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李思亮 职务:副院长
性别：男
职称:教授
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工作经历
· 2015.12 - 2020.5 地球系统科学学院（表层地球系统科学研究院）→天津大学 →教授


研究方向
· 环境地理学：不同流域单元水环境质量变化的自然风化机理和人为活动影响评估
· 环境地球化学：利用多元素的稳定同位素探究流域物质生物地球化学循环过程和机理以及全球变化意义
· 地球关键带：中国西南喀斯特关键带生源要素生物地球化学过程和水碳氮硫耦合






个人简介 李思亮，天津大学讲席教授，博士生导师，国家****科学基金获得者（2019）。
从事流域生物地球化学循环与生态环境效应研究，基于多种稳定同位素方法在山地河流进行研究，为流域风化和地表过程研究获得新的认识。目前已发表论文120余篇，SCI论文70余篇，分别在JGR、GCA、EPSL、EST、Nature Comm等国际知名期刊上发表，参编专著三部。作为中国代表受到国际原子能机构邀请和资助，参加了全球河流同位素研究专家研讨会（GNIR – Global Network of Isotopes in Rivers）。作为召集人或学术秘书组织国际学术会议多次，同时多次在国际学术会议或国内外研究机构作邀请报告。国家自然科学基金委“****科学基金”和“优秀青年科学基金”项目获得者，另外承担中英合作交流项目（等同重点基金）和科技部研发计划项目课题，天津市****基金项目，国际原子能机构项目等多项。获“第17届侯德封矿物岩石地球化学青年科学家”荣誉称号，现为第九届环境地质地球化学专业委员会，第四纪生物地球化学循环专业委员会委员，天津地理学会理事。TOP杂志Agric Ecosyst Environ客座编辑，Frontiers In Water, 《中国岩溶》编委会成员。

学术成果
论文成果
[1]Xu S, Li S-L*, Zhong J, Li C. 2020. Spatial scale effects of the variable relationships between landscape pattern and water quality: Example from an agricultural karst river basin, Southwestern China. Agriculture, Ecosystems and Environment 300:106999.

[2]Zeng J, Yue F-J*, Li S-L, Wang ZJ, Wu Q, Qin C, Yan Z. 2020. Determining rainwater chemistry to reveal alkaline rain trend in Southwest China: Evidence from a frequent-rainy karst area with extensive agricultural production. Environmental Pollution 266:115166.

[3]Zeng J, Yue F-J*, Li S-L, Wang ZJ, Wu Q, Qin C, Wu QX, Xu,S. 2020. Agriculture driven nitrogen wet deposition in a karst catchment in southwest China. Agriculture, Ecosystems & Environment, 294:10688.

[4]Liu Y, Yue J, Yue FJ, Li S-L, Wang BL, Mohinuzzaman M, Yang X, Senesi N, Lao X, Li L, Liu C-Q, Ellam R, Mostofa K*. 2020b. New insights into mechanisms of sunlight-mediated high-temperature accelerated diurnal production-degradation of fluorescent DOM in lake waters. DOI:10.5194/bg-2020-145

[5]Peters M, Guo Q, Strauss H, Wei R, Li S-L, Yue F. 2020. Seasonal effects on contamination characteristics of tap water from rural Beijing: A multiple isotope approach. Journal of Hydrology 588:125037.

[6]Zhang Z, Chen X*, Cheng Q, Li S-L, Soulsby C. 2020. Coupled hydrological and biogeochemical modelling of nitrogen transport in the karst critical zone. Science of the Total Environment 732:138902.

[7]Han X, Guo Q, Lang Y, Li S-L, Li, Y, Guo, Z, Hu, J, Wei, R, Tian, L, Wan, Y. 2020. Seasonal and long-term trends of sulfate, nitrate, and ammonium in PM 2.5 in Beijing: implication for air pollution control. Environmental Science and Pollution Research 27: 23730-23741.

[8]Liu J, Zhong J*, Ding H, Yue F-J, Li C, Xu S, Li S-L. 2020a. Hydrological regulation of chemical weathering and dissolved inorganic carbon biogeochemical processes in a monsoonal river. 34:2780-2792.

[9]Ma T, Weynell M, Li S-L*, Liu Y, Chetelat B, Zhong J, Xu S, Liu C-Q. 2020. Lithium isotope compositions of the Yangtze River headwaters: Weathering in high-relief catchments. Geochimica Et Cosmochimica Acta 280:46-65.

[10]Qin C, Li S-L*, Waldron S, Yue FJ, Wang ZJ, Zhong J, Hu D, Liu CQ. 2020. High-frequency monitoring reveals how hydrochemistry and dissolved carbon respond to rainstorms at a karstic critical zone, Southwestern China. Science of the Total Environment 714:136833.

