A high‐resolution monitoring station for the in situ assessment of nitrate‐related redox processes at an agricultural site
Biogeochemical redox processes control the chemical behavior of many major and trace elements, making their comprehension crucial for predicting and protecting environmental health. Nitrogen (N) is especially susceptible to changes in soil redox conditions and affects the cycles of other redox‐sensi...
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| Published in | Journal of environmental quality Vol. 52; no. 1; pp. 188 - 198 |
|---|---|
| Main Authors | , , , , , , |
| Format | Journal Article |
| Language | English |
| Published |
United States
01.01.2023
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| Subjects | |
| Online Access | Get full text |
| ISSN | 0047-2425 1537-2537 1537-2537 |
| DOI | 10.1002/jeq2.20423 |
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| Abstract | Biogeochemical redox processes control the chemical behavior of many major and trace elements, making their comprehension crucial for predicting and protecting environmental health. Nitrogen (N) is especially susceptible to changes in soil redox conditions and affects the cycles of other redox‐sensitive species. Elevated N concentrations, in nitrate form, in agricultural soils and associated freshwater ecosystems constitute a problem in many parts of the world. Although a wide variety of measures have been adopted, their assessment through concentration measurements in groundwater and surface water of the different monitoring networks has shortcomings. Nitrate, as a non‐point pollutant, is subject to several processes (e.g., transformation and retardation) before it is detected, making it impossible to evaluate measurements’ effectiveness reliably. Thus, we designed and constructed a monitoring station featuring commercially available products and self‐manufactured components at an agricultural site for the in situ assessment of nitrate‐related processes by high‐resolution monitoring of hydraulic (soil water content, matric potential, groundwater head) and hydrogeochemical variables (oxidation‐reduction potential and groundwater and pore water chemistry) within the vadose zone and the shallow aquifer. The monitoring station has proven to be a reliable tool. Changes over depth and time of measured variables have been identified, allowing the detection of the transient behavior of the redox reactive zone and the interpretation of ongoing denitrification processes and other redox nitrate‐triggered phenomena, such as uranium roll‐front and selenium accumulation at the redox interface. Measuring both geochemical and soil water variables allows for the calculation of in situ solute inputs into the groundwater and their reaction rates.
Core Ideas
We propose a robust design for long‐term, high‐resolution monitoring of soil hydraulic and hydrogeochemical variables.
It features a combination of commercially available products and self‐manufactured components.
Redox processes such as denitrification and uranium roll‐front propagation are observed. |
|---|---|
| AbstractList | Biogeochemical redox processes control the chemical behavior of many major and trace elements, making their comprehension crucial for predicting and protecting environmental health. Nitrogen (N) is especially susceptible to changes in soil redox conditions and affects the cycles of other redox-sensitive species. Elevated N concentrations, in nitrate form, in agricultural soils and associated freshwater ecosystems constitute a problem in many parts of the world. Although a wide variety of measures have been adopted, their assessment through concentration measurements in groundwater and surface water of the different monitoring networks has shortcomings. Nitrate, as a non-point pollutant, is subject to several processes (e.g., transformation and retardation) before it is detected, making it impossible to evaluate measurements' effectiveness reliably. Thus, we designed and constructed a monitoring station featuring commercially available products and self-manufactured components at an agricultural site for the in situ assessment of nitrate-related