[1] Ibrahim M. Makhadmeh, Seba F. Gharaiebeh and Ammar A. Albalasmeh. (2021). Impact of Irrigation with Treated Domestic Wastewater on Squash (Cucurbita pepo L.) Fruit and Seed under Semi Arid Conditions. Horticulturae 2021, 7, 226. https://doi.org/10.3390/horticulturae7080226
[2] Awoke Guadie, Asamin Yesigat, Shetie Gatew, Abebe Worku, Wenzong Liu, Mengist Minale, Aijie Wang. (2021). Effluent quality and reuse potential of urban wastewater treated with aerobic-anoxic system: A practical illustration for environmental contamination and human health risk assessment, Journal of Water Process Engineering, Volume 40, https://doi.org/10.1016/j.jwpe.2020.101891.
[3] Rasheed, F.; Zafar, Z.; Waseem, Z.A.; Rafay, M.; Abdullah, M.; Salam, M.M.A.; Mohsin, M.; Khan, W.R. (2020). Phytoaccumulation of Zn, Pb, and Cd in Conocarpus lancifolius irrigated with wastewater: Does physiological response influence heavy metal uptake? Int. J. Phytoremediat. 22, 287–294. [CrossRef]
[4] Quist-Jensen, C.A.; Macedonio, F.; Drioli, E. (2015). Membrane technology for water production in agriculture: Desalination and wastewater reuse. Desalination 2015, 364, 17–32. [CrossRef]
[5] Farhadkhani, M.; Nikaeen, M.; Yadegarfar, G.; Hatamzadeh, M.; Pourmohammadbagher, H.; Sahbaei, Z.; Rahmani, H.R. (2018). Effects of irrigation with secondary treated wastewater on physicochemical and microbial properties of soil and produce safety in a semiarid area. Water Res. 144, 356–364. [CrossRef]
[6] Abbruzzini, T.F.; Silva, C.A.; de Andrade, D.A.; de Oliveira Carneiro, W.J. (2014). Influence of digestion methods on the recovery of Iron, Zinc, Nickel, Chromium, Cadmium and Lead contents in 11 organic residues. Rev. Bras. Ciência Solo 2014, 38, 166–176. [CrossRef
[7] FAO (Food and Agricultural Organization), 2008. Soil Bulletin 55, Guidelines: Land Evaluation for Irrigated Agriculture. Agriculture Organization of the United Nation. Roma, Italy.
[8] Walkley A and Black A. (1934). An examination of degtjareff method for determining soil organic matter and a proposed modification of the chromic acid titration method, Soil Science, (37): 29–37,View at Google Scholar.
[9] Boyadgiev, T. and Sayegh, A.H. 1992. Forms of evolution of gypsum in arid soils
and soil parent materials. Pedologie, XL11-2, pp.171-182.
[10] Okalebo, J.R., Gathua, K.W. and Woomer, P.L. (2002) Laboratory Methods for Soil and Plant Analysis: A Working Manual. TSBF, Nairobi.
[11] US Salinity Laboratory Staff (1954) Diagnosis and improvement of saline and alkali soils. US Department of Agriculture Handbook 60, Washington, DC.
[12] Fikret Ustaoğlu, Beyhan Taş, Yalçın Tepe and Halim Topaldemir, (2021) Comprehensive assessment of water quality and associated health risk by using physicochemical quality indices and multivariate analysis in Terme River, Turkey, Environmental Science and Pollution Research
[13] Elsiddig Eldaw, Tao Huang, Adam Khalifa Mohamed, Yahaya Mahama. (2021). Classification of groundwater suitability for irrigation purposes using a comprehensive approach based on the AHP and GIS techniques in North Kurdufan Province, Sudan, Applied Water Science 11:126 https://doi.org/10.1007/s13201-021-01443-z
[14]Mbagwu JSC. (1992). Improving the productivity of a degraded Ultisol in Nigera using organic and inorganic amendment. Part 2. Change in physical properties, Bioresource technology 42.
[15] Magesan GN. (2001). Change in soil physical properties after irrigation of two forested soils with municipal wastewater. New Zealand Journal of forestry science 31(2): 180;195.
[16] Mohammad, M.J. and Mazahreh, N. (2003) Changes in Soil Fertility Parameters in Response to Irrigation of Forage Crops with Secondary Treated Wastewater. Communications in Soil Science and Plant Analysis, 34, 1281-1294. http://dx.doi.org/10.1081/CSS-120020444
[17] Hazelton, P. and Murphy, B. (2007). Interpreting Soil Test Results: What do all the Numbers mean?. CSIRO Publishing, Collingwood, Victoria, 2007. xi+152 pp. Aus$59.95, paperback. ISBN 978-0-643092-25-9.
[18] Kiran DH. Ladwani D, Krishna S, Vivek, D. Ramteke S. (2012). Impact Wastewater Irrigation on Soil Properties and Crop Yield. International Journal of Scientific and ResearchPublications, 2(10): 164 -172.
[19] Vieira C, Morais S, Ramos S, Delerue-Matos C and Oliveira, M.B.P.P. (2011). Mercury, cadmium, lead and arsenic levels in three pelagic fish species from the Atlantic Ocean: intra- and inter specific variability and human health risks for consumption. Journal of Food and Chemical Toxicology, 49: 923-932.
[20] Jomova K and Valko M. (2010). Advances in metal-induced oxidative stress and human disease. Journal of Toxicology, 283: 65–87.
[21] Berglund S, Davis RD and Hernite P. (1984). Utilization of sewage sludge on land: rates of application and long-term effects of metals. Dordrecht: D. Reidel Publishing, 216p.
[22] Rezapour S. and Samadi A. (2011). Nutr Cycl Agroecosys 269.
[23] Mohammad Rusan, M.J., S. Hinnawi, and L. Rousan. 2007. Long term effect of wastewater irrigation of forage crops on soil and plant quality parameters. Desalination 215:143–152.
[24] Vassanda Coumar Mounissamy, Raghbendra Singh Parihar, Anil Kumar Dwivedi, Jayanta Kumar Saha, Selladurai Rajendiran, Brij Lal Lakaria & Ashok Kumar Patra. (2021). Effects