[11]Piao HC, Li S-L*, Yan Z, Cai L. Understanding nutrient allocation based on leaf nitrogen isotopes and elemental ratios in the karst region of Southwest China. Agriculture Ecosystems and Environment 294:106864.

[12]Mohinuzzaman M, Yuan J, Yang X, Senesi N, Li S-L, Ellam RM, Mostofa KMG, Liu C-Q. 2020. Insights into solubility of soil humic substances and their fluorescence characterisation in three characteristic soils. Science of the Total Environment:137395.

[13]Davidson C, Geophrey A, Ganyaglo SY, Appiah-Adjei EK, Li S-L. 2019. Nitrate contamination of groundwater in the Lower Volta River Basin of Ghana: Sources and related human health risks. European Geosciences Union General Assembly, 2019.

[14]Qi Y, Fu P, Li S-L, Ma C, Liu C, Volmer DA. 2020. Assessment of molecular diversity of lignin products by various ionization techniques and high-resolution mass spectrometry. Science of the Total Environment 713:136573.

[15]Wang ZJ, Li S-L*, Yue FJ*, Qin C, Zeng J. 2019b. Rainfall driven nitrate transport in agricultural karst surface river system: Insight from high resolution hydrochemistry and nitrate isotopes. Agriculture, Ecosystems and Environment 291:106787.

[16]Wang W-F, Li S-L*, Zhong J, Maberly SC, Li C, Wang F-S, Xiao H-Y, Liu C-Q. 2020. Climatic and anthropogenic regulation of carbon transport and transformation in a karst river-reservoir system. Science of the Total Environment 707:135628.

[17]Chen BB, Li S-L*, Strandmann PAEPV, Sun J, Liu CQ. 2019. Ca isotope constraints on chemical weathering processes: Evidence from headwater in the Changjiang River, China. Chemical Geology 531:119341.

[18]Buckerfield SJ, Quilliam RS, Waldron S, Naylor LA, Li S-L, Oliver DM. 2019a. Rainfall-driven E. coli transfer to the stream-conduit network observed through increasing spatial scales in mixed land-use paddy farming karst terrain. Water Research 5:100038.

[19]Fadhullah W, Yaccob NS, Syakir MI, Muhammad SA, Li S-L. 2019. Nitrate sources and processes in the surface water of a tropical reservoir by stable isotopes and mixing model. Science of the Total Environment 700:134517.

[20]Li C, Li S-L*, Yue F-J, He S, Shi Z-B, Di C, Liu C-Q. 2019a. Nitrate sources and formation of rainwater constrained by nitrate isotopes in Southeast Asia: Example from Singapore. Chemosphere 241:125024.

[21]Zeng J, Yue F-J, Wang Z-J, Wu Q, Qin C-Q, Li S-L. 2019. Quantifying depression trapping effect on rainwater chemical composition during the rainy season in karst agricultural area, southwestern China. Atmospheric Environment 218:116998.

[22]Liang X, Xing T, Li J, Wang B, Li S-L. 2019. Control of the Hydraulic Load on Nitrous Oxide Emissions from Cascade Reservoirs. Environmental Science Technology 53:11745-11754.

[23]Di C, Wang TJ, Istanbulluoglu E, Jayawardena AW, Li S-L, Chen X. 2019. Deterministic chaotic dynamics in soil moisture across Nebraska. Journal of Hydrology 578:124048.

[24]Yue FJ, Waldron S, Li S-L*, Wang ZJ, Oliver DM. 2019. Land use interacts with changes in catchment hydrology to generate chronic nitrate pollution in karst waters and strong seasonality in excess nitrate export. Science of the Total Environment 696:134062.

[25]Davidson C, Geophrey A, Ganyaglo SY, Appiah-Adjei EK, Li S-L. 2019. Nitrate contamination of groundwater in the Lower Volta River Basin of Ghana: Sources and related human health risks. European Geosciences Union General Assembly, 2019.

[26]Matiatos I, Wassenaar LI, Douence, C, Alonso-Hernandez C, Welti N, Li S-L, et al. 2019. The IAEA coordinated research project on Isotopes to study nitrogen pollution and eutrophication of Rivers and Lakes. International Symposium on Isotope Hydrology:20–24

[27]Qin C, Li S-L*, Yue F, Xu S, Ding H*. 2019. Spatiotemporal variations of dissolved inorganic carbon and controlling factors in a small karstic catchment, Southwestern China. Earth Surface Processes Landforms.