processes by high-resolution monitoring of hydraulic (soil water content, matric potential, groundwater head) and hydrogeochemical variables (oxidation-reduction potential and groundwater and pore water chemistry) within the vadose zone and the shallow aquifer. The monitoring station has proven to be a reliable tool. Changes over depth and time of measured variables have been identified, allowing the detection of the transient behavior of the redox reactive zone and the interpretation of ongoing denitrification processes and other redox nitrate-triggered phenomena, such as uranium roll-front and selenium accumulation at the redox interface. Measuring both geochemical and soil water variables allows for the calculation of in situ solute inputs into the groundwater and their reaction rates.Biogeochemical redox processes control the chemical behavior of many major and trace elements, making their comprehension crucial for predicting and protecting environmental health. Nitrogen (N) is especially susceptible to changes in soil redox conditions and affects the cycles of other redox-sensitive species. Elevated N concentrations, in nitrate form, in agricultural soils and associated freshwater ecosystems constitute a problem in many parts of the world. Although a wide variety of measures have been adopted, their assessment through concentration measurements in groundwater and surface water of the different monitoring networks has shortcomings. Nitrate, as a non-point pollutant, is subject to several processes (e.g., transformation and retardation) before it is detected, making it impossible to evaluate measurements' effectiveness reliably. Thus, we designed and constructed a monitoring station featuring commercially available products and self-manufactured components at an agricultural site for the in situ assessment of nitrate-related processes by high-resolution monitoring of hydraulic (soil water content, matric potential, groundwater head) and hydrogeochemical variables (oxidation-reduction potential and groundwater and pore water chemistry) within the vadose zone and the shallow aquifer. The monitoring station has proven to be a reliable tool. Changes over depth and time of measured variables have been identified, allowing the detection of the transient behavior of the redox reactive zone and the interpretation of ongoing denitrification processes and other redox nitrate-triggered phenomena, such as uranium roll-front and selenium accumulation at the redox interface. Measuring both geochemical and soil water variables allows for the calculation of in situ solute inputs into the groundwater and their reaction rates. Biogeochemical redox processes control the chemical behavior of many major and trace elements, making their comprehension crucial for predicting and protecting environmental health. Nitrogen (N) is especially susceptible to changes in soil redox conditions and affects the cycles of other redox‐sensitive species. Elevated N concentrations, in nitrate form, in agricultural soils and associated freshwater ecosystems constitute a problem in many parts of the world. Although a wide variety of measures have been adopted, their assessment through concentration measurements in groundwater and surface water of the different monitoring networks has shortcomings. Nitrate, as a non‐point pollutant, is subject to several processes (e.g., transformation and retardation) before it is detected, making it impossible to evaluate measurements’ effectiveness reliably. Thus, we designed and constructed a monitoring station featuring commercially available products and self‐manufactured components at an agricultural site for the in situ assessment of nitrate‐related processes by high‐resolution monitoring of hydraulic (soil water content, matric potential, groundwater head) and hydrogeochemical variables (oxidation‐reduction potential and groundwater and pore water chemistry) within the vadose zone and the shallow aquifer. The monitoring station has proven to be a reliable tool. Changes over depth and time of measured variables have been identified, allowing the detection of the transient behavior of the redox reactive zone and the