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Hao Yan
  • Career:  Career:   Tenure-track Assistant Professor
  • Post:  仅研究系列选择
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Personal Profile

My research interests include: 1) stable isotope kinetics in calcite growth, diffusion, evaporation, oxidation of reduced sulfur, etc.; 2) non-mass-dependent fractionation of oxygen and sulfur isotopes in nature; 3) Water cycling on the Moon; 4) carbon cycle in inland water bodies; 5) development of new method for isotope analysis.

Educational Background

2009.9-2015.6 University of Chinese Academy of Sciences, Geochemistry, PhD
2013.4-2014.4 University of Strasbourg (France), Geochemistry
2005.9-2009.6 Sichuan University, Environment science, Bachelor

Work Experience

2021.7 – present, Assistant Professor, Nanjing University
2018.12-2020.11, Visiting scholar, Louisiana State University (USA)
2019.5-2021.6, Associated professor, Institute of Geochemistry, Chinese Academy of Sciences
2015.7-2019.4, Assistant professor, Institute of Geochemistry, Chinese Academy of Sciences

Academic Service

Research Intersets

Teaching

Research Projects

Publications

First/corresponding-author papers

12.  Wei, Y., Yan, H., Peng, Y., Han, S., and Bao, H., 2024.  Thermal-gradient-induced isotope fractionation during CO2-O2 triple  oxygen isotope exchange. Geochimica et Cosmochimica Acta. 370: 29–40

11.  Yan H, Peng Y, Bao H. Isotope fractionation during capillary leaking in  an isotope ratio mass spectrometer[J]. Rapid Communications in Mass  Spectrometry, 2022, 36(11): e9290.

10.  Wei Y, Yan H, Liu Z, et al. The ballast effect controls the settling of  autochthonous organic carbon in three subtropical karst reservoirs[J].  Science of The Total Environment, 2022, 818: 151736.

9.  Yan H, Dreybrodt W, Bao H, et al. The influence of hydrodynamics on the  carbon isotope composition of inorganically precipitated calcite[J].  Earth and Planetary Science Letters, 2021, 565: 116932.

8.  Yan H, Liu Z, Sun H. Large degrees of carbon isotope disequilibrium  during precipitation-associated degassing of CO2 in a mountain  stream[J]. Geochimica et Cosmochimica Acta, 2020, 273: 244-256.

7. 魏榆, 杨昌平, 晏浩, . 喀斯特水库碳, 硅耦合循环: 以红枫湖, 普定水库和平寨水库为例[J]. 地球与环境, 2020, 48(1): 1-9.

6.  Yan H, Liu Z, Sun H. Effect of in-stream physicochemical processes on  the seasonal variations in δ13C and δ18O values in laminated travertine  deposits in a mountain stream channel[J]. Geochimica et Cosmochimica  Acta, 2017, 202: 179-189.

5.  Yan H., Schmitt A.D., Liu Z., Gangloff S., Sun H., Chen J., Chabaux F.  Calcium isotopic fractionation during travertine deposition under  different hydrodynamic conditions: Examples from Baishuitai (Yunnan, SW  China)[J]. Chemical Geology, 2016, 426: 60-70.

4. Wang H, Yan H(共同一作),  Liu Z. Contrasts in variations of the carbon and oxygen isotopic  composition of travertines formed in pools and a ramp stream at  Huanglong Ravine, China: Implications for paleoclimatic  interpretations[J]. Geochimica et Cosmochimica Acta, 2014, 125: 34-48.

3.晏浩, 刘再华, 邓贵平, . 四川九寨沟景区钙华起源初探[J]. 中国岩溶, 2013, 32(1): 15-22.

2. Yan  H, Sun H, Liu Z. Equilibrium vs. kinetic fractionation of oxygen  isotopes in two low-temperature travertine-depositing systems with  differing hydrodynamic conditions at Baishuitai, Yunnan, SW China[J].  Geochimica et Cosmochimica Acta, 2012, 95: 63-78.

1.晏浩, 刘再华. 层状钙华及其地球化学指标的古气候/环境意义[J]. 第四纪研究, 2011, 31(1): 88-95.

  

Co-author papers

19. Bao,  R., Sheng, X., Li, C., Cui, C., Yan, H., Ji, J., & Chen, J. (2023).  Calibration of the carbonate clumped isotope thermometer of land snail  shells.Chemical Geology,641, 121773.

18.  Sun H, Shen C C, Wu C C, et al. Subannual-to-biannual-resolved  travertine record of Asian Summer Monsoon dynamics in the early Holocene  at the eastern margin of Tibetan Plateau[J]. Applied Geochemistry,  2022, 141: 105305.

17.  Sun H, Han C, Liu Z, et al. Nutrient limitations on primary  productivity and phosphorus removal by biological carbon pumps in dammed  karst rivers: Implications for eutrophication control[J]. Journal of  Hydrology, 2022, 607: 127480.

