Tianming Huang
Professor of Hydrogeology
Institute of Geology and Geophysics
Chinese Academy of Sciences
Email: tmhuang@mail.iggcas.ac.cn
Telephone: 010-82998276
Address: No. 19, Beituchengxi Road, Beijing, China
Postcode: 100029
Research Areas
Dr. Tianming Huang is a Professor of Hydrogeology at the Institute of Geology and Geophysics, Chinese Academy of Sciences. His research is focused on processes of water cycling and water chemistry in the unsaturated zone and groundwater. He applies geochemical and isotopic tracers to a wide range of topics including groundwater recharge and water-rock interactions. He has (co-)authored more than 100 papers (citation of >3000 times) on a wide variety of geochemical topics.
He is currently the Deputy Director of the Key Laboratory of Shale Gas and Geoengineering, Chinese Academy of Sciences, and the Director of the Department of Hydrogeology and Geothermal Resources, College of Earth and Planetary Sciences, University of Chinese Academy of Sciences. He once undertook research at the Department of Geoscience, the University of Calgary (Canada) as a visiting professor (2019/08-2020/08) and worked on tracing water-rock interaction following hydraulic fracturing mainly using solute isotopic techniques.
His expertise has garnered him the secretary general of the China Commission on Tracers, Deputy-Director of the Groundwater Committee of the Chinese Hydraulic Engineering Society, and a member of the Youth Innovation Promotion Association of the Chinese Academy of Sciences. He is an Associate Editor of Frontiers in Earth Science, and also involved in the editorial board for the Journal of Groundwater Science and Engineering, Journal of Engineering Geology, and Journal of Ludong University (Natural Science Edition).
Education
(3) March 2008 – November 2010,
University of Chinese Academy of Sciences
Ph.D., Geological Engineering (Hydrogeology)
(2) September 2004 – June 2007, Lanzhou University
Master, Hydrology and Water Resources
(1) September 2000 – June 2004, Lanzhou University
Bachelor, Hydrology and Water Resources Engineering
Experience
(4) December 2021 – present,
Institute of Geology and Geophysics, Chinese Academy of Sciences
Location: Beijing; Position: Professor
(3) January 2013 – December 2021,
Institute of Geology and Geophysics, Chinese Academy of Sciences
Location: Beijing; Position: Associate Professor
(2) August 2019 – August 2020,
University of Calgary
Location: Calgary; Position: Visiting Scientist
(1) November 2010 – December 2012,
Institute of Geology and Geophysics, Chinese Academy of Sciences
Location: Beijing; Position: Postdoctoral Researcher
Teaching Experience
Isotope Hydrogeology
Hydrogeology
Honors & Distinctions
Natural Resources Science and Technology Award of China (2nd level)
Pollyanna Chu Outstanding Teacher of the Chinese Academy of Sciences
Youth S&T Award of China Society of Natural Resources
Youth Innovation Promotion Association of the Chinese Academy of Sciences
Water-Rock Interaction GMZ Scholarship
First Prize of Water Science and Technology Progress Award of Gansu Province
Publications
Peer-reviewed Science Citation Index (SCI)-journal papers
[64] Zhang Y, Manga M*, Fu L-Y, Zhang H, Huang T*, Yang Q, Cui Z-D, Qi S*, Huang Y (2024) Long‐ and short‐term effects of seismic waves and coseismic pressure changes on fractured aquifers. Journal of Geophysical Research: Solid Earth 129, e2023JB027970, https://doi.org/10.1029/2023JB027970 [link]
[63] Li Y, Zhou X*, Huang T*, Tian J, He M, Zhu X, Li J, Zhang Y, Wu Z, Li B, Yan Y, Wang Y, Yao B, Zeng Z, Xing G, Cui S (2024) Origins of volatiles and helium fluxes from hydrothermal systems in the Eastern Himalayan Syntaxis and constraints on regional heat and tectonic activities. Journal of Hydrology 631, 130776, https://doi.org/10.1016/j.jhydrol.2024.130776 [link]