interpretation of ongoing denitrification processes and other redox nitrate‐triggered phenomena, such as uranium roll‐front and selenium accumulation at the redox interface. Measuring both geochemical and soil water variables allows for the calculation of in situ solute inputs into the groundwater and their reaction rates. Core Ideas We propose a robust design for long‐term, high‐resolution monitoring of soil hydraulic and hydrogeochemical variables. It features a combination of commercially available products and self‐manufactured components. Redox processes such as denitrification and uranium roll‐front propagation are observed. Biogeochemical redox processes control the chemical behavior of many major and trace elements, making their comprehension crucial for predicting and protecting environmental health. Nitrogen (N) is especially susceptible to changes in soil redox conditions and affects the cycles of other redox‐sensitive species. Elevated N concentrations, in nitrate form, in agricultural soils and associated freshwater ecosystems constitute a problem in many parts of the world. Although a wide variety of measures have been adopted, their assessment through concentration measurements in groundwater and surface water of the different monitoring networks has shortcomings. Nitrate, as a non‐point pollutant, is subject to several processes (e.g., transformation and retardation) before it is detected, making it impossible to evaluate measurements’ effectiveness reliably. Thus, we designed and constructed a monitoring station featuring commercially available products and self‐manufactured components at an agricultural site for the in situ assessment of nitrate‐related processes by high‐resolution monitoring of hydraulic (soil water content, matric potential, groundwater head) and hydrogeochemical variables (oxidation‐reduction potential and groundwater and pore water chemistry) within the vadose zone and the shallow aquifer. The monitoring station has proven to be a reliable tool. Changes over depth and time of measured variables have been identified, allowing the detection of the transient behavior of the redox reactive zone and the interpretation of ongoing denitrification processes and other redox nitrate‐triggered phenomena, such as uranium roll‐front and selenium accumulation at the redox interface. Measuring both geochemical and soil water variables allows for the calculation of in situ solute inputs into the groundwater and their reaction rates. Biogeochemical redox processes control the chemical behavior of many major and trace elements, making their comprehension crucial for predicting and protecting environmental health. Nitrogen (N) is especially susceptible to changes in soil redox conditions and affects the cycles of other redox‐sensitive species. Elevated N concentrations, in nitrate form, in agricultural soils and associated freshwater ecosystems constitute a problem in many parts of the world. Although a wide variety of measures have been adopted, their assessment through concentration measurements in groundwater and surface water of the different monitoring networks has shortcomings. Nitrate, as a non‐point pollutant, is subject to several processes (e.g., transformation and retardation) before it is detected, making it impossible to evaluate measurements’ effectiveness reliably. Thus, we designed and constructed a monitoring station featuring commercially available products and self‐manufactured components at an agricultural site for the in situ assessment of nitrate‐related processes by high‐resolution monitoring of hydraulic (soil water content, matric potential, groundwater head) and hydrogeochemical variables (oxidation‐reduction potential and groundwater and pore water chemistry) within the vadose zone and the shallow aquifer. The monitoring station has proven to be a reliable tool. Changes over depth and time of measured variables have been identified, allowing the detection of the transient behavior of the redox reactive zone and the interpretation of ongoing denitrification processes and other redox nitrate‐triggered phenomena, such as uranium roll‐front and selenium accumulation at the redox interface. Measuring both geochemical and soil water variables allows for the calculation of in situ solute inputs into the groundwater and their reaction rates. We propose a robust design for long‐term, high‐resolution monitoring of soil hydraulic and hydrogeochemical variables. It features a combination of commercially available products and self‐manufactured components. Redox processes such as denitrification and uranium roll‐front propagation are observed. |