[28]Wang W, Li S-L*, Zhong J, Li C, Yi Y, Chen S, Ren Y. 2019a. Understanding transport and transformation of dissolved inorganic carbon (DIC) in the reservoir system using δ13CDIC and water chemistry. Journal of Hydrology.

[29]Bai L, Liu XL, Hu J, Li J, Wang ZL, Han G, Li S-L, Liu CQ. 2018. Heavy Metal Accumulation in Common Aquatic Plants in Rivers and Lakes in the Taihu Basin. Int J Environ Res Public Health 15:2857.

[30]Yan Z, Wang T, Wang L, Yang X, Smith P, Hilpert M, Li S-L, Shang J, Bailey V, Liu C. 2018b. Microscale water distribution and its effects on organic carbon decomposition in unsaturated soils. Science of the Total Environment 644:1036-1043.

[31]Yan Z, Bond-Lamberty B, Todd-Brown KE, Bailey VL, Li S-L, Liu C, Liu C. 2018a. A moisture function of soil heterotrophic respiration that incorporates microscale processes. Nature communications 9:2562-2562.

[32]Peters M, Guo Q, Strauss H, Wei R, Li S-L, Yue F. 2019. Contamination patterns in river water from rural Beijing: A hydrochemical and multiple stable isotope study. Science of the Total Environment 654:226-236.

[33]Yaccob S, Syakir MI, Muhammad SA, Hashim Z, Rahman A, Yue F-J, Li S-L, Fadhullah W. 2018. Application of Nitrate Stable Isotopes, δ15N-NO3- and δ18O-NO3-, in Bukit Merah Reservoir, Malaysia. Journal of Physical Science 29:1-6.

[34]Wang ZJ, Yue FJ*, Li S-L, Li XD, Wang SL, Li C, Tao FX, Impacts. 2018. Nitrate dynamics during impoundment and flood periods in a subtropical karst reservoir: Hongfeng Lake, Southwestern China. Environmental Science: Processes Impacts.

[35]Di C, Wang T, Yang X, Li S-L. 2018. Technical note: An improved Grassberger–Procaccia algorithm for analysis of climate system complexity. Hydrology and Earth System Science. 22:5069-5079.

[36]Jing K, Guo Q, Wei R, Strauss H, Zhu G, Li S-L, Song Z, Chen T, Song B, Zhou T. 2018. Contamination of heavy metals and isotopic tracing of Pb in surface and profile soils in a polluted farmland from a typical karst area in southern China. Science of the Total Environment s 637–638:1035-1045.

[37]Zhong J, Li S-L*, Liu J, Ding H, Sun X, Xu S, Wang T, Ellam RM, Liu C-Q. 2018. Climate variability controls on CO2 consumption fluxes and carbon dynamics for monsoonal rivers: evidence from Xijiang river, Southwest China. 123:2553-2567.

[38]Piao H, Li S-L*, Yan Z. 2018. The partitioning patterns of nutrients between pods and seeds of Zanthoxylum fruits impacted by environmental factors. Acta Geochimica 37:676-683.

[39]Li C, Li S-L*, Yue FJ, Liu J, Zhong J, Yan ZF, Zhang RC, Wang ZJ, Xu S. 2019. Identification of sources and transformations of nitrate in the Xijiang River using nitrate isotopes and Bayesian model. Science of the Total Environment 646:801-810.

[40]Buckerfield SJ, Waldron S, Quilliam RS, Naylor LA, Li S-L, Oliver DM. 2019b. How can we improve understanding of faecal indicator dynamics in karst systems under changing climatic, population, and land use stressors? Research opportunities in SW China. Science of the Total Environment 646:438-447.

[41]Liu X-L, Li S-L*, Wang Z-L, Wang B-L, Han G-L, Wang F-S, Bai L, Xiao M, Yue F-J, Liu C-Q. 2018. Sources and key processes controlling particulate organic nitrogen in impounded river–reservoir systems on the Maotiao River, southwest China. Inland Waters 8:167-175.

[42]Jun Zhong, Si-Liang Li*, Hu Ding, Yunchao Lang, Stephen C. Maberly, Sheng Xu，2018, Mechanisms controlling dissolved CO2 over-saturation in the Three Gorges Reservoir area. Inland Waters.

[43]Fu-Jun Yue, Si-Liang Li*, Cong-Qiang Liu, Khan M.G. Mostofa, Naohiro Yoshida, Sakae Toyoda, Shi-Lu Wang, Xiao-Long Liu, 2018, The Spatial Variation of Nitrogen Cycling in a Subtropical Stratified Dam Lake in SW China, Elucidated by Nitrous Oxide Isotopomer and Nitrate Isotopes. Inland Waters (Accepted).