[62] Zhang Y, Chu B, Huang T*, Qi S, Manga M*, Zhang H, Zheng B, Zhou Y (2024) Using the tidal response of groundwater to assess and monitor caprock confinement in CO2 geological sequestration. Water 16, 868, https://doi.org/10.3390/w16060868 [link]
[61] Gao B, Li Y*, Pang Z, Huang T, Kong Y, Li B, Zhang F (2024) Geochemical mechanisms of water/CO2-rock interactions in EGS and its impacts on reservoir properties: A review. Geothermics 118, 102923, https://doi.org/10.1016/j.geothermics.2024.102923 [link]
[60] Dong Y, Gao J*, Liu Y, Tao L, Wu J, Zhu P, Huang H, Zheng H, Huang T (2024) Salinization of groundwater in shale gas extraction area in the Sichuan Basin, China: Implications for water protection in shale regions with well-developed faults. Science of The Total Environment 915, 170065, https://doi.org/10.1016/j.scitotenv.2024.170065 [link]
[59] Shen J, Huang T, Zhang H, Lin W* (2024) Hydrochemical and isotopic characteristics of water sources for biological activity across a massive evaporite basin on the Tibetan Plateau: Implications for aquatic environments on early Mars. Science of The Total Environment 935, 173442, https://doi.org/10.1016/j.scitotenv.2024.173442
[58] Zhang F, Li Y*, Zhou X*, Huang T, Tian J, Cheng Y, Zhao Y (2023) Geochemical behaviors of rare earth elements in granite-hosted geothermal systems in SE China. Geothermics 115, 102826, https://doi.org/10.1016/j.geothermics.2023.102826 [link]
[57] Chu B, Feng G, Zhang Y*, Qi S, Li P, Huang T (2023) Residual saturation effects on CO2 migration and caprock sealing: a study of permeability and capillary pressure models. Water 15(18), 3316. https://doi.org/10.3390/w15183316 [link]
[56] Qi S*, Zheng B, Wang Z, Zhao H, Cui Z, Huang T, Guo S, Fu L, Dong P (2023) Geological evaluation for the carbon dioxide geological utilization and storage (CGUS) site: A review. Science China Earth Sciences 66(9): 1917–1936, https://doi.org/10.1007/s11430-022-1107-x [link]
[55] Zhang Y, Fu L-Y*, Zhu A*, Zhao L, Qi S, Huang T, Ma Y, Zhang W (2023) Anisotropy and heterogeneity induced by shale in aquifer lithology - influence of aquifer shale on the leaky model with tidal response analysis. Water Resources Research 59(2), e2021WR031451, https://doi.org/10.1029/2021WR031451 [link]
[54] Li Y*, Luo J, Tian J, Cheng Y, Pang Z, Huang T, Fan Y (2023) Formation of the hydrothermal system from granite reservoir for power generation in igneous rock areas of South China. Geothermics 110, 102673. https://doi.org/10.1016/j.geothermics.2023.102673 [link]
[53] Tian J, Zhou X*, Yan Y, He M, Li J, Dong J, Liu F, Ouyang S, Li Y, Tian L, Wang Y, Huang T, Pang Z (2023) Earthquake-induced impulsive release of water in the fractured aquifer system: Insights from the long-term hydrochemical monitoring of hot springs in the Southeast Tibetan Plateau. Applied Geochemistry 148, 105553. https://doi.org/10.1016/j.apgeochem.2022.105553 [link]
[52] 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, doi: 10.1016/j.jhydrol.2022.127800 [link]
[51] 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(23), 15673, doi: 10.3390/ijerph192315673 [link]
[50] 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, doi: 10.1016/j.apgeochem.2022.105360 [link]
[49] Zhang Y*, Huang T* (2022) DNA-based tracers for the characterization of hydrogeological systems—recent advances and new frontiers. Water 14(21), 3545, doi: 10.3390/w14213545 [link]
[48] 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, doi: 10.1155/2022/4419310 [link]
[47] Bao Y, Pang Z*, Huang T, Li Y, Tian J, Luo J, Qian T (2022) Chemical and isotopic evidences on evaporite dissolution as the origin of high sulfate water in a karst geothermal reservoir. Applied Geochemistry 145, 105419. doi: 10.1016/j.apgeochem.2022.105419 [link]
