http://orcid.org/0000-0003-4464-3078
References
- Al-Dabbous AN and Kumar P. 2015. Source apportionment of airborne nanoparticles in a Middle Eastern city using positive matrix factorization. Environ Sci Process Impacts 17(4):802–12
- Al-Shaibani AM. 2008. Hydrogeology and hydrochemistry of a shallow alluvial aquifer, western Saudi Arabia. Hydrogeol J 16(1):155–65
- Brown SG, Eberly S, Paatero P, et al. 2015. Methods for estimating uncertainty in PMF solutions: Examples with ambient air and water quality data and guidance on reporting PMF results. Sci Tot Environ 518:626–35
- Çamdevýren H, Demýr N, Kanik A, et al. 2005. Use of principal component scores in multiple linear regression models for prediction of Chlorophyll-a in reservoirs. Ecol Model 181(4):581–9
- Carrillo-Rivera JJ, Cardona A, and Edmunds WM. 2002. Use of abstraction regime and knowledge of hydrogeological conditions to control high-fluoride concentration in abstracted groundwater: San Luis Potosı basin, Mexico. J Hydrol 261(1):24–47
- Chae JS, Choi MS, Song YH, et al. 2014. Source identification of heavy metal contamination using metal association and Pb isotopes in Ulsan Bay sediments, East Sea, Korea. Mar Pollut Bull 88(1):373–82
- Chan YC, Hawas O, Hawker D, et al. 2011. Using multiple type composition data and wind data in PMF analysis to apportion and locate sources of air pollutants. Atmos Environ 45(2):439–49
- Chen H, Teng Y, Li J, et al. 2016. Source apportionment of trace metals in river sediments: A comparison of three methods. Environ Pollut 211:28–37
- Chen J, He D, and Cui S. 2003. The response of river water quality and quantity to the development of irrigated agriculture in the last 4 decades in the Yellow River Basin, China. Water Resour Res 39(3):1–11
- Chen K, Jiao JJ, Huang J, et al. 2007. Multivariate statistical evaluation of trace elements in groundwater in a coastal area in Shenzhen, China. Environ Pollut 147(3):771–80
- Cho JC, Cho HB, and Kim SJ. 2000. Heavy contamination of a subsurface aquifer and a stream by livestock wastewater in a stock farming area, Wonju, Korea. Environ Pollut 109(1):137–46
- Clague JC, Stenger R, and Clough TJ. 2015. Evaluation of the stable isotope signatures of nitrate to detect denitrification in a shallow groundwater system in New Zealand. Agric Ecosyst Environ 202:188–97
- Clarke R, Healy MG, Fenton O, et al. 2016. A quantitative risk ranking model to evaluate emerging organic contaminants in biosolid amended land and potential transport to drinking water. Hum Ecol Risk Assess Int J 22(4):958–90
- Cloutier V, Lefebvre R, Therrien R, et al. 2008. Multivariate statistical analysis of geochemical data as indicative of the hydrogeochemical evolution of groundwater in a sedimentary rock aquifer system. J Hydrol 353(3):294–313
- Dai G, Wang B, Fu C, et al. 2016. Pharmaceuticals and personal care products (PPCPs) in urban and suburban rivers of Beijing, China: Occurrence, source apportionment and potential ecological risk. Environ Sci Process Impacts 18(4):445–55
- D'Alessio M, Yoneyama B, and Ray C. 2015. Fate of selected pharmaceutically active compounds during simulated riverbank filtration. Sci Tot Environ 505:615–22
- Datry T, Malard F, and Gibert J. 2004. Dynamics of solutes and dissolved oxygen in shallow urban groundwater below a stormwater infiltration basin. Sci Tot Environ 329(1):215–29
- Dsikowitzky L and Schwarzbauer J. 2014. Industrial organic contaminants: Identification, toxicity and fate in the environment. Environ Chem Lett 12(3):371–86
- Farooqi A, Masuda H, and Firdous N. 2007. Toxic fluoride and arsenic contaminated groundwater in the Lahore and Kasur districts, Punjab, Pakistan and possible contaminant sources. Environ Pollut 145(3):839–49
- Galloway JN. 2005. The global nitrogen cycle: Past, present and future. Sci China Ser C Life Sci 48(2):669–78
- Gulgundi MS and Shetty A. 2016. Identification and apportionment of pollution sources to groundwater quality. Environ Process 3(2):451–61
- Helena B, Pardo R, Vega M, et al. 2000. Temporal evolution of groundwater composition in an alluvial aquifer (Pisuerga River, Spain) by principal component analysis. Water Res 34(3):807–16
- Jaeckels JM, Bae MS, and Schauer JJ. 2007. Positive matrix factorization (PMF) analysis of molecular marker measurements to quantify the sources of organic aerosols. Environ Sci Technol 41(16):5763–9
- Khan S, Rauf R, Muhammad S, et al. 2016. Arsenic and heavy metals health risk assessment through drinking water consumption in the Peshawar District, Pakistan. Hum Ecol Risk Assess Int J 22(3):581–96
- Ki MG, Koh DC, Yoon H, et al. 2015. Temporal variability of nitrate concentration in groundwater affected by intensive agricultural activities in a rural area of Hongseong, South Korea. Environ Earth Sci 74(7):6147–61