[44]Fu-Jun Yue, Si-Liang Li*, Jun Zhong, and Jing Liu, 2018, Evaluation of Factors Driving Seasonal Nitrate Variations in Surface and Underground Systems of a Karst Catchment, Vadose Zone J. 17:170071. doi:10.2136/vzj2017.04.0071

[45]Fu-Jun Yue, Si-Liang Li*, Cong-Qiang Liu*, Zhi-Qi Zhao, Hu Ding, 2017, Tracing nitrate sources with dual isotopes and long term monitoring of nitrogen species in the Yellow River, China. Scientific Reports: 7: 8537, DOI:10.1038/s41598-017-08756-7.

[46]Jun Zhong, Si-Liang Li*, Faxiang Tao, Fujun Yue, Cong-Qiang Liu. 2017. Sensitivity of chemical weathering and dissolved carbon dynamics to hydrological conditions in a typical karst river. Scientific Reports: DOI: 10.1038/srep42944.

[47]Jun Zhong，Si-Liang Li*，Faxiang Tao，et al., 2017. Impacts of hydrologic variations on chemical weathering and solute sources in the Min River basin, Himalayan-Tibetan region. Environmental Science and Pollution Research. DOI: 10.1007/s11356-017-9584-2.

[48]Piao H, Li SL*, Wang S, Li S, 2017，The preference of nitrate uptake in Chinese prickly ash estimated by δ15N values and cation concentrations. Environ Earth Sci: 76:87 DOI 10.1007/s12665-017-6407-1

[49]Liu J, Li SL*, Chen J-B, et al. 2017，Temporal transport of major and trace elements in the upper reaches of the Xijiang River, SW China.

[50]Yue F-J, Li S-L*, Liu C-Q, Lang Y-C, Ding H, 2015. Sources and transport of nitrate constrained by the isotopic technique in a karst catchment: an example from Southwest China. Hydrol. Process. 29, 1883-1893.

[51]Yue F-J, Liu C-Q*, Li S-L*, Zhao Z-Q, Liu X-L, Ding H, Liu B-J, Zhong J, 2014. Analysis ofδ15N and δ18O to identify nitrate sources and transformations in Songhua River, Northeast China. J. Hydrol. 519: 329–339.

[52]Li S-L, Chetelat B, Yue F-J, Zhao Z, Liu C-Q, 2014. Chemical weathering processes in the Yalong River draining the eastern Tibetan Plateau, China. J. Asian Earth Sci. 88: 74–84.

[53]Yue, F.-J., Li S-L*, Liu C-Q, et al., 2013, Using dual isotopes to evaluate sources and transformation of nitrogen in the Liao River, northeast China. Appl. Geochem., 36: 1-9.

[54]Li S-L, Liu C-Q, Li J., et al., Evaluation of nitrate source in surface water of southwestern China based on stable isotopes. Environmental Earth Sciences, 2013，68：219-228.

[55]Li S-L, Liu C-Q, Patra S., et al., 2011, Using a dual isotopic approach to trace sources and mixing of sulphate in Changjiang Estuary, China. Applied Geochemistry, 26: s210-s213.

[56]Li S-L, Liu C-Q, Li J, Lang Y-C, Ding H, Li L, 2010. Geochemistry of dissolved inorganic carbon and carbonate weathering in a small typical karstic catchment of Southwest China: Isotopic and chemical constraints. Chemical Geology, 277: 301-309.

[57]Li S-L, Liu C-Q, Li J, Liu X, Chetelat B, Wang B, Wang F, 2010. Assessment of the sources of nitrate in the Changjiang River, China using a nitrogen and oxygen isotopic approach. Environmental Science and Technology, 44: 1573-1578.

[58]Li S-L, Liu C-Q, Lang Y-C, 2010. Tracing the sources of nitrate in karstic groundwater in Zunyi, Southwest China: a combined nitrogen isotope and water chemistry approach, Environmental Earth Sciences, 60: 1415-1423

[59]Li S-L, Calmels D, Han G, Gaillardet J, Liu C-Q, 2008. Sulfuric acid as an agent of carbonate weathering constrained by d13CDIC: Examples from Southwest China. Earth and Planetary Science Letters, 170: 189-199.