[46] 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(21), e2021GL095909, https://doi.org/10.1029/2021GL095909 [link]
[45] 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(4), e14166, https://doi.org/10.1002/hyp.14166 [link]
[44] 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 [link]
[43] 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(20), e2020GL090420, https://doi.org/10.1029/2020GL090420 [link]
[42] 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(9), e2019JD032185, https://doi.org/10.1029/2019JD032185 [link]
[41] 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, https://doi.org/10.1016/j.jhydrol.2019.124532 [link]
[40] 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, https://doi.org/10.1016/j.jhydrol.2019.124403 [link]
[39] 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(6), 1741, https://doi.org/10.3390/w12061741 [link]
[38] Long Y, Liu J, Huang T* (2020) Impact of afforestation on soil hydraulic conductivity and repellency index based on microdisk infiltration experiment. Fresenius Environmental Bulletin 29(7A): 5855–5859
[37] 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]
[36] 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 [link]
[35] Huang T*, Ma B (2019) The origin of major ions of groundwater in a loess aquifer. Water 11(12), 2464, https://doi.org/10.3390/w11122464 [link]
[34] Fan Y, Pang Z*, Liao D, Tian J, Hao Y, Huang T, Li Y (2019) Hydrogeochemical characteristics and genesis of geothermal water from the Ganzi geothermal field, Eastern Tibetan Plateau. Water 11(8), 1631. https://doi.org/10.3390/w11081631 [link]
[33] Lyu M, Pang Z*, Huang T, Yin L (2019) Chemical and isotopic evidence on hydrogeochemical evolution and groundwater quality assessment in the Dake Lake Basin, Northwest China. Journal of Radioanalytical and Nuclear Chemistry 320(3): 865–883 [link]
[32] Lyu M, Pang Z*, Yin L, Zhang J, Huang T, Yang S, Li Z, Wang X, Gulbostan T (2019) The control of groundwater flow systems and geochemical processes on groundwater chemistry: a case study in Wushenzhao Basin, NW China. Water 11(4), 790, https://doi.org/10.3390/w11040790 [link]
[31] Tian J, Pang Z*, Guo Q, Wang Y, Li J, Huang T, Kong Y (2018) Geochemistry of geothermal fluids with implications on the sources of water and heat recharge to the Rekeng high-temperature geothermal system in the Eastern Himalayan Syntax. Geothermics 74: 92–105 [link]
[30] 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]
[29] 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]
[28] 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]
[27] 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]
[26] Huang T*, Yang S, Pang Z (2017) Hydrogeochemistry evolution and fluoride accumulation in an arid piedmont alluvial-proluvial plain. Fresenius Environmental Bulletin 26(5): 3569–3576 [link]
[25] 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, https://doi.org/10.3390/w9050299 [link]
[24] Li Y, Huang T*, Pang Z, Jin C (2017) Geochemical processes during hydraulic fracturing: a water-rock interaction experiment and field test study. Geosciences Journal 21(5): 753–763 [link]
[23] Li Z*, Lin X, Xiang W, Chen X, Huang T (2017) Stable isotope tracing of headwater sources in a river on China’s Loess Plateau. Hydrological Sciences Journal 62(13): 2150–2159 [link]
[22] Huang T*, Yang S, Liu J, Li Z (2016) How much information can soil solute profiles reveal about groundwater recharge. Geosciences Journal 20(4): 495–502 [link]
[21] Huang T*, Yang S, Liu J (2016) Using soil profile to assess groundwater recharge and effect of land-use change in a rain-fed agricultural area. Fresenius Environmental Bulletin 25(3): 862–873 [link]
[20] Li Y, Huang T*, Pang Z*, Wang Y, Jin C (2016) Geochemical characteristics of shallow groundwater in Jiaoshiba shale gas production area: implications for environmental concerns. Water 8(12), 552, https://doi.org/10.3390/w8120552 [link]