- Koh DC, Ko KS, Kim Y, et al. 2007. Effect of agricultural land use on the chemistry of groundwater from basaltic aquifers, Jeju Island, South Korea. Hydrogeol J 15(4):727–43
- Larsen RK and Baker JE. 2003. Source apportionment of polycyclic aromatic hydrocarbons in the urban atmosphere: A comparison of three methods. Environ Sci Technol 37(9):1873–81
- Lockhart KM, King AM, and Harter T. 2013. Identifying sources of groundwater nitrate contamination in a large alluvial groundwater basin with highly diversified intensive agricultural production. J Contam Hydrol 151:140–54
- Lu J, Jiang P, Wu L, et al. 2008. Assessing soil quality data by positive matrix factorization. Geoderma 145(3):259–66
- Machiwal D and Jha MK. 2015. Identifying sources of groundwater contamination in a hard-rock aquifer system using multivariate statistical analyses and GIS-based geostatistical modeling techniques. J Hydrol Region Stud 4:80–110
- Menció A, Mas-Pla J, Otero N, et al. 2016. Nitrate pollution of groundwater; all right…, but nothing else? Sci Tot Environ 539:241–51
- Mondal D, Gupta S, Reddy DV, et al. 2014. Geochemical controls on fluoride concentrations in groundwater from alluvial aquifers of the Birbhum district, West Bengal, India. J Geochem Explor 145:190–206
- Panagopoulos GP. 2014. Assessing the impacts of socio-economic and hydrological factors on urban water demand: A multivariate statistical approach. J Hydrol 518:42–8
- Pekey H and Doğan G. 2013. Application of positive matrix factorisation for the source apportionment of heavy metals in sediments: A comparison with a previous factor analysis study. Microchem J 106:233–7
- Pujari PR and Deshpande V. 2005. Source apportionment of groundwater pollution around landfill site in Nagpur, India. Environ Monit Assess 111(1–3):43–54
- Re V, Sacchi E, Mas-Pla J, et al. 2014. Identifying the effects of human pressure on groundwater quality to support water management strategies in coastal regions: a multi-tracer and statistical approach (Bou-Areg region, Morocco). Sci Tot Environ 500:211–23
- Rizzo MJ and Scheff PA. 2007. Utilizing the chemical mass balance and positive matrix factorization models to determine influential species and examine possible rotations in receptor modeling results. Atmos Environ 41(33):6986–98
- Singh KP, Malik A, Mohan D, et al. 2004. Multivariate statistical techniques for the evaluation of spatial and temporal variations in water quality of Gomti River (India)—A case study. Water Research 38(18):3980–92
- Sofowote UM, McCarry BE, and Marvin CH. 2008. Source apportionment of PAH in Hamilton Harbour suspended sediments: Comparison of two factor analysis methods. Environ Sci Technol 42(16):6007–14
- Tariq SR, Shah MH, Shaheen N, et al. 2008. Statistical source identification of metals in groundwater exposed to industrial contamination. Environ Monit Assess 138(1–3):159–65
- Tariq SR, Shah MH, Shaheen N, et al. 2006. Multivariate analysis of trace metal levels in tannery effluents in relation to soil and water: A case study from Peshawar, Pakistan. J Environ Manag 79(1):20–9
- Teixeira EC, Agudelo-Castañeda DM, and Mattiuzi CDP. 2015. Contribution of polycyclic aromatic hydrocarbon (PAH) sources to the urban environment: A comparison of receptor models. Sci Tot Environ 538:212–9
- Vaccaro S, Sobiecka E, Contini S, et al. 2007. The application of positive matrix factorization in the analysis, characterisation and detection of contaminated soils. Chemosphere 69(7):1055–63
- Wheeler DC, Nolan BT, Flory AR, et al. 2015. Modeling groundwater nitrate concentrations in private wells in Iowa. Sci Tot Environ 536:481–8
- Wolska L, Mechlińska A, Rogowska J, et al. 2014. Polychlorinated biphenyls (PCBs) in bottom sediments: Identification of sources. Chemosphere 111:151–6
- Xiao J, Jin Z, and Zhang F. 2015. Geochemical controls on fluoride concentrations in natural waters from the middle Loess Plateau, China. J Geochem Explor 159:252–61
- Yan S, Liu Y, Liu C, et al. 2016. Nitrate bioreduction in redox-variable low permeability sediments. Sci Tot Environ 539:185–95
- Zeng X, Wu J, Wang D, et al. 2016. Assessing the pollution risk of a groundwater source field at western Laizhou Bay under seawater intrusion. Environ Res 148:586–94
- Zhou F, Huang GH, Guo H, et al. 2007. Spatio-temporal patterns and source apportionment of coastal water pollution in eastern Hong Kong. Water Res 41(15):3429–39
- Zuo R, Ma DS, Liu L, et al. 2015. Distribution of ammonia nitrogen in riverside water source field and identification of influencing factors. J Beijing Normal Univ (Nat Sci) 51(6):626–30 ( in Chinese)