Groundwater Quality and Health: Making the Invisible Visible.

Linking groundwater quality to health will make the invisible groundwater visible, but there are knowledge gaps to understand the linkage which requires cross-disciplinary convergent research. The substances in groundwater that are critical to health can be classified into five types according to the sources and characteristics: geogenic substances, biogenic elements, anthropogenic contaminants, emerging contaminants, and pathogens. The most intriguing questions are related to quantitative assessment of human health and ecological risks of exposure to the critical substances via natural or induced artificial groundwater discharge: What is the list of critical substances released from discharging groundwater, and what are the pathways of the receptors' exposure to the critical substances? How to quantify the flux of critical substances during groundwater discharge? What procedures can we follow to assess human health and ecological risks of groundwater discharge? Answering these questions is fundamental for humans to deal with the challenges of water security and health risks related to groundwater quality. This perspective provides recent progresses, knowledge gaps, and future trends in understanding the linkage between groundwater quality and health.

[1]  Xilai Zheng,et al.  A critical review of the central role of microbial regulation in the nitrogen biogeochemical process: New insights for controlling groundwater nitrogen contamination. , 2022, Journal of environmental management.

[2]  S. K. Naik,et al.  Emerging groundwater contaminants: A comprehensive review on their health hazards and remediation technologies , 2022, Groundwater for Sustainable Development.

[3]  Tyler D. Johnson,et al.  Quality of Groundwater Used for Public Supply in the Continental United States: A Comprehensive Assessment , 2022, ACS ES&T Water.

[4]  J. Mahlknecht,et al.  Global groundwater vulnerability for Pharmaceutical and Personal care products (PPCPs): The scenario of second decade of 21st century. , 2022, Journal of environmental management.

[5]  J. Podgorski,et al.  Global analysis and prediction of fluoride in groundwater , 2022, Nature Communications.

[6]  S. Chakma,et al.  Ecological and human health risk assessment of chromite ore processing residue (COPR) dumpsites in Northern India: A multi–pathways based probabilistic risk approach , 2022, Process Safety and Environmental Protection.

[7]  E. Banks,et al.  Fault-controlled springs: A review , 2022, Earth-Science Reviews.

[8]  S. Muhammad,et al.  Spatial distribution of radon concentrations in groundwater and annual exposure doses in Mirpur District Pakistan , 2022, Groundwater for Sustainable Development.

[9]  M. Dippenaar,et al.  Potential SARS-CoV-2 contamination of groundwater as a result of mass burial: A mini-review , 2022, Science of The Total Environment.

[10]  Chunmiao Zheng,et al.  Plans to protect China’s depleted groundwater , 2022, Science.

[11]  S. M. Maliyekkal,et al.  A critical review of uranium contamination in groundwater: Treatment and sludge disposal. , 2022, The Science of the total environment.

[12]  P. Smedley,et al.  Groundwater quality: Global threats, opportunities and Realising the potential of groundwater. , 2021, The Science of the total environment.

[13]  L. Gómez-Coma,et al.  Global diagnosis of nitrate pollution in groundwater and review of removal technologies. , 2021, The Science of the total environment.

[14]  Xiaoshu Lü,et al.  Application of upscaling methods for fluid flow and mass transport in multi-scale heterogeneous media: A critical review , 2021 .

[15]  A. Vengosh,et al.  A critical review on the occurrence and distribution of the uranium- and thorium-decay nuclides and their effect on the quality of groundwater. , 2021, The Science of the total environment.

[16]  A. Surapaneni,et al.  Nitrogen contamination and bioremediation in groundwater and the environment: A review , 2021, Earth-Science Reviews.

[17]  Yan-xin Wang,et al.  Novel Insights into Dissolved Organic Matter Processing Pathways in a Coastal Confined Aquifer System with the Highest Known Concentration of Geogenic Ammonium. , 2021, Environmental Science and Technology.

[18]  J. Sorensen,et al.  Seasonality of enteric viruses in groundwater-derived public water sources. , 2021, Water research.

