference: An interfacial process analysis. Materials & Design 256, 114295.
[17] Liu, D., Zhou, Y., Wei, B., Li, Q., and Zhao, H.* (2024). Analyzing the active sites of carbocatalyst for peroxydisulfate activation: Specific surface area or electrochemical surface area? Chemosphere 364, 143124.
[18] Li, Y., Ma, H., Li, Q., Yan, G., and Guo, S.* (2024). One-step synthesis of Pt-Nd co-doped Ti/SnO2-Sb nanosphere electrodes used to degrade nitrobenzene. Environmental Science and Pollution Research 31, 4528-4538.
[19] Li, Q., Zhang, M., Wei, B., Lan, W., Wang, Q., Chen, C., Zhao, H., Liu, D.*, and Gadd, G.M.* (2024). Fungal biomineralization of toxic metals accelerates organic pollutant removal. Current Biology 34, 2077-2084.e2073.
[20] Liu, D., Li, Q.*, Liu, E., Zhang, M., Liu, J., and Chen, C. (2023). Biomineralized nanoparticles for the immobilization and degradation of crude oil-contaminated soil. Nano Research 16, 12238-12245.
[21] Lan, W., Li, Q., Wei, B., Bi, W., Xu, C., and Liu, D.* (2023). Evaluation of AC corrosion under anodic polarization using microzone pH analysis. Corrosion Science 219, 111219.
[22] Li, Q., Liu, F., Li, M., Chen, C., and Gadd, G.M.* (2022). Nanoparticle and nanomineral production by fungi. Fungal Biology Reviews 41, 31-44.
[23] Liu, D.*, Li, Q., Hou, J., and Zhao, H.* (2021). Mixed-valent manganese oxide for catalytic oxidation of Orange II by activation of persulfate: heterojunction dependence and mechanism. Catalysis Science & Technology 11, 3715-3723.
[24] Wang, X., Ming, J., Chen, C.M., Yoza, B.A., Li, Q., Liang, J.H., Gadd, G.M., and Wang, Q.* (2020). Rapid aerobic granulation using biochar for the treatment of petroleum refinery wastewater. Petroleum Science 17, 1411-1421.
[25] Li, Q.*, Liu, J., and Gadd, G.M.* (2020). Fungal bioremediation of soil co-contaminated with petroleum hydrocarbons and toxic metals. Applied Microbiology and Biotechnology 104, 8999-9008.
[26] Li, Q., Liu, D., Wang, T., Chen, C.*, and Gadd, G.M. (2020). Iron coral: Novel fungal biomineralization of nanoscale zerovalent iron composites for treatment of chlorinated pollutants. Chemical Engineering Journal 402, 126263.
[27] Lang, X., Li, Q., Ji, M., Yan, G.*, and Guo, S. (2020). Isolation and niche characteristics in simultaneous nitrification and denitrification application of an aerobic denitrifier, Acinetobacter sp. YS2. Bioresource Technology 302, 122799.
[28] Liu, D., Li, Q.*, Li, S., Hou, J., and Zhao, H.* (2019). A confinement strategy to prepare N-doped reduced graphene oxide foams with desired monolithic structures for supercapacitors. Nanoscale 11, 4362-4368.
[29] Li, Q.*, Liu, D., Chen, C.*, Shao, Z., Wang, H., Liu, J., Zhang, Q., and Gadd, G.M. (2019). Experimental and geochemical simulation of nickel carbonate mineral precipitation by carbonate-laden ureolytic fungal culture supernatants. Environmental Science: Nano 6, 1866-1875.
[30] Lang, X., Li, Q., Xu, Y., Ji, M., Yan, G.*, and Guo, S. (2019). Aerobic denitrifiers with petroleum metabolizing ability isolated from caprolactam sewage treatment pool. Bioresource Technology 290, 121719.
[31] Liu, D., Li, Q., and Zhao, H.* (2018). Electrolyte-assisted hydrothermal synthesis of holey graphene films for all-solid-state supercapacitors. Journal of Materials Chemistry A 6, 11471-11478.
[32] Liu, D., Li, Q., Hou, J., and Zhao, H.* (2018). Porous 3D graphene-based biochar materials with high areal sulfur loading for lithium–sulfur batteries. Sustainable Energy & Fuels 2, 2197-2205.