[19] Hou X, Zhang J, Liu J*, Huang T (2016) Rational exploitation of large wellfields based on ecological water demand in arid inland basins. Fresenius Environmental Bulletin 25(8): 3003–3011
[18] Li J, Pang Z*, Froehlich K, Huang T, Kong Y, Song W, Yun H (2015) Paleo-environment from isotopes and hydrochemistry of groundwater in East Junggar Basin, Northwest China. Journal of Hydrology 529: 650–661 [link]
[17] Kong Y, Pang Z*, Li J, Huang T (2014) Seasonal variations of water isotopes in the Kumalak river catchments, western Tianshan mountains, central Asia. Fresenius Environmental Bulletin 23(1A): 169–174
[16] Li J, Pang Z*, Kong Y, Zhou M, Huang T (2014) Contrasting seasonal distribution of stable isotopes and deuterium excess in precipitation over China. Fresenius Environmental Bulletin 23(9): 2074–2085
[15] 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]
[14] 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]
[13] 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]
[12] Liu J, Huang T*, Yuan L (2013) Fluoride content in groundwater and the unsaturated zone in three large basins in (semi)arid northern China. Fresenius Environmental Bulletin 22(8A): 2393–2401
[11] Pang Z*, Yuan L, Huang T, Kong Y, Liu J, Li Y (2013) Impacts of human activities on the occurrence of groundwater nitrate in an alluvial plain: A multiple isotopic tracers approach. Journal of Earth Science 24(1): 111–124 [link]
[10] 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]
[9] Yuan L, Pang Z*, Huang T (2012) Integrated assessment on groundwater nitrate by unsaturated zone probing and aquifer sampling with environmental tracers. Environmental Pollution 171: 226–233 [link]
[8] 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]
[7] Pang Z*, Kong Y, Froehlich K, Huang T, Yuan L, Li Z, Wang F (2011) Processes affecting isotopes in precipitation of an arid region. Tellus B 63: 352–359 [link]
[6] 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]
[5] Pang Z*, Huang T, Chen Y (2010) Diminished groundwater recharge and circulation relative to degrading riparian vegetation in the middle Tarim River, Xinjiang Uygur, Western China. Hydrological Processes 24: 147–159 [link]
[4] Ma J*, Pan F, Chen L, Edmunds WM, Ding Z, He J, Zhou K, Huang T (2010) Isotopic and geochemical evidence of recharge sources and water quality in the Quaternary aquifer beneath Jinchang city, NW China. Applied Geochemistry 25: 996–1007 [link]
[3] Ma J*, Ding Z, Edmunds WM, Gates JB, Huang T (2009) Limits to recharge of groundwater from Tibetan Plateau to the Gobi desert, implications for water management in the Mountain front. Journal of Hydrology 364: 128–141 [link]
[2] Ma J*, Ding Z, Wei G, Zhao H, Huang T (2009) Sources of water pollution and evolution of water quality in the Wuwei basin of Shiyang river, Northwest China. Journal of Environmental Management 90: 1168–1177 [link]
[1] Chen Y, Pang Z*, Chen Y, Li W, Xu C, Hao X, Huang X, Huang T, Ye Z (2008) Response of riparian vegetation to water-table changes in the lower reaches of Tarim River, Xinjiang Uygur, China. Hydrogeology Journal 16: 1371–1379 [link]
Selected peer-reviewed CSCD-journal papers (in Chinese) and conference papers
[30] Li Z, Huang T*, Li Y, Li G, Yang P, Long Y, Zhao Y, Zan C, Zhang F, Li X, Pang Z (2024) A framework for evaluation of groundwater environmental effects related to shale gas development:a case study in the Xishui shallow shale block in SW China[J]. Journal of Engineering Geology 32(4):1459-1477. (in Chinese) https://doi.org/10.13544/j.cnki.jeg.2024-0141