[19]  M. Shah,et al.  Origin, fate, and risk assessment of emerging contaminants in groundwater bodies: a holistic review , 2021, Emergent Materials.

[20]  Ping Wang,et al.  A review of water pollution arising from agriculture and mining activities in Central Asia: Facts, causes and effects. , 2021, Environmental pollution.

[21]  P. Papazotos Potentially toxic elements in groundwater: a hotspot research topic in environmental science and pollution research , 2021, Environmental Science and Pollution Research.

[22]  Martin S. Andersen,et al.  Quantifying groundwater carbon dioxide and methane fluxes to an urban freshwater lake using radon measurements. , 2021, Science of the Total Environment.

[23]  K. Al-Jabri,et al.  A critical review of environmental and public health impacts from the activities of evaporation ponds. , 2021, The Science of the total environment.

[24]  S. Jasechko,et al.  Global groundwater wells at risk of running dry , 2021, Science.

[25]  M. Perraki,et al.  Tracing the origin of chromium in groundwater: Current and new perspectives , 2021 .

[26]  Shamsad Ahmad,et al.  Groundwater Contamination by Hazardous Wastes , 2021, Arabian Journal for Science and Engineering.

[27]  A. Helton,et al.  Continental-scale analysis of shallow and deep groundwater contributions to streams , 2021, Nature Communications.

[28]  C. von Sperber,et al.  Groundwater phosphorus concentrations: global trends and links with agricultural and oil and gas activities , 2021, Environmental Research Letters.

[29]  T. Wagner,et al.  Groundwater discharges as a source of phytoestrogens and other agriculturally derived contaminants to streams. , 2021, The Science of the total environment.

[30]  Gautam Bisht,et al.  Coupling surface flow with high-performance subsurface reactive flow and transport code PFLOTRAN , 2021, Environ. Model. Softw..

[31]  Shan Zhao,et al.  Hot spots and hot moments of nitrogen removal from hyporheic and riparian zones: A review. , 2020, The Science of the total environment.

[32]  T. Russo,et al.  A Snapshot of the World's Groundwater Challenges , 2020 .

[33]  Jessica R. Meyer,et al.  The importance of transects for characterizing aged organic contaminant plumes in groundwater. , 2020, Journal of contaminant hydrology.

[34]  Yan-xin Wang,et al.  Genesis of geogenic contaminated groundwater: As, F and I , 2020, Critical Reviews in Environmental Science and Technology.

[35]  V. Uricchio,et al.  Chromium Pollution in European Water, Sources, Health Risk, and Remediation Strategies: An Overview , 2020, International journal of environmental research and public health.

[36]  Y. Charabi,et al.  Ecological and human health risk assessment , 2020, Water environment research : a research publication of the Water Environment Federation.

[37]  Dong Zhang,et al.  Impacts of the Sanmenxia Dam on the Interaction between Surface Water and Groundwater in the Lower Weihe River of Yellow River Watershed , 2020, Water.

[38]  Yan-xin Wang,et al.  Sources and enrichment of phosphorus in groundwater of the Central Yangtze River Basin. , 2020, The Science of the total environment.

[39]  V. Achal,et al.  Environmental and health impacts due to e-waste disposal in China - A review. , 2020, The Science of the total environment.

[40]  J. Podgorski,et al.  Global threat of arsenic in groundwater , 2020, Science.

[41]  M. Stute,et al.  Arsenic contamination of Bangladesh aquifers exacerbated by clay layers , 2020, Nature Communications.

[42]  Yan-xin Wang,et al.  Enrichment of geogenic ammonium in Quaternary alluvial-lacustrine aquifer systems: Evidence from carbon isotopes and DOM characteristics. , 2020, Environmental science & technology.

[43]  O. Alegbeleye,et al.  Manure-borne pathogens as an important source of water contamination: An update on the dynamics of pathogen survival/transport as well as practical risk mitigation strategies. , 2020, International journal of hygiene and environmental health.