[33] Li, Q., and Gadd, G.M.* (2017). Fungal nanoscale metal carbonates and production of electrochemical materials. Microb Biotechnol 10, 1131-1136.
[34] Li, Q., and Gadd, G.M.* (2017). Biosynthesis of copper carbonate nanoparticles by ureolytic fungi. Applied Microbiology and Biotechnology 101, 7397-7407.
[35] Li, Q., Liu, D., Jia, Z., Csetenyi, L., and Gadd, G.M.* (2016). Fungal Biomineralization of Manganese as a Novel Source of Electrochemical Materials. Current Biology 26, 950-955.
[36] Kumari, D.*, Qian, X.Y.*, Pan, X.*, Achal, V., Li, Q., and Gadd, G.M.* (2016). Chapter Two - Microbially-induced Carbonate Precipitation for Immobilization of Toxic Metals. In Advances in Applied Microbiology, Volume 94, S. Sariaslani and G.M. Gadd, eds. (Academic Press), pp. 79-108.
[37] Li, Q., Csetenyi, L., Paton, G.I., and Gadd, G.M.* (2015). CaCO3 and SrCO3 bioprecipitation by fungi isolated from calcareous soil. Environmental Microbiology 17, 3082-3097.
[38] Shi, C., Yan, P.*, Li, J., Wu, H., Li, Q., and Guan, S. (2014). Biocontrol of Fusarium graminearum Growth and Deoxynivalenol Production in Wheat Kernels with Bacterial Antagonists. International Journal of Environmental Research and Public Health 11, 1094-1105.
[39] Li, Q., Csetenyi, L., and Gadd, G.M.* (2014). Biomineralization of Metal Carbonates by Neurospora crassa. Environmental Science & Technology 48, 14409-14416.
[40] Gadd, G.M.*, Bahri-Esfahani, J., Li, Q., Rhee, Y.J., Wei, Z., Fomina, M., and Liang, X. (2014). Oxalate production by fungi: significance in geomycology, biodeterioration and bioremediation. Fungal Biology Reviews 28, 36-55.
[41] Wang, Z., Yan, P.*, Cao, L., Li, Q., & Lin, F. (2011). Effects of Nutritional Factors on Production of Bacterial Bioactive Metabolites against Aflatoxin Biosynthesis. Advanced Materials Research, 343–344, 564–567.
[42] Yan, P.*, Gao, X., Wu, H., Li, Q., Ning, L., and Guan, S. (2010). Isolation and screening of biocontrol bacterial strains against Aspergillus parasiticus from groundnut geocarposphere. Journal of Earth Science 21, 309.
發(fā)明專(zhuān)利
[1] 李倩瑋�,王通哲����,邢楊。負(fù)載有納米單質(zhì)鐵的復(fù)合材料及其制備方法和應(yīng)用 CN201910831635.9 (實(shí)施許可)
[2] 李倩瑋�,汪華珍,陳春茂�?;趯蛹?jí)疏水/親水電極同步除鹽和有機(jī)物的方法�、裝置 CN202110183426.5(已授權(quán))
[3] 李倩瑋,張苗���,陳春茂��。一種基于微生物的調(diào)剖驅(qū)油方法 CN202210587780.9 (已授權(quán))
[4] 李倩瑋���,劉恩會(huì)��,劉道慶�,張苗,陳春茂�����。一種重金屬生物有效性的檢測(cè)裝置和方法 CN202211155496.0(已授權(quán))
[5] 李倩瑋�����,張苗����,韋標(biāo)�,陳春茂��。一種用于石油污染土壤的微生物修復(fù)劑和修復(fù)方法 CN202310417896.2
[6] 李倩瑋�����,韋標(biāo)����,劉道慶,張苗��,張晨���,陳春茂��。一種基于電化學(xué)調(diào)控的磷酸鹽吸附脫附方法 CN202311184465.2 (已授權(quán))
[7] 劉道慶�����,張苗�,李倩瑋���,邊澤晨���,陳春茂�。一種工程菌及其構(gòu)建方法和應(yīng)用 CN202410102898.7
[8] 李倩瑋��,劉浩�,劉道慶,陳春茂�����。二氧化碳捕獲裝置及二氧化碳捕獲方法CN202411486430.9 (已授權(quán))
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