[60]Li S-L, Liu C-Q, Lang Y-C, Tao F, Zhao Z, Zhou Z, 2008. Stable carbon isotope biogeochemistry and anthropogenic impacts on karst ground water, Zunyi, Southwest China. Aquatic Geochemistry, 14: 211-221

[61]Li S-L, Liu C-Q, Tao F-X, Lang Y-C, Han G, 2005. Carbon biogeochemistry of ground water, Guiyang, Southwest China. Ground Water，43: 494-499

[62]Liu J, Li SL*, Zhong J, et al. 2017，Sulfate sources constrained by sulfur and oxygen isotopic compositions in the upper reaches of the Xijiang River, Southwest China. Acta Geochimica. 36(4): 611–618.

[63]Piao H, Li SL*, Wang S, 2016，Nutrient uptake by mulberry and Chinese prickly ash associated with arbuscular mycorrhizal fungi. Acta Geochim, 35(2):120–129.

[64]Xiaolong Liu*, Siliang Li*, Zhongliang Wang, Guilin Han, Jun Li, Baoli Wang, Fushun Wang, Li Bai, 2017, Nitrous oxide (N2O) emissions from a mesotrophic reservoir on the Wujiang River, southwest China. Acta Geochim, 36(4):667–679.

[65]Li S-L, Yue F-J, Liu C-Q, Ding H, Zhao Z-Q, Li X. 2015. The O and H isotope characteristics of water from major rivers in China. Chin. J. Geochem., 34(1): 28–37.

[66]Liu C-Q, Li S-L, Lang Y-C, and Xiao H-Y, 2006. Using d15N and d18O values to identify nitrate sources in karst ground water, Guiyang, Southwest China. Environmental Science and Technology, 40: 6928-6933

[67]Yue F-J, Li S-L, Hu J, 2015. The Contribution of Nitrate Sources in Liao Rivers, China, Based on Isotopic Fractionation and Bayesian Mixing Model. Procedia Earth and Planetary Science, 13, 16 – 20.

[68]Jun Zhu, Siliang Li, Yuchun Wang, Haiyu Yan, Limin Liao, Jun Zhong, 2017, Spatial characters of nutrients in Wujiangdu Reservoir in karst river, SW China. Acta Geochim, 36(4): 605–610.

[69]Jianchao Zhang, Jian Xiao, Siliang Li, Wei Ran. Manure amendment increases the content of nanomineral allophane in an acid arable soil, Scientific Reports, 2017, 7, 14256.

[70]Yan Zhifeng, S. Li, X. Yang, and M. Hilpert. 2017, Two-Relaxation-Time Lattice Boltzmann Method and its Applications to Advective-Diffusive-Reactive Transport. Advanced in Water Resources. 109:333-342

[71]Zhong-JunWang, Fu-Jun Yue, Jie Zeng, Si-Liang Li, 2017, The influence of urbanization on karst rivers based on nutrient concentration and nitrate dual isotopes: an example from southwestern China. Acta Geochim, 36(3):446–45.

[72]Jian Hu, Congqiang Liu, Qingjun Guo, Junxin Yang, Chukwunonso Peter Okoli, Yunchao Lang, Zhiqi Zhao, Siliang Li, Baojian Liu, Guangwei Song, 2017, Characteristics, source, and potential ecological risk assessment of polycyclic aromatic hydrocarbons (PAHs) in the Songhua River Basin, Northeast China. Environmental Science and Pollution Research, 24(20): 17090–17102.

[73]Ding, H; Liu, CQ; Zhao, ZQ; Li, SL; Lang, YC; Li, XD; Hu, J ; Liu, BJ，2017，Geochemistry of the dissolved loads of the Liao River basin in northeast China under anthropogenic pressure: Chemical weathering and controlling factors，Journal Of Asian Earth Sciences，138: 657-671.

[74]Jian Hu, Congqiang Liu, Guoping Zhang, Siliang Li, Zhiqi Zhao, Baojian Liu, Qinjun Guo, 2016, Distribution characteristics and source apportionment of polycyclic aromatic hydrocarbons (PAHs) in the Liao River drainage basin, northeast China. Environ Monit Assess, 188:277, DOI 10.1007/s10661-016-5123-8.

[75]Xiao-Long Liu, Li Bai, Zhong-Liang Wang, Jun Li, Fu-Jun Yue, Si-Liang Li. 2015. Nitrous oxide emissions from river network with variable nitrogen loading in Tianjin, China. Journal of Geochemical Exploration. 157: 153–161

[76]Wang Q-L, Chetelata B, Zhao Zhi-Qi, Ding H, Li S-L, Wang B, Li J, Liu X-L, 2015. Behavior of Lithium isotopes in the Changjiang River system: Sources effects and response to weathering and erosion. Geochimica et Cosmochimica, 151, 117-132.