[44]  Carol S. Woodward,et al.  Simulating coupled surface–subsurface flows with ParFlow v3.5.0: capabilities, applications, and ongoing development of an open-source, massively parallel, integrated hydrologic model , 2019, Geoscientific Model Development.

[45]  Biao Zhang,et al.  Hydrochemical Characteristics of Groundwater and Dominant Water–Rock Interactions in the Delingha Area, Qaidam Basin, Northwest China , 2020, Water.

[46]  M. Kumar,et al.  Sulphate contamination in groundwater and its remediation: an overview , 2020, Environmental Monitoring and Assessment.

[47]  I. Santos,et al.  Changes in global groundwater organic carbon driven by climate change and urbanization , 2018, Nature Communications.

[48]  L. Gill,et al.  A combined-method approach to trace submarine groundwater discharge from a coastal karst aquifer in Ireland , 2019, Hydrogeology Journal.

[49]  S. Schiff,et al.  Review of phosphorus attenuation in groundwater plumes from 24 septic systems. , 2019, The Science of the total environment.

[50]  Basak Guven,et al.  Microplastics in the environment: A critical review of current understanding and identification of future research needs. , 2019, Environmental pollution.

[51]  D. Oliver,et al.  Rainfall-driven E. coli transfer to the stream-conduit network observed through increasing spatial scales in mixed land-use paddy farming karst terrain , 2019, Water research X.

[52]  M. Walther,et al.  Effect of subsurface dams on saltwater intrusion and fresh groundwater discharge , 2019, Journal of Hydrology.

[53]  Xilai Zheng,et al.  The missing nitrogen pieces: A critical review on the distribution, transformation, and budget of nitrogen in the vadose zone-groundwater system. , 2019, Water research.

[54]  Yao Du,et al.  Spatial Variability of Nitrate and Ammonium in Pleistocene Aquifer of Central Yangtze River Basin , 2019, Ground water.

[55]  Hang Lv,et al.  Determination of major pollutant and biogeochemical processes in an oil-contaminated aquifer using human health risk assessment and multivariate statistical analysis , 2019 .

[56]  J. Leszczynski,et al.  Exploration of Computational Approaches to Predict the Toxicity of Chemical Mixtures , 2019, Toxics.

[57]  E. A. Ferreira da Silva,et al.  An Inter-disciplinary Approach to Evaluate Human Health Risks Due to Long-Term Exposure to Contaminated Groundwater Near a Chemical Complex , 2019, Exposure and Health.

[58]  Yan-xin Wang,et al.  Sedimentogenesis and hydrobiogeochemistry of high arsenic Late Pleistocene-Holocene aquifer systems , 2017, Earth-Science Reviews.

[59]  D. S. Glass,et al.  Vapor intrusion mitigation: Road map to successful sub‐slab depressurization at sites with shallow water tables , 2018, Environmental Progress & Sustainable Energy.

[60]  P. Schuler,et al.  Submarine and intertidal groundwater discharge through a complex multi-level karst conduit aquifer , 2018, Hydrogeology Journal.

[61]  B. Xi,et al.  Distribution, formation and human-induced evolution of geogenic contaminated groundwater in China: A review. , 2018, The Science of the total environment.

[62]  Yan-xin Wang,et al.  Review: Safe and sustainable groundwater supply in China , 2018, Hydrogeology Journal.

[63]  Yilong Zhang,et al.  Review: Groundwater resources and related environmental issues in China , 2018, Hydrogeology Journal.

[64]  S. Nagel,et al.  Endocrine-Disrupting Activities and Organic Contaminants Associated with Oil and Gas Operations in Wyoming Groundwater , 2018, Archives of Environmental Contamination and Toxicology.

[65]  Caren L. S. Vilela,et al.  Water contamination by endocrine disruptors: Impacts, microbiological aspects and trends for environmental protection. , 2018, Environmental pollution.

[66]  M. Raessler The Arsenic Contamination of Drinking and Groundwaters in Bangladesh: Featuring Biogeochemical Aspects and Implications on Public Health , 2018, Archives of Environmental Contamination and Toxicology.