| Author | Kübeck, Christine Muñoz‐Vega, Edinsson Schüth, Christoph Schulz, Stephan Berthold, Georg Richard‐Cerda, Juan Carlos Giber, Alexandra |
| Author_xml | – sequence: 1 givenname: Juan Carlos orcidid: 0000-0001-9020-2973 surname: Richard‐Cerda fullname: Richard‐Cerda, Juan Carlos email: richard.cerda@geo.tu-darmstadt.de organization: Technische Univ. Darmstadt – sequence: 2 givenname: Alexandra surname: Giber fullname: Giber, Alexandra organization: Water Resources Management – sequence: 3 givenname: Edinsson orcidid: 0000-0003-3893-1671 surname: Muñoz‐Vega fullname: Muñoz‐Vega, Edinsson organization: Technische Univ. Darmstadt – sequence: 4 givenname: Christine surname: Kübeck fullname: Kübeck, Christine organization: Water Resources Management – sequence: 5 givenname: Georg surname: Berthold fullname: Berthold, Georg organization: Hessian Agency for Nature Conservation, Environment and Geology (HLNUG), Groundwater – sequence: 6 givenname: Christoph surname: Schüth fullname: Schüth, Christoph organization: Water Resources Management – sequence: 7 givenname: Stephan orcidid: 0000-0001-7060-7690 surname: Schulz fullname: Schulz, Stephan organization: Technische Univ. Darmstadt |
| BackLink | https://www.ncbi.nlm.nih.gov/pubmed/36251299$$D View this record in MEDLINE/PubMed |
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| Cites_doi | 10.1021/acs.est.0c03056 10.2134/jeq2003.2158 10.1016/j.jhydrol.2012.04.041 10.1029/92WR00252 10.1016/j.scitotenv.2020.143026 10.2136/sssaj1992.03615995005600040011x 10.1021/es1038358 10.1088/1748‐9326/ab7d5c 10.2134/jeq2007.0218 10.1021/es9026248 10.1088/1748‐9326/aa7bf4 10.2136/vzj2016.07.0061 10.1029/2006WR004977 10.1029/2020WR028706 10.1021/es100546y 10.1016/j.agwat.2018.11.002 10.1130/GES00073.1 10.1016/j.jhydrol.2018.02.027 10.5194/hess‐20‐3099‐2016 10.1007/s10533‐006‐9032‐8 10.1111/gwat.12459 10.1073/pnas.1305372110 10.1021/acs.est.7b03087 10.2136/vzj2019.01.0008 10.1016/j.scitotenv.2020.140318 10.1016/j.scitotenv.2019.133655 10.1002/vzj2.20190 10.1016/j.watres.2008.07.020 10.2136/vzj2016.07.0058 10.2136/vzj2013.10.0176 10.1021/acs.est.6b01569 10.1016/j.jhydrol.2018.09.005 10.1007/s10040‐001‐0183‐3 10.1186/s12302‐020‐00382‐x 10.1021/es304609e 10.1016/j.envint.2006.05.002 10.2136/vzj2008.0134 10.2134/jeq1999.00472425002800040019x 10.1029/2020GB006626 10.1127/0941‐2948/2006/0130 10.5194/hess‐18‐333‐2014 10.1007/s00767‐009‐0129‐6 |
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| Copyright | 2022 The Authors. published by Wiley Periodicals LLC on behalf of American Society of Agronomy, Crop Science Society of America, and Soil Science Society of America. 2022 The Authors. Journal of Environmental Quality published by Wiley Periodicals LLC on behalf of American Society of Agronomy, Crop Science Society of America, and Soil Science Society of America. |
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| References | 2012; 448–449 2018; 560 2013; 47 2010; 15 2006; 32 2021; 763 1999; 28 2002; 10 2018; 566 2006; 15 2019; 18 2020; 34 2022; 21 2020; 32 2020; 54 2016; 15 1992; 56 2003; 32 2007; 36 2016; 55 2017; 51 2006; 81 2010; 44 2021; 57 2006; 42 2017; 17 2020 1992; 28 2019 2016; 20 2009; 8 2019; 213 2014; 13 2017 2011; 45 2015 2014; 18 2013; 110 2013 2008; 42 2007; 3 2020; 738 2019; 693 Bergmann A. (e_1_2_11_4_1) 2013 e_1_2_11_10_1 e_1_2_11_32_1 e_1_2_11_31_1 e_1_2_11_30_1 e_1_2_11_36_1 e_1_2_11_14_1 e_1_2_11_13_1 e_1_2_11_35_1 e_1_2_11_12_1 e_1_2_11_34_1 e_1_2_11_11_1 e_1_2_11_33_1 e_1_2_11_7_1 e_1_2_11_29_1 e_1_2_11_6_1 e_1_2_11_28_1 e_1_2_11_5_1 e_1_2_11_27_1 e_1_2_11_26_1 e_1_2_11_3_1 e_1_2_11_2_1 Weber F. A. (e_1_2_11_43_1) 2015 e_1_2_11_21_1 e_1_2_11_44_1 e_1_2_11_20_1 e_1_2_11_45_1 e_1_2_11_46_1 e_1_2_11_25_1 e_1_2_11_40_1 e_1_2_11_24_1 e_1_2_11_41_1 e_1_2_11_9_1 e_1_2_11_23_1 e_1_2_11_42_1 e_1_2_11_8_1 e_1_2_11_22_1 e_1_2_11_18_1 e_1_2_11_17_1 e_1_2_11_16_1 e_1_2_11_15_1 e_1_2_11_37_1 e_1_2_11_38_1 e_1_2_11_39_1 e_1_2_11_19_1 |