[77]Wang Baoli, Liu Congqiang, Wang Fushun, Li Siliang, Sivaji Patra1, 2014, Distributions of Picophytoplankton and Phytoplankton Pigments Along a Salinity Gradient in the Changjiang River Estuary, China. J. Ocean Univ. China, 13(4): 621-627.

[78]Liu, Baojian; Liu, Cong-Qiang; Zhang, Gan; Zhao, Zhi-Qi; Li, Si-Liang; Hu, Jian; Ding, Hu; Lang, Yun-Chao; Li, Xiao-Dong. 2013, Chemical weathering under mid- to cool temperate and monsoon-controlled climate: A study on water geochemistry of the Songhuajiang River system, northeast China. Applied Geochemistry, 31: 265-278.

[79]Patra S, Liu C-Q, Wang F, Li S, Wang B，2012，Behavior of major and minor elements in a temperate river estuary to the coastal sea，Int. J. Environ. Sci. Technol，9, 647–654.

[80]Tao F-X, Liu C-Q, Li S-L, 2009. Source and flux of POC in two subtropical karstic tributaries with contrasting land use practice in the Yangtze River Basin. Applied Geochemistry. 24: 2102-2112

[81]Liu X-L, Liu C-Q, Li S-L, Wang F-S, Wang B-L, Wang Z-L., 2011, Spatiotemporal variations of nitrous oxide(N2O) emissions from two reservoirs in SW China. Atmospheric Environment, 45: 5458-5468

[82]Lang Y-C, Liu C-Q, Li S-L, Zhao Z-Q, Zhou Z-H, Tracing natural and anthropogenic sources of dissolved sulfate in a karst region by using major ion chemistry and stable sulfur isotopes. Applied Geochemistry 2011, 26: s202-s205.

[83]Li X-D, Liu C-Q, Harue M, Li S-L, Liu X-L, 2010. The use of environmental isotopic (C, Sr, S) and hydrochemical tracers to characterize anthropogenic effects on karst groundwater quality: A case study of the Shuicheng Basin, SW China. Applied Geochemistry, 25: 1924-1936

[84]Lang Y-C, Liu C-Q, Zhao Z-Q, Li S-L, Han G-L, 2006. Geochemistry of surface and ground water in Guiyang, China: Water/rock interaction and pollution in a karst hydrological system. Applied Geochemistry, 21: 887-903

[85]Liu C-Q, Lang Y-C, Satake H, Wu J, Li S-L, 2008. Identification of Anthropogenic and Natural Inputs of Sulfate and Chloride into the Karstic Ground Water of Guiyang, SW China: Combined δ37Cl and δ34S Approach. Environmental Science and Technology, 42: 5421-5427

[86]Chetelat B, Liu C-Q, Zhao ZQ, Wang QL, Li S-L, Li J, Wang BL, 2008. Geochemistry of the dissolved load of the Changjiang Basin rivers: Anthropogenic impacts and chemical weathering. Geochimica et Cosmochimica Acta, 72: 4254-4277

[87]Liu B, Liu C-Q, Zhang B,?Zhao Z,? Li S-L,?Hu J,?Hu Ding, Y-C Lang,?X-D Li, 2013, Chemical weathering under mid- to cool temperate and monsoon-controlled climate: A study on water geochemistry of the Songhuajiang River system, northeast China, Applied Geochemistry, 31:265–278

[88]Yu YuanXiu, Liu Cong-Qiang, Wang FuShun, Wang BaoLi, Li Jun, Li Si-Liang，2008，Dissolved inorganic carbon and its isotopic differentiation in cascade reservoirs in the Wujiang drainage basin，Chinese Science Bulletin, 53(21), 3371-3378

[89]高蝶,陈赛男,李思亮,刘小龙,李军,白莉,杨静,王中良.峡谷型水库温度分层期关键界面N2O的产生和释放机理[J/OL].生态学杂志:1-12[2020-08-09].https://doi.org/10.13292/j.1000-4890.202008.007.

[90]王万发,钟君,李彩,易沅壁,陈赛男,陈率,郎赟超,李思亮.喀斯特地区梯级水库建造对水化学分布的影响[J].湖泊科学,2020,32(03):713-725.

[91]陈率,钟君,李彩,王万发,徐森,颜泽龙,李思亮.西南不同岩性混合小流域化学风化特征[J].生态学杂志,2020,39(04):1288-1299.

[92]张雨童,张若纯,李彩,孙佩哲,杨艳文,冀豪栋,刘文,李思亮.表层水体中典型小分子有机氮的光铵化反应[J].生态学杂志,2020,39(03):900-908.

[93]颜泽龙,韩晓昆,岳甫均,钟君,王忠军,曾杰,李思亮.西南喀斯特农业区大气降水化学及硫同位素组成特征[J].地球与环境,2019,47(06):811-819.