[29] Zhao Y, Huang T*, Zan C, Long Y, Li Y, Zhang Y, Qi S, Pang Z (2024) Groundwater age and its application for evaluating the sealing capability of aquifer. Bulletin of Mineralogy,Petrology and Geochemistry 43(3): 489–501. (in Chinese) https://doi.org/10.3724/j.issn.1007-2802.20240058
[28] Li B, Li Y*, Pang Z, Huang T, Gao B (2024) Dating methods for calcareous and siliceous sinters in geothermal systems: Progress in research and applications. Coal Geology & Exploration 52(1):1–12. (in Chinese) https://doi.org/10.12363/issn.1001-1986.23.09.0556
[27] Chu B, Zhang Y, Fu L, Qi S*, Chen G, Shi Z, Huang T*, Pang Z*, Zhang H* (2024) Deep learning for identifying earthquake precursors: Applications and challenges in subsurface fluid signals. The Innovation Geoscience 2(4): 100093. https://doi.org/10.59717/j.xinn-geo.2024.100093
[26] Huang T, Li Y, Li X, He J, Qi S, Pang Z* (2023) Shale water: awakened water cycle zombies. Bulletin of Mineralogy,Petrology and Geochemistry 42(6):1439–1441. (in Chinese) https://doi.org/10.19658/j.issn.1007-2802.2023.42.123
[25] Li Y, Luo J, Chen K, Huang T*, Tian J, Cheng Y (2023) Genesis of geothermal fluid with high fluorine content and reservoir temperature assessment in Fengliang geothermal field, eastern Guangdong. Geological Review 49(4): 1337–1348. (in Chinese) https://doi.org/10.16509/j.georeview.2023.03.015
[24] Qi S*, Zheng B, Wang Z, Zhao H, Cui Z, Huang T, Guo S, Fu L, Dong P (2023) Geological evaluation for the carbon dioxide geological utilization and storage. Scientia Sinica Terrae 53(9): 1937–1957 (in Chinese) https://doi.org/10.1360/N072022-0351
[23] Huang T*, Long Y, Zhao Y, Pang Z (2023) Impact of sorption–desorption and ion exchange on isotopic composition following water-rock interaction. XXVIII General Assembly of the International Union of Geodesy and Geophysics (IUGG). Berlin, Germany, 11-21 July, 2023, IUGG23-2609, https://doi.org/10.57757/IUGG23-2609
[22] Huang T*, Long Y, Zhang F, Zhao Y, Liu W, Li Y, Ma J, Qi S, Pang Z (2023) The hydrochemical evolution of groundwater in a typical loess tableland and its significance for the carbon cycle. Quaternary Sciences 43(2): 356–367. (in Chinese) https://doi.org/10.11928/j.issn.1001-7410.2023.02.05
[21] Xie Y, Li Y*, Wang Z, Man G, Bu X, Pang Z, Huang T (2023) Status of scale prevention and removal technologies in utilization of geothermal fluid. Advances in New and Renewable Energy 11(1): 21–28 (in Chinese) https://doi.org/10.3969/j.issn.2095-560X.2023.01.004
[20] Long Y, Huang T*, Zhang F, Ma B, Ma G, Han Z, Zhang L (2022) Effect and mechanism of waste rock stacking during sulfide metal deposit mining on water environment and implication for the treatment measures. Journal of Engineering Geology 30(3): 874–883. (in Chinese) https://doi.org/10.13544/j.cnki.jeg.2022-0121
[19] Zhang F, Huang T, Pang Z (2022) Intensive quantification of precipitation moisture sources in the eastern Asian monsoon zone: A modified deuterium-excess-based model. IAHS-AISH Scientific Assembly 2022. Montpellier, France, 29 May–3 Jun 2022, IAHS2022-561 [link]
[18] Huang T*, Li Z, Mayer B*, Nightingale M, Pang Z, Li X , Li G (2020) Field and laboratory studies of the water chemistry evolution of flowback fluids from a shallow shale gas well. Goldschmidt Abstract. https://doi.org/10.46427/gold2020.1095 [link]
[17] Li Z, Huang T*, Pang Z, Xiong D, Li Y, Tian J, Li X, Ma F, Hao Y (2019) Study on groundwater baseline quality, monitoring indicators and contamination tracing methods related to shale gas development: a case study in the Fuling Gasfield in SW China. Journal of Engineering Geology 27(1): 170–177. (in Chinese) https://doi.org/10.13544/j.cnki.jeg.2019-056
[16] Huang T*, Ma B, Long Y, Pang Z (2019) The role of unsaturated zone in estimating groundwater recharge in arid and semiarid areas as depicted by geochemical tracers. E3S Web of Conferences [WRI 16] 98, 12007 https://doi.org/10.1051/e3sconf/20199812007 [link]