[67]  Kristine Walraevens,et al.  Groundwater Overexploitation and Seawater Intrusion in Coastal Areas of Arid and Semi-Arid Regions , 2018 .

[68]  M. Robson,et al.  Using urine as a biomarker in human exposure risk associated with arsenic and other heavy metals contaminating drinking groundwater in intensively agricultural areas of Thailand , 2018, Environmental Geochemistry and Health.

[69]  D. Blowes,et al.  Storage and Preservation of Artificial Sweeteners in Groundwater Samples , 2017 .

[70]  C. Binder,et al.  Local groundwater balance model: stakeholders’ efforts to address groundwater monitoring and literacy , 2017 .

[71]  M. Puma,et al.  Groundwater depletion embedded in international food trade , 2017, Nature.

[72]  J. Lebov,et al.  A framework for One Health research , 2017, One Health.

[73]  M. Borchardt,et al.  Review: Epidemiological evidence of groundwater contribution to global enteric disease, 1948–2015 , 2017, Hydrogeology Journal.

[74]  S. Harrad,et al.  Pharmaceuticals and personal care products (PPCPs) in the freshwater aquatic environment , 2017 .

[75]  M. Rizwan,et al.  Human health risk assessment of arsenic in groundwater aquifers of Lahore, Pakistan , 2017 .

[76]  R. Bailey Review: Selenium contamination, fate, and reactive transport in groundwater in relation to human health , 2017, Hydrogeology Journal.

[77]  Todor G. Baychev,et al.  Review of pore network modelling of porous media: Experimental characterisations, network constructions and applications to reactive transport. , 2016, Journal of contaminant hydrology.

[78]  Peiyue Li,et al.  Groundwater Quality in Western China: Challenges and Paths Forward for Groundwater Quality Research in Western China , 2016, Exposure and Health.

[79]  Z. Rao,et al.  Perfluorinated compounds in soil, surface water, and groundwater from rural areas in eastern China. , 2016, Environmental pollution.

[80]  M. Barnett,et al.  Decreased Salinity and Actinide Mobility: Colloid-Facilitated Transport or pH Change? , 2016, Environmental science & technology.

[81]  E. McBean,et al.  A critical review of arsenic exposures for Bangladeshi adults. , 2015, The Science of the total environment.

[82]  R. Corsi,et al.  Relationship between vapor intrusion and human exposure to trichloroethylene , 2015, Journal of environmental science and health. Part A, Toxic/hazardous substances & environmental engineering.

[83]  Ilenia Battiato,et al.  An Analysis Platform for Multiscale Hydrogeologic Modeling with Emphasis on Hybrid Multiscale Methods , 2015, Ground water.

[84]  M. Charette,et al.  Hydrologic controls on nutrient cycling in an unconfined coastal aquifer. , 2014, Environmental science & technology.

[85]  C. Steefel,et al.  Pore-scale controls on calcite dissolution rates from flow-through laboratory and numerical experiments. , 2014, Environmental science & technology.

[86]  E. O’Loughlin,et al.  Sulfur-mediated electron shuttling during bacterial iron reduction , 2014, Science.

[87]  Henning Prommer,et al.  Prediction of diffuse sulfate emissions from a former mining district and associated groundwater discharges to surface waters , 2014 .

[88]  A. Kappler,et al.  Humic substances as fully regenerable electron acceptors in recurrently anoxic environments , 2014 .

[89]  M. Berg,et al.  Groundwater Arsenic Contamination Throughout China , 2013, Science.

[90]  B. Scanlon,et al.  Ground water and climate change , 2013 .

[91]  Glenn E. Hammond,et al.  Elucidating geochemical response of shallow heterogeneous aquifers to CO2 leakage using high-performance computing: Implications for monitoring of CO2 sequestration , 2013 .

[92]  K. Hatfield,et al.  A stochastic model for estimating groundwater and contaminant discharges from fractured rock passive flux meter measurements , 2013 .

