黄天明，1982年出生于宁夏固原，研究员，博士生导师，中国科学院页岩气与地质工程重点实验室副主任，水文地质与地热资源学科组组长，中国科学院大学地球与行星科学学院水文地质与地热资源教研室主任。主要从事水循环与水岩气相互作用研究。已发表学术论文90余篇，其中以第一作者在JGR、GRL、JH、HP、HJ等SCI期刊上发表论文22篇，被SCI引用630余次；以通讯作者在GRL、HP、Catena等SCI期刊上发表论文12篇。任中国水利学会地下水科学与工程专委会副主任委员、国际水文科学协会中国委员会同位素分委员会委员兼秘书长、中国地质学会勘查地球化学专委会、环境地质专委会委员；任Frontiers in Earth Science副主编，Journal of Groundwater Science and Engineering、工程地质学报等期刊编委。 

　　学习工作经历： 

• 本科（2000.09-2004.06）：水文与水资源工程，兰州大学
• 硕士（2004.09-2007.06）：水文学及水资源，兰州大学
• 博士（2008.03-2010.11）：水文地质，中国科学院地质与地球物理研究所
• 博士后（2010.11-2012.12）：中国科学院地质与地球物理研究所
• 副研究员（2013.01-2021.12）：中国科学院地质与地球物理研究所
• 访问学者（2019.08-2020.08）：加拿大University of Calgary
• 研究员（2021.12至今）：中国科学院地质与地球物理研究所

　　主要学术成果：
　　利用同位素和水化学手段，刻画了气候变化和人类活动影响下地下水补给变化过程，揭示了人类活动影响下水化学变化机制，刻画了水力压裂中水循环规律和地球化学过程以及相应的水环境效应。在同位素水文学理论与技术方法方面，揭示了吸附-解吸附和离子交换作用对同位素示踪的影响；提出了利用氘盈余确定水体盐化机理的方法；构建了一种地下水C-14年龄校正模型；改进了水汽再循环氘盈余示踪模型。

• 水循环同位素示踪与年代学
• 水-岩-气相互作用与碳储热储工程和监测
• 地下水补给与演化
• 岩浆挥发分与高温地热成因机制

• 中国科学院青年创新促进会会员
• 中国自然资源学会青年科技奖
• 国际水岩相互作用（WRI）GMZ Scholarship
• 甘肃省水利科技进步一等奖

• 国家自然科学基金常规面上项目，编号：42172277
• 国家自然科学基金常规面上项目，编号：41877207
• 中国科学院战略性先导科技专项子课题，编号：XDB10030603
• 国家自然科学基金常规面上项目，编号：41672254
• 国家自然科学基金青年基金项目，编号：41202183
• 中国博士后科学基金特别资助项目，编号：2012T50136
• 中国博士后科学基金面上资助项目，编号：20110490581
• 国家/部委重点实验室开放基金项目
• 中国地质科学院矿产资源研究所项目

[Google Scholar]