[94]任奕蒙,岳甫均,徐森,陈赛男,王忠军,李思亮.利用氮氧同位素解析赤水河流域水体硝酸盐来源及其时空变化特征[J].地球与环境,2019,47(06):820-828.

[95]代义彬,郎赟超,王铁军,李思亮,王礼春.SPARROW模型及其应用研究进展[J].地球与环境,2019,47(03):397-404.

[96]李思亮,钟君,李彩,刘静,岳甫均,任奕蒙,徐森.中国西南河流碳、氮运移机制及其对水文条件变化的响应:以西江为例[J].矿物岩石地球化学通报,2019,38(03):499-507+438.

[97]曾杰,王忠军,岳甫均,李思亮,吴起鑫,刘涛泽,司霞莉.喀斯特洼地湿沉降氮形态及硝酸盐同位素组成的垂向分布特征[J].生态学杂志,2018,37(11):3422-3429.

[98]付玉聪,郎赟超,王忠军,李思亮,丁虎.夏季石灰土CO_2昼夜动态及其影响因素[J].生态学杂志,2018,37(11):3315-3322.

[99]刘静,李思亮,钟君,丁虎.西江上游河水中硫酸盐来源及其对化学风化的影响[J].生态学杂志,2018,37(03):714-722.

[100]徐森, 李思亮, 钟君, 苏靖, 陈率，2018，赤水河流域水化学特征与岩石风化机制，生态学杂志, 1-15[2018-02-07].

[101]夏妍梦, 李彩, 李思亮, 狄崇利, 岳甫均, 彭慧，2018，天津海河氮动态变化对夏季强降雨的响应过程，生态学杂志, 1-10[2018-02-07].

[102]周苗, 李思亮, 丁虎, 覃蔡清, 岳甫均，2018，地表流域有机碳地球化学研究进展，生态学杂志, 1-11[2018-0207].

[103]李思亮, 刘丛强, 丁虎, 韩贵琳，2012，δ13C-DIC在河流风化和碳生物地球化学过程中的应用，地球环境学报, 3(4), 929-935

[104]岳甫均, 李思亮, 刘丛强, 安宁, 蔡虹明，2012，利用反硝化细菌法测试水体硝酸盐氮氧同位素 ，生态学杂志, 08, 2152-2157

[105]李思亮, 刘丛强, 肖化云, 陶发祥, 郎赟超, 韩贵琳，2005，δ15N在贵阳地下水氮污染来源和转化过程中的辨识应用，地球化学, 34(3), pp 257-262

[106]李思亮, 刘丛强, 肖化云，2002，地表环境氮循环过程中微生物作用及同位素分馏研究综述，地质地球化学, 30(4), pp 40-45

[107]司霞莉, 岳甫均, 王忠军, 曾杰, 贾国栋, 钟君, 李思亮，2018，深水湖泊沉积物不同形态氮的生物地球化学特征——以百花湖为例，生态学杂志:133. -10[2018-02-07].https://doi.org/10.13292/j.1000-4890.201803.033.（网络出版）

[108]吕鑫, 刘小龙, 李军, 白莉, 李思亮, 王宝利, 王中良，2018，河流拦截背景下水库氧化亚氮(N2O)排放的研究进展[J/OL]，生态学杂志:1-14[2018-02-07].https://doi.org/10.13292/j.1000-4890.201803.025. （网络出版）

[109]徐森, 狄崇利, 李思亮，2017，典型喀斯特流域降水与径流特征分析及径流年际变化的影响因素贡献分解，第四纪研究, 37(6) , 1238-1250.

[110]曾杰, 吴起鑫, 李思亮, 岳甫均，2017，雨季喀斯特小流域氮输出特征及其受降雨的影响，水土保持学报,?31(3), 73-78.

[111]丁虎, 刘丛强, 郎赟超, 李思亮, 李晓东, 汪福顺，2015，河流水-气界面碳交换研究进展及趋势，上海大学学报(自然科学版),?21(3), 275-285.

[112]刘小龙, 汪福顺, 白莉, 李思亮, 王宝利, 刘丛强，2015，河流梯级开发对乌江中上游水体溶存N2O释放的影响，上海大学学报(自然科学版), 21(3), 301-310.

[113]刘宝剑, 赵志琦, 李思亮, 刘丛强, 张干, 胡健，2013，寒温带流域硅酸盐岩的风化特征——以嫩江为例，生态学杂志,?32(4), 1006-1016.