[15] Pang Z*, Huang T, Yang S, Yuan L (2018) The potential of the unsaturated zone in groundwater recharge in arid and semiarid areas. Journal of Engineering Geology 26(1): 51–61. (in Chinese) https://doi.org/10.13544/j.cnki.jeg.2018.01.006
[14] Huang T*, Li Y, Pang Z, Wang Y, Yang S (2017) Groundwater baseline water quality in a shale gas exploration site and fracturing fluid - shale rock interaction. Procedia Earth and Planetary Science [WRI 15] 17: 638–641 [link]
[12] Huang T*, Yang S, Li Z (2016) Genesis of the inorganic carbon with high carbon-13 content in brine water of the Lower Silurian Longmaxi shale. Internation Journal of Geoheritage 4(2): 73–75
[12] Li J, Pang Z*, Tursun G, Kong Y, Huang T, Bai G, Zhao H, Zhou D, Yang Z (2016) Identification of moisture sources in Junggar Basin and its implication for groundwater recharge. Science & Technology Review 34(18): 118–124. (in Chinese) https://doi.org/10.3981/j.issn.1000-7857.2016.18.015
[11] Liu J*, Pang Z, Huang T, Wang S (2014) Groundwater extraction threshold and safe water table of the Machikou emergency wellfiled in the alluvial and diluvial fan in Beijing. Quaternary Sciences 34(5): 1117–1124. (in Chinese) https://doi.org/10.3969/j.issn.1001-7410.2014.05.20
[10] Huang T, Pang Z* (2013) Groundwater recharge and dynamics in northern China: implications for sustainable utilization of groundwater. Procedia Earth and Planetary Science [WRI 14] 7: 369–372 [link]
[9] Huang T, Liu J, Wang G* (2012) Groundwater baseline quality in the Minqin Basin, NW China. Advanced Materials Research 518-523: 3643–3646 [link]
[8] Huang T*, Pang Z* (2011) A combined conceptual model (V&P model) to correct groundwater radiocarbon age. In: 2011 International Symposium on Water Resource and Environmental Protection. 20-22 May 2011, Xi'an China, pp. 28–30. https://doi.org/10.1109/ISWREP.2011.5892937 [link]
[7] Liu J*, Liu C, Huang T, Wang S, Du C, Ji M (2010) Evaluation of artificial recharge to groundwater reservoir in Beijing western suburbs based on regulation and storage experiment and numerical simulation. Journal of China Hydrology 30(3): 33–37. (in Chinese) https://doi.org/10.3969/j.issn.1000-0852.2010.03.007
[6] Huang T*, Nie Z, Yuan L (2008) Temperature and Geographical Effects of Hydrogen and Oxygen Isotopes in Precipitation in West of China. Journal of Arid Land Resources and Environment 22(8): 76–81. (in Chinese) https://doi.org/10.3969/j.issn.1003-7578.2008.08.015
[5] Huang T*, Pang Z (2007) Groundwater recharge in Badain Jaran Desert and Gurinai Oasis based on environmental tracers. Geoscience 21(4): 624–631. (in Chinese) https://doi.org/10.3969/j.issn.1000-8527.2007.04.006
[4] Ma J*, Huang T, Ding Z, Edmunds WM (2007) Environmental isotopes as the indicators of the groundwater recharge in the south Badain Jaran Desert. Advances in Earth Science 22(9): 922–930 (in Chinese) https://doi.org/10.3321/j.issn:1001-8166.2007.09.006
[3] Zhang B, Ma J*, Zhao X, Huang T (2007) Analysis on variation characteristics of temperature in Minqin during recent 50 years. Agricultural Research in the Arid Areas 25(2): 226–229. (in Chinese) https://doi.org/10.3321/j.issn:1000-7601.2007.02.045
[2] Ma J*, Li X, Huang T, Edmunds WM (2005) Chemical evolution and recharge characteristics of water resources in the Shiyang River Basin. Resources Science 27(3): 117–122. (in Chinese) https://doi.org/10.3321/j.issn:1007-7588.2005.03.019
[1] Huang T*, Wang X, Shi P (2004) Estimating of water demand of ecosystem and rebuilding ecosystem in arid areas. Journal of Arid Land Resources and Environment 18(8): 43–47. (in Chinese)
Students
已指导学生
杨硕 硕士研究生 081803-地质工程
利振彬 博士研究生 081803-地质工程
龙吟 博士研究生 081803-地质工程
现指导学生
张芬 博士研究生 081803-地质工程
赵雅静 博士研究生 081803-地质工程
昝朝耀 硕士研究生 081803-地质工程
楚炳菲 博士研究生 081803-地质工程
叶竞繁 博士研究生 081803-地质工程