| References_xml | – volume: 10 start-page: 153 issue: 1 year: 2002 end-page: 179 article-title: Groundwater recharge and agricultural contamination publication-title: Hydrogeology Journal – volume: 566 start-page: 299 issue: August year: 2018 end-page: 312 article-title: Evaluating best management practices to lower selenium and nitrate in groundwater and streams in an irrigated river valley using a calibrated fate and reactive transport model publication-title: Journal of Hydrology – volume: 15 issue: 11 year: 2016 article-title: Estimating nitrate leaching to groundwater from orchards: Comparing crop nitrogen excess, deep vadose zone data‐driven estimates, and HYDRUS modeling publication-title: Vadose Zone Journal – volume: 18 start-page: 1 issue: 1 year: 2019 end-page: 8 article-title: Advanced in situ soil water sampling system for monitoring solute fluxes in the vadose zone publication-title: Vadose Zone Journal – volume: 45 start-page: 839 issue: 3 year: 2011 end-page: 844 article-title: Nitrogen contamination of surficial aquifers: A growing legacy publication-title: Environmental Science and Technology – volume: 28 start-page: 1657 issue: 6 year: 1992 end-page: 1668 article-title: Natural denitrification in the saturated zone: A review publication-title: Water Resources Research – volume: 763 year: 2021 article-title: Soil redox dynamics under dynamic hydrologic regimes: A review publication-title: Science of the Total Environment – volume: 42 start-page: 4215 issue: 16 year: 2008 end-page: 4232 article-title: Nitrate attenuation in groundwater: A review of biogeochemical controlling processes publication-title: Water Research – volume: 44 start-page: 15 issue: 1 year: 2010 end-page: 23 article-title: Biogeochemical redox processes and their impact on contaminant dynamics publication-title: Environmental Science and Technology – volume: 20 start-page: 3099 issue: 8 year: 2016 end-page: 3108 article-title: Real‐time monitoring of nitrate transport in the deep vadose zone under a crop field‐implications for groundwater protection publication-title: Hydrology and Earth System Sciences – volume: 17 issue: 1 year: 2017 article-title: Monitoring of water and solute transport in the vadose zone: A review publication-title: Vadose Zone Journal – volume: 51 start-page: 13806 issue: 23 year: 2017 end-page: 13815 article-title: High resolution monitoring above and below the groundwater table uncovers small‐scale hydrochemical gradients publication-title: Environmental Science and Technology – volume: 42 start-page: 1 issue: 12 year: 2006 end-page: 20 article-title: Timescales and development of groundwater pollution by nitrate in drinking water wells of the Jahna‐Aue, Saxonia, Germany publication-title: Water Resources Research – volume: 32 start-page: 831 issue: 6 year: 2006 end-page: 849 article-title: Ecological and toxicological effects of inorganic nitrogen pollution in aquatic ecosystems: A global assessment publication-title: Environment International – volume: 738 year: 2020 article-title: Assessing controls on selenium fate and transport in watersheds using the SWAT model publication-title: Science of the Total Environment – volume: 448–449 start-page: 195 year: 2012 end-page: 200 article-title: A simple rain collector preventing water re‐evaporation dedicated for δ O and δ H analysis of cumulative precipitation samples publication-title: Journal of Hydrology – volume: 55 start-page: 10 issue: 1 year: 2016 end-page: 26 article-title: Using diurnal temperature signals to infer vertical groundwater‐surface water exchange publication-title: Groundwater – volume: 21 issue: 3 year: 2022 article-title: Calibration and validation of soil water reflectometers publication-title: Vadose Zone Journal – volume: 47 start-page: 13941 issue: 24 year: 2013 end-page: 13948 article-title: Groundwater uranium origin and fate control in a river valley aquifer publication-title: Environmental Science and Technology – volume: 13 start-page: 1 issue: 4 year: 2014 end-page: 13 article-title: Investigation of groundwater recharge under agricultural fields using transient deep vadose zone data publication-title: Vadose Zone Journal – volume: 213 start-page: 568 year: 2019 end-page: 579 article-title: Performance evaluation of a recently developed soil water content, dielectric permittivity, and bulk electrical conductivity electromagnetic sensor publication-title: Agricultural Water Management – start-page: 12 issue: 8 year: 2017 article-title: Time lags in watershed‐scale nutrient transport: An exploration of dominant controls publication-title: Environmental Research Letters – volume: 18 start-page: 333 issue: 1 year: 2014 end-page: 341 article-title: Nitrate leaching from intensive organic farms to groundwater publication-title: Hydrology and Earth System Sciences – volume: 81 start-page: 95 issue: 1 year: 2006 end-page: 110 article-title: Redox fluctuations frame microbial community impacts on N‐cycling rates in a humid tropical forest soil publication-title: Biogeochemistry – volume: 3 start-page: 366 issue: 5 year: 2007 end-page: 380 article-title: Biogeochemistry at the zone of intermittent saturation: Field‐based study of the shallow alluvial aquifer, Rio Grande, New Mexico publication-title: Geosphere – volume: 54 start-page: 12092 issue: 19 year: 2020 end-page: 12101 article-title: Coupling flow, heat, and reactive transport modeling to reproduce in situ redox potential evolution: Application to an infiltration pond publication-title: Environmental Science & Technology – volume: 693 year: 2019 article-title: Nitrate‐dependent uranium mobilisation in groundwater publication-title: Science of the Total Environment – volume: 51 start-page: 337 issue: 1 year: 2017 end-page: 345 article-title: Redox roll‐front mobilization of geogenic uranium by nitrate input into aquifers: Risks for groundwater resources publication-title: Environmental Science and Technology – volume: 32 start-page: 2158 issue: 6 year: 2003 end-page: 2171 article-title: Long‐term effects of nitrogen fertilizer use on ground water nitrate in two small watersheds publication-title: Journal of Environmental Quality – volume: 8 start-page: 916 issue: 4 year: 2009 end-page: 925 article-title: In situ monitoring of water percolation and solute transport using a vadose zone monitoring system publication-title: Vadose Zone Journal – start-page: 15 issue: 6 year: 2020 article-title: Nation‐wide estimation of groundwater redox conditions and nitrate concentrations through machine learning publication-title: Environmental Research Letters – volume: 560 start-page: 512 year: 2018 end-page: 529 article-title: Simulating selenium and nitrogen fate and transport in coupled stream‐aquifer systems of irrigated regions publication-title: Journal of Hydrology – volume: 44 start-page: 4988 issue: 13 year: 2010 end-page: 4997 article-title: Nitrate in groundwater of the United States, 1991–2003 publication-title: Environmental Science and Technology – volume: 34 start-page: 1 issue: 9 year: 2020 end-page: 16 article-title: Long‐term shifts in U.S. nitrogen sources and sinks revealed by the new TREND‐Nitrogen data set (1930–2017) publication-title: Global Biogeochemical Cycles – volume: 56 start-page: 1071 year: 1992 end-page: 1073 article-title: Sequential reduction and oxidation of inorganic nitrogen, manganese, and iron in flooded soil publication-title: Soil Science Society of America Journal – volume: 15 start-page: 19 issue: 1 year: 2010 end-page: 32 article-title: Depth‐specific water sampling system for detailed sampling in the unsaturated zone, the capillary fringe and the saturated zone publication-title: Grundwasser – volume: 28 start-page: 1182 issue: 4 year: 1999 end-page: 1187 article-title: Oxidation and mobilization of selenium by nitrate in irrigation drainage publication-title: Journal of Environmental Quality – volume: 32 start-page: 109 issue: 1 year: 2020 article-title: Nitrogen soil surface budgets for districts in Germany 1995 to 2017 publication-title: Environmental Sciences Europe – year: 2019 – volume: 36 start-page: 1735 issue: 6 year: 2007 end-page: 1748 