• Huang T, Li Z, Long Y, Zhang F, Pang Z (2022) Role of desorption-adsorption and ion exchange in isotopic and chemical (Li, B, and Sr) evolution of water following water–rock interaction. Journal of Hydrology 610, 127800, https://doi.org/10.1016/j.jhydrol.2022.127800
• Li Z, Huang T*, Wang G*, Long Y, Zhang F, Pang Z (2022) A conceptual model for correcting groundwater 14C age. Applied Geochemistry 143, 105360, https://doi.org/10.1016/j.apgeochem.2022.105360
• Long Y, Huang T*, Zhang F, Zhao Y (2022) Soil column experimental study on the effect of soil structure disturbance on water chemistry. International Journal of Environmental Research and Public Health 19, 15673, https://doi.org/10.3390/ijerph192315673
• Zhang Y*, Sun X, Huang T*, Qi S, Fu L-Y, Yang Q-Y, Hu J, Zheng B, Zhang W (2022) Possible continuous vertical water leakage of deep aquifer: Records from a deep well in Tianjin Province, North China. Geofluids 2022, 4419310, https://doi.org/10.1155/2022/4419310
• Zhang Y*, Huang T* (2022) DNA-based tracers for the characterization of hydrogeological systems—recent advances and new frontiers. Water 14, 3545, https://doi.org/10.3390/w14213545
• Zhang F, Huang T*, Man W, Hu H, Long Y, Li Z, Pang Z (2021) Contribution of recycled moisture to precipitation: A modified d-excess-based model. Geophysical Research Letters 48, e2021GL095909, https://doi.org/10.1029/2021GL095909
• Long Y, Huang T*, Zhang F, Li Z, Ma B, Li Y, Pang Z (2021) Origin of sulfate in the unsaturated zone and groundwater of a loess aquifer. Hydrological Processes 35, e14166, https://doi.org/10.1002/hyp.14166
• Ma B, Huang T*, Li J, Li Z, Long Y, Zhang F, Pang Z (2021) Tracing nitrate source and transformation in a semiarid loess aquifer with the thick unsaturated zone. Catena 198, 105045, https://doi.org/10.1016/j.catena.2020.105045
• Li Z, Huang T*, Ma B, Long Y, Zhang F, Tian J, Li Y, Pang Z (2020) Baseline groundwater quality before shale gas development in Xishui, Southwest China: Analyses of hydrochemistry and multiple environmental isotopes (2H, 18O, 13C, 87Sr/86Sr, 11B, and noble gas isotopes). Water 12, 1741, https://doi.org/10.3390/w12061741  
• Huang T, Li Z, Mayer B, Nightingale M, Li X, Li G, Long Y, Pang Z (2020) Identification of geochemical processes during hydraulic fracturing of a shale gas reservoir: a controlled field and laboratory water-rock interaction experiment. Geophysical Research Letters 47, e2020GL090420, https://doi.org/10.1029/2020GL090420
• Huang T, Pang Z, Yang S, Yin L (2020) Impact of afforestation on atmospheric recharge to groundwater in a semiarid area. Journal of Geophysical Research: Atmospheres 125, e2019JD032185, doi: 10.1029/2019JD032185 
• Huang T, Ma B, Pang Z, Li Z, Li Z, Long Y (2020) How does precipitation recharge groundwater in loess aquifers? Evidence from multiple environmental tracers. Journal of Hydrology 583, 124532, doi: 10.1016/j.jhydrol.2019.124532
• Huang T, Pang Z, Li Z, Li Y, Hao Y (2020) A framework to determine sensitive inorganic monitoring indicators for tracing groundwater contamination by produced formation water from shale gas development in the Fuling Gasfield, SW China. Journal of Hydrology 581, 124403, doi: 10.1016/j.jhydrol.2019.124403
• Huang T, Li Z, Ma B, Long Y (2019) Tracing the origin of groundwater nitrate in an area affected by acid rain using dual isotopic composition of nitrate. Geofluids 2019, 8964182, doi: 10.1155/2019/8964182
• Huang T, Ma B (2019) The origin of major ions of groundwater in a loess aquifer. Water 11(12), 2464, doi: 10.3390/w11122464
• Huang T, Fan Y, Long Y, Pang Z (2019) Quantitative calculation for the contribution of acid rain to carbonate weathering. Journal of Hydrology 568: 360–371 [link]
• Huang T, Pang Z, Liu J, Ma J, Gates J (2017) Groundwater recharge mechanism in an integrated tableland of the Loess Plateau, northern China: insights from environmental tracers. Hydrogeology Journal 25(7): 2049–2065 [link]
• Huang T, Pang Z, Liu J, Yin L, Edmunds WM (2017) Groundwater recharge in an arid grassland as indicated by soil chloride profile and multiple tracers. Hydrological Processes 31(5): 1047-1057 [link]
• Huang T, Pang Z, Li J, Xiang Y, Zhao Z(2017) Mapping groundwater renewability using age data in the Baiyang alluvial fan, NW China. Hydrogeology Journal 25(3): 743-755 [link]
• Huang T, Pang Z, Tian J, Li Y, Yang S, Luo L (2017) Methane content and isotopic composition of shallow groundwater: implications for environmental monitoring related to shale gas exploitation. Journal of Radioanalytical and Nuclear Chemistry 312(3):577-585 [link]
• Huang T, Hao Y, Pang Z, Li Z, Yang S (2017) Radioactivity of soil, rock and water in a shale gas exploitation area, SW China. Water 9(5), 299, doi: 10.3390/w9050299 [link]
• Huang T, Yang S, Liu J, Li Z (2016) How much information can soil solute profiles reveal about groundwater recharge? Geosciences Journal 20: 495-502. [link]
• Huang T, Pang Z, Edmunds WM (2013) Soil profile evolution following land-use change: implications for groundwater quantity and quality. Hydrological Processes 27: 1238-1252 [link]
• Huang T, Pang Z, Yuan L (2013) Nitrate in groundwater and the unsaturated zone in (semi)arid northern China: baseline and factors controlling its transport and fate. Environmental Earth Sciences 70: 145-156 [link]
• Huang T, Pang Z, Chen Y, Kong Y (2013) Groundwater circulation relative to water quality and vegetation in an arid transitional zone linking oasis, desert and river. Chinese Science Bulletin 58: 3088-3097[link]
• Huang T, Pang Z (2012) The role of deuterium excess in determining the water salinisation mechanism: a case study of the arid Tarim River Basin, NW China. Applied Geochemistry 27: 2382-2388 [link]
• Huang T, Pang Z (2011) Estimating groundwater recharge following land-use change using chloride mass balance of soil profiles: a case study at Guyuan and Xifeng in the Loess Plateau of China. Hydrogeology Journal  19: 177-186 [link]
• Huang T, Pang Z (2010) Changes in groundwater induced by water diversion in the Lower Tarim River, Xinjiang Uygur, NW China: evidence from environmental isotopes and water chemistry. Journal of Hydrology 387: 188-201 [link]