16.  Zhao M, Sun H, Liu Z, et al. Organic carbon source tracing and the BCP  effect in the Yangtze River and the Yellow River: Insights from  hydrochemistry, carbon isotope, and lipid biomarker analyses[J]. Science  of The Total Environment, 2022, 812: 152429.

15.  Chen B, Zhao M, Yan H, et al. Tracing source and transformation of  carbon in an epikarst spring-pond system by dual carbon isotopes  (13C-14C): Evidence of dissolved CO2 uptake as a carbon sink[J]. Journal  of Hydrology, 2021, 593: 125766.

14.  He H, Liu Z, Li D, et al. Recent environmental changes in the  Yunnan–Guizhou Plateau inferred from organic geochemical records from  the sediments of Fuxian Lake[J]. Elementa: Science of the Anthropocene,  2021, 9(1).

13. 马松, 魏榆, 韩翠红, 晏浩, 刘再华, 孙海龙, 鲍乾.喀斯特水库水化学特征及对无机碳沉积通量的指示[J]. J. Lake. Sci, 2021, 33(6).

12.  Liu Z, Yan H, Zeng S. Increasing autochthonous production in inland  waters as a contributor to the missing carbon sink[J]. Frontiers in  Earth Science, 2021: 772.

11. 韩翠红, 孙海龙, 魏榆, 鲍乾, 晏浩. 喀斯特筑坝河流中生物碳泵效应的碳施肥及对水化学时空变化的影响——以贵州平寨水库及红枫湖为例[J]. 湖泊科学, 2020, 32(6): 1683-1694.

10.  He H., Liu Z., Chen C., Wei Y., Bao Q., Sun H., Yan H. The sensitivity  of the carbon sink by coupled carbonate weathering to climate and  land-use changes: Sediment records of the biological carbon pump effect  in Fuxian Lake, Yunnan, China, during the past century[J]. Science of  the Total Environment, 2020, 720: 137539.

9.  He H., Liu Z., Chen C., Wei Y., Bao Q., Sun H., Yan H. Influence of the  biological carbon pump effect on the sources and deposition of organic  matter in Fuxian Lake, a deep oligotrophic lake in southwest China[J].  Acta Geochimica, 2019, 38: 613-626.

8.  Chen B, Yang R, Liu Z, Sun H, Yan H, Zeng Q, Zeng S, Zeng C. Coupled  control of land uses and aquatic biological processes on the diurnal  hydrochemical variations in the five ponds at the Shawan Karst Test  Site, China: implications for the carbonate weathering-related carbon  sink[J]. Chemical Geology, 2017, 456: 58-71.

7. 曾振宇, 晏浩, 孙海龙, . 云南白水台钙华池出入口水化学和d13CDIC昼夜变化的影响因素及水生光合作用影响比例的计算[J]. 中国岩溶, 2016, 35(6): 605-613.

6. Yang  R., Chen B., Liu H., Liu Z., Yan H. Carbon sequestration and decreased  CO2 emission caused by terrestrial aquatic photosynthesis: Insights from  diel hydrochemical variations in an epikarst spring and two spring-fed  ponds in different seasons[J]. Applied Geochemistry, 2015, 63: 248-260.

5. Kele  S., Breitenbach S., Capezzuoli E., Meckler A., Ziegler M., Millan I.,  Kluge T., Deák J., Hanselmann K., John C., Yan H., Liu Z., Bernasconi S.  M. Temperature dependence of oxygen-and clumped isotope fractionation  in carbonates: a study of travertines and tufas in the 6–95 C  temperature range[J]. Geochimica et Cosmochimica Acta, 2015, 168:  172-192.

4. Zhao M, Liu Z, Li H C, Zeng C, Yang R, Chen B, Yan H. Response  of dissolved inorganic carbon (DIC) and δ13CDIC to changes in climate  and land cover in SW China karst catchments[J]. Geochimica et  Cosmochimica Acta, 2015, 165: 123-136.

3. Sun  H, Liu Z, Yan H. Oxygen isotope fractionation in travertine-depositing  pools at Baishuitai, Yunnan, SW China: effects of deposition rates[J].  Geochimica et Cosmochimica Acta, 2014, 133: 340-350.

2.陈波, 杨睿, 刘再华, 晏浩, 赵敏. 水生光合生物对茂兰拉桥泉及其下游水化学和d13CDIC 昼夜变化的影响[J]. 地球化学, 2014, 43(4): 375-385.

1.孙海龙, 刘再华, 晏浩, . 不同方法萃取的溶解无机碳的 δ^(13) C 值比较分析[J]. 中国岩溶, 2013, 32(1): 117-122.

Honors and Awards

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