article-title: In situ soil water extraction: A review publication-title: Journal of Environmental Quality – volume: 57 issue: 8 year: 2021 article-title: On the propagation of reaction fronts in a sandy aquifer over 20+ years: Lessons from a test site in northwestern Germany publication-title: Water Resources Research – volume: 15 start-page: 259 issue: 3 year: 2006 end-page: 263 article-title: World map of the Köppen‐Geiger climate classification updated publication-title: Meteorologische Zeitschrift – year: 2015 – year: 2013 – volume: 110 start-page: 18185 issue: 45 year: 2013 end-page: 18189 article-title: Long‐term fate of nitrate fertilizer in agricultural soils publication-title: Proceedings of the National Academy of Sciences of the United States of America – ident: e_1_2_11_31_1 doi: 10.1021/acs.est.0c03056 – ident: e_1_2_11_36_1 doi: 10.2134/jeq2003.2158 – ident: e_1_2_11_14_1 doi: 10.1016/j.jhydrol.2012.04.041 – ident: e_1_2_11_20_1 doi: 10.1029/92WR00252 – ident: e_1_2_11_46_1 doi: 10.1016/j.scitotenv.2020.143026 – ident: e_1_2_11_25_1 doi: 10.2136/sssaj1992.03615995005600040011x – ident: e_1_2_11_28_1 doi: 10.1021/es1038358 – ident: e_1_2_11_19_1 doi: 10.1088/1748‐9326/ab7d5c – ident: e_1_2_11_44_1 doi: 10.2134/jeq2007.0218 – ident: e_1_2_11_7_1 doi: 10.1021/es9026248 – ident: e_1_2_11_40_1 doi: 10.1088/1748‐9326/aa7bf4 – ident: e_1_2_11_3_1 doi: 10.2136/vzj2016.07.0061 – ident: e_1_2_11_24_1 doi: 10.1029/2006WR004977 – ident: e_1_2_11_16_1 doi: 10.1029/2020WR028706 – ident: e_1_2_11_8_1 doi: 10.1021/es100546y – ident: e_1_2_11_18_1 doi: 10.1016/j.agwat.2018.11.002 – ident: e_1_2_11_41_1 doi: 10.1130/GES00073.1 – ident: e_1_2_11_33_1 doi: 10.1016/j.jhydrol.2018.02.027 – ident: e_1_2_11_38_1 doi: 10.5194/hess‐20‐3099‐2016 – ident: e_1_2_11_27_1 doi: 10.1007/s10533‐006‐9032‐8 – ident: e_1_2_11_17_1 doi: 10.1111/gwat.12459 – ident: e_1_2_11_32_1 doi: 10.1073/pnas.1305372110 – ident: e_1_2_11_13_1 doi: 10.1021/acs.est.7b03087 – ident: e_1_2_11_29_1 doi: 10.2136/vzj2019.01.0008 – volume-title: Quantifizierung des nitratabbauvermögens in den grundwasserkörpern des hessischen rieds und lokalisierung von risikogebieten year: 2015 ident: e_1_2_11_43_1 – ident: e_1_2_11_23_1 doi: 10.1016/j.scitotenv.2020.140318 – volume-title: Konsequenzen nachlassenden Nitratabbauvermögens in grundwasserleitern year: 2013 ident: e_1_2_11_4_1 – ident: e_1_2_11_6_1 doi: 10.1016/j.scitotenv.2019.133655 – ident: e_1_2_11_26_1 doi: 10.1002/vzj2.20190 – ident: e_1_2_11_30_1 doi: 10.1016/j.watres.2008.07.020 – ident: e_1_2_11_35_1 doi: 10.2136/vzj2016.07.0058 – ident: e_1_2_11_37_1 doi: 10.2136/vzj2013.10.0176 – ident: e_1_2_11_39_1 doi: 10.1021/acs.est.6b01569 – ident: e_1_2_11_34_1 doi: 10.1016/j.jhydrol.2018.09.005 – ident: e_1_2_11_5_1 doi: 10.1007/s10040‐001‐0183‐3 – ident: e_1_2_11_15_1 doi: 10.1186/s12302‐020‐00382‐x – ident: e_1_2_11_2_1 doi: 10.1021/es304609e – ident: e_1_2_11_10_1 doi: 10.1016/j.envint.2006.05.002 – ident: e_1_2_11_12_1 doi: 10.2136/vzj2008.0134 – ident: e_1_2_11_45_1 doi: 10.2134/jeq1999.00472425002800040019x – ident: e_1_2_11_9_1 doi: 10.1029/2020GB006626 – ident: e_1_2_11_21_1 doi: 10.1127/0941‐2948/2006/0130 – ident: e_1_2_11_11_1 doi: 10.5194/hess‐18‐333‐2014 – ident: e_1_2_11_42_1 doi: 10.1007/s00767‐009‐0129‐6 – ident: e_1_2_11_22_1 |
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| Snippet | Biogeochemical redox processes control the chemical behavior of many major and trace elements, making their comprehension crucial for predicting and protecting... |
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| SubjectTerms | aquifers denitrification Ecosystem environmental health Environmental Monitoring environmental quality freshwater groundwater Groundwater - chemistry groundwater flow hydrogeochemistry nitrates Nitrates - analysis nitrogen Oxidation-Reduction pollutants redox potential selenium Soil soil water soil water content solutes surface water uranium vadose zone Water Water Pollutants, Chemical - analysis |
| Title | A high‐resolution monitoring station for the in situ assessment of nitrate‐related redox processes at an agricultural site |
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