[93]  L. V. Beek,et al.  Water balance of global aquifers revealed by groundwater footprint , 2012, Nature.

[94]  H. Albrechtsen,et al.  Identification of discharge zones and quantification of contaminant mass discharges into a local stream from a landfill in a heterogeneous geologic setting , 2012 .

[95]  L Posthuma,et al.  State of the art of contaminated site management in The Netherlands: policy framework and risk assessment tools. , 2012, The Science of the total environment.

[96]  E. Topp,et al.  Role of livestock in microbiological contamination of water: Commonly the blame, but not always the source , 2012 .

[97]  D. Lapworth,et al.  Emerging organic contaminants in groundwater: A review of sources, fate and occurrence. , 2012, Environmental pollution.

[98]  C. Simmons,et al.  HydroGeoSphere: A Fully Integrated, Physically Based Hydrological Model , 2012 .

[99]  D. Lapworth,et al.  Review of risk from potential emerging contaminants in UK groundwater. , 2012, The Science of the total environment.

[100]  M. Warne,et al.  Quantifying reduction in ecological risk in Penrhyn Estuary, Sydney, Australia, following groundwater remediation , 2012, Integrated environmental assessment and management.

[101]  D. Labat,et al.  Modeling of water-rock interaction in the Mackenzie basin: Competition between sulfuric and carbonic acids , 2011 .

[102]  H. Jarvie,et al.  Understanding Phosphorus Mobility and Bioavailability in the Hyporheic Zone of a Chalk Stream , 2011 .

[103]  Karsten Pruess,et al.  TOUGHREACT Version 2.0: A simulator for subsurface reactive transport under non-isothermal multiphase flow conditions , 2011, Comput. Geosci..

[104]  Scott Fendorf,et al.  Spatial and Temporal Variations of Groundwater Arsenic in South and Southeast Asia , 2010, Science.

[105]  M. Warne,et al.  Site‐specific probabilistic ecological risk assessment of a volatile chlorinated hydrocarbon‐contaminated tidal estuary , 2010, Environmental toxicology and chemistry.

[106]  M. K. Landon,et al.  Depth-dependent sampling to identify short-circuit pathways to public-supply wells in multiple aquifer settings in the United States , 2010 .

[107]  Verónica M. Vieira,et al.  Using Residential History and Groundwater Modeling to Examine Drinking Water Exposure and Breast Cancer , 2010, Environmental Health Perspectives.

[108]  P. Laurberg,et al.  Iodine intake as a determinant of thyroid disorders in populations. , 2010, Best practice & research. Clinical endocrinology & metabolism.

[109]  C. H. Ward,et al.  In Situ Remediation of Chlorinated Solvent Plumes , 2010 .

[110]  M. Stute,et al.  Redox trapping of arsenic during groundwater discharge in sediments from the Meghna riverbank in Bangladesh , 2009, Proceedings of the National Academy of Sciences.

[111]  M. Charette,et al.  Field, laboratory, and modeling study of reactive transport of groundwater arsenic in a coastal aquifer. , 2009, Environmental science & technology.

[112]  Hermann Fromme,et al.  Perfluorinated compounds--exposure assessment for the general population in Western countries. , 2009, International journal of hygiene and environmental health.

[113]  J. Samper,et al.  A Subgrid-Scale Stabilized Finite Element Method for Multicomponent Reactive Transport through Porous Media , 2009 .

[114]  A. Geen Environmental science: Arsenic meets dense populations , 2008 .

[115]  S. Kanae,et al.  Global Hydrological Cycles and World Water Resources , 2006, Science.

[116]  D. Clifford,et al.  Preservation of inorganic arsenic species in groundwater. , 2005, Environmental science & technology.

[117]  T. Reilly,et al.  Flow and Storage in Groundwater Systems , 2002, Science.

[118]  D. Kampbell,et al.  Improved Method for the Storage of Groundwater Samples Containing Volatile Organic Analytes , 1999, Archives of Environmental Contamination and Toxicology.