[114]张岩林, 胡健, 刘宝剑, 李思亮, 灌瑾，2012，辽河流域多环芳烃(PAHs)的分布特征及来源解析，地球与环境, 02，188-194

[115]李军, 刘丛强, 李龙波, 李思亮, 王宝利, B.CHETELAT ，2010，硫酸侵蚀碳酸盐岩对长江河水DIC循环的影响，地球化学, 39(04), pp 305-313

[116]Sivaji Patra, 刘丛强, 李思亮, 王宝利, 汪齐连，2010，长江口溶解无机碳循环的地球化学研究，地球与环境, 38(04), pp 309-413

[117]刘小龙, 刘丛强, 李思亮, 李晓东，2010，碳与锶同位素在六盘水地下水研究中的应用，生态学杂志, 29(05), 978-984

[118]刘丛强, 郎赟超, 李思亮, 朴何春, 涂成龙, 刘涛泽, 张伟, 朱书法，2009，喀斯特生态系统生物地球化学过程与物质循环研究:重要性、现状与趋势，地学前缘, 16(06), pp 1-12

[119]李干蓉, 刘丛强, 陈椽, 王宝利, 李军, 李思亮, 刘小龙, 汪福顺，2009，猫跳河流域梯级水库夏-秋季节溶解无机碳(DIC)含量及其同位素组成的分布特征，环境科学, 30(10), 2891-2897

[120]韩志伟, 刘丛强, 吴攀, 汪福顺, 王宝利, 李思亮, 灌瑾，2009，大坝拦截对河流水溶解组分化学组成的影响分析——以夏季乌江渡水库为例，长江流域资源与环境, 18(04), 361-367.

[121]刘小龙, 刘丛强, 李思亮, 汪福顺, 王宝利, 灌瑾, 杨妍，2009，猫跳河流域梯级水库夏季N2O的产生与释放机理，长江流域资源与环境, 18(04), 373-378

[122]郎赟超, 刘丛强, Satake H, 李思亮，2008，贵阳地表水—地下水的硫和氯同位素组成特征及其污染物示踪意义，地球科学进展, 23(2), 151-159.

[123]喻元秀, 刘丛强, 汪福顺, 王宝利, 李军, 李思亮，2008，乌江流域梯级水库中溶解无机碳及其同位素分异特征，科学通报, 53(16), 1935-1941

[124]刘丛强, 蒋颖魁, 陶发祥, 郎赟超, 李思亮，2008，西南喀斯特流域碳酸盐岩的硫酸侵蚀与碳循环，地球化学, 37(04), 404-414

[125]朱俊, 刘丛强, 王雨春, 李思亮,, 李军，2006，乌江渡水库中溶解性硅的时空分布特征，水科学进展, 17(3), 330-333

[126]郎赟超, 刘丛强, 韩贵琳, 赵志琦, 李思亮，2005，贵阳市区地表/地下水化学与锶同位素研究，第四纪研究, 25(5), 655-662.

[127]郎赟超, 刘丛强, 赵志琦, 李思亮, 韩贵琳，2005，贵阳市地表水地下水化学组成:喀斯特水文系统水-岩反应及污染特征，水科学进展, 16(6), 826-832.

[128]肖化云, 刘丛强, 王仁禄, 李思亮，2003，硝化和反硝化对湖泊有机质沉积成岩前降解作用的研究 ，地球化学, 32(4), 375-381

[129]肖化云, 刘丛强, 李思亮，2003，贵阳地区夏季雨水硫和氮同位素地球化学特征，地球化学, 32(3), 248-254

[130]肖化云, 刘丛强, 李思亮, 王仕禄，2002，强水动力湖泊夏季分层期氮的生物地球化学循环初步研究：以贵州红枫湖南湖为例 ，地球化学, 31(6), 571-576.

[131]吴攀, 刘丛强, 杨元根, 张国平, 李思亮，2002，土法炼锌废渣堆中的重金属及其释放规律，中国环境科学, 22(2), 109-113.







奖励与荣誉
1. 2019 国家****科学基金获得者
2. 2018 第17届侯德封矿物岩石地球化学青年科学家
3. 2014 国家优秀青年科学基金获得者



团队
流域生物地球化学循环研究中? 本中心重点基于多学科交叉和表层地球系统科学理论，以流域中水土气生为重要研究介质，结合观测、实验和模型来解译流域物质生物地球化学循环规律、关键过程和生态环境效应，推动联合、综合和交叉研究，增加表层地球系统物质生物地球化学循环新认识，服务人类社会可持续发展。本中心通过流域系统理论教育、室内外物理、化学和生物实验、多维度模型构建和国际化多元开放合作，培养流域环境和生态保护的复合研究型和综合管理型人才。

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