Unveiling the nitrogen transport and transformation in different karst aquifers media
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D. Yuan | L. Fan | Fangxin Guo | Qiangli Zhang | Jing Bao | Xisong Wu
[1] D. Yuan,et al. Nitrate sources and nitrogen dynamics in a karst aquifer with mixed nitrogen inputs (Southwest China): Revealed by multiple stable isotopic and hydro-chemical proxies. , 2021, Water research.
[2] Yu-Chun Wang,et al. New insight into the response and transport of nitrate in karst groundwater to rainfall events. , 2021, The Science of the total environment.
[3] G. Jiang,et al. Biological sulfate reduction in an epigene karst aquifer and its impact on cave environment , 2021 .
[4] H. Rügner,et al. Fate of nitrate during groundwater recharge in a fractured karst aquifer in Southwest Germany , 2021, Hydrogeology Journal.
[5] D. Oliver,et al. Rainfall and conduit drainage combine to accelerate nitrate loss from a karst agroecosystem: Insights from stable isotope tracing and high-frequency nitrate sensing. , 2020, Water research.
[6] J. Mahlknecht,et al. Estimation of nitrate pollution sources and transformations in groundwater of an intensive livestock-agricultural area (Comarca Lagunera), combining major ions, stable isotopes and MixSIAR model. , 2020, Environmental pollution.
[7] Lisheng Song,et al. Nitrate sources and biogeochemical processes in karst underground rivers impacted by different anthropogenic input characteristics. , 2020, Environmental pollution.
[8] J. Hartmann,et al. Global distribution of carbonate rocks and karst water resources , 2020, Hydrogeology Journal.
[9] Qiong Xiao,et al. Sources and transformations of nitrate constrained by nitrate isotopes and Bayesian model in karst surface water, Guilin, Southwest China , 2020, Environmental Science and Pollution Research.
[10] D. Oliver,et al. Land use interacts with changes in catchment hydrology to generate chronic nitrate pollution in karst waters and strong seasonality in excess nitrate export , 2019, Science of The Total Environment.
[11] R. Dahlgren,et al. Coupling stable isotopes and water chemistry to assess the role of hydrological and biogeochemical processes on riverine nitrogen sources. , 2019, Water research.
[12] O. Fenton,et al. Combining stable isotopes with contamination indicators: A method for improved investigation of nitrate sources and dynamics in aquifers with mixed nitrogen inputs. , 2017, Water research.
[13] A. Soler,et al. Characterizing sources and natural attenuation of nitrate contamination in the Baix Ter aquifer system (NE Spain) using a multi-isotope approach. , 2017, The Science of the total environment.
[14] U. Ofterdinger,et al. The influence of bedrock hydrogeology on catchment-scale nitrate fate and transport in fractured aquifers. , 2016, The Science of the total environment.
[15] M. Musgrove,et al. Source, variability, and transformation of nitrate in a regional karst aquifer: Edwards aquifer, central Texas. , 2016, The Science of the total environment.
[16] L. Gill,et al. Quantifying the influence of surface water–groundwater interaction on nutrient flux in a lowland karst catchment , 2016 .
[17] Y. Jianjun,et al. δ18O characteristics of meteoric precipitation and its water vapor sources in the Guilin area of China , 2015, Environmental Earth Sciences.
[18] F. Benjamin Zhan,et al. Twenty years of global groundwater research: A Science Citation Index Expanded-based bibliometric survey (1993–2012) , 2014 .
[19] Thorsten Wagener,et al. Karst water resources in a changing world: Review of hydrological modeling approaches , 2014 .
[20] Fadong Li,et al. Tracing nitrate pollution sources and transformation in surface- and ground-waters using environmental isotopes. , 2014, The Science of the total environment.
[21] L. Zeng,et al. Nitrate source apportionment in a subtropical watershed using Bayesian model. , 2013, The Science of the total environment.
[22] S. Derenne,et al. Using δ15N and δ18O values to identify sources of nitrate in karstic springs in the Paris basin (France) , 2013 .
[23] L. Band,et al. Tracking nonpoint source nitrogen pollution in human-impacted watersheds. , 2011, Environmental science & technology.
[24] N. Yoshida,et al. Evaluation of wastewater nitrogen transformation in a natural wetland (Ulaanbaatar, Mongolia) using dual-isotope analysis of nitrate. , 2011, The Science of the total environment.
[25] Richard Inger,et al. Source Partitioning Using Stable Isotopes: Coping with Too Much Variation , 2010, PloS one.
[26] G. Jia,et al. Nitrate sources and watershed denitrification inferred from nitrate dual isotopes in the Beijiang River, south China , 2009 .
[27] B. De Baets,et al. Present limitations and future prospects of stable isotope methods for nitrate source identification in surface- and groundwater. , 2009, Water research.
[28] M. Rivett,et al. Nitrate attenuation in groundwater: a review of biogeochemical controlling processes. , 2008, Water research.
[29] John T. Wilson,et al. Transport and fate of nitrate at the ground-water/surface-water interface. , 2008, Journal of environmental quality.
[30] E. Elliott,et al. Tracing Anthropogenic Inputs of Nitrogen to Ecosystems , 2008 .
[31] Li Xuehui,et al. The Application of Nitrogen and Oxygen Isotopes in the Study of Nitrate in Rivers , 2007 .
[32] B. Mayer,et al. Hydrodynamic and microbial processes controlling nitrate in a fissured-porous karst aquifer of the Franconian Alb, southern Germany. , 2006, Environmental science & technology.
[33] N. Goldscheider,et al. Dynamics and interaction of organic carbon, turbidity and bacteria in a karst aquifer system , 2006 .
[34] M. Bakalowicz. Karst groundwater: a challenge for new resources , 2005 .
[35] K. Hiscock,et al. A dual isotope approach to identify denitrification in groundwater at a river-bank infiltration site. , 2003, Water research.
[36] W. White,et al. Metal transport to karst springs during storm flow: an example from Fort Campbell, Kentucky/Tennessee, USA , 2003 .
[37] G. Billen,et al. Isotopic composition of nitrate-nitrogen as a marker of riparian and benthic denitrification at the scale of the whole Seine River system , 2003 .
[38] James M. Thomas,et al. Environmental isotopes in hydrogeology , 2003 .
[39] W. Kelly,et al. Determination of the sources of nitrate contamination in karst springs using isotopic and chemical indicators , 2001 .
[40] W. Robertson,et al. Use of Multiple Isotope Tracers to Evaluate Denitrification in Ground Water: Study of Nitrate from a Large‐Flux Septic System Plume , 1998 .
[41] S. J. Altman,et al. Dilution of Nonpoint-Source Nitrate in Groundwater , 1995 .
[42] Peter Engesgaard,et al. A geochemical transport model for redox-controlled movement of mineral fronts in groundwater flow systems: A case of nitrate removal by oxidation of pyrite , 1992 .
[43] A. Hooper,et al. O2 and H2O are each the source of one O in NO− 2 produced from NH3 by Nitrosomonas: 15N‐NMR evidence , 1983 .
[44] C. Curtis,et al. A quantitative evaluation of pyrite weathering , 1981 .
[45] H. Craig,et al. Standard for Reporting Concentrations of Deuterium and Oxygen-18 in Natural Waters , 1961, Science.
[46] Hongguang Cheng,et al. Nitrate behaviors and source apportionment in an aquatic system from a watershed with intensive agricultural activities. , 2015, Environmental science. Processes & impacts.
[47] 郝芳,et al. Characteristics and depositional models of source rocks in Langgu Sag,Bohai Bay Basin , 2014 .
[48] C. Coxon. Agriculture and Karst , 2011 .
[49] Qin Zheng-jiao. Causes of Karst Groundwater Damage to the Zengpiyan Ruins of Guilin and the Prevention and Control Countermeasures , 2011 .
[50] T. Borch,et al. Biogeochemical Redox Processes and their Impact on Contaminant Dynamics , 2009 .
[51] Bruno Bussière,et al. Passive treatment of acid mine drainage in bioreactors using sulfate-reducing bacteria: critical review and research needs. , 2007, Journal of environmental quality.
[52] Ni Shi. DEUTERIUM EXCESS PARAMETER AND GEOHYDROLOGY SIGNIFICANCE ——Taking the geohydrology researches in Jiuzaigou and Yele, Sichuan for example , 2001 .
[53] C. Kendall. Tracing Nitrogen Sources and Cycling in Catchments , 1998 .
[54] D. Lovley,et al. Competitive Exclusion of Sulfate Reduction by Fe(lll)‐Reducing Bacteria: A Mechanism for Producing Discrete Zones of High‐Iron Ground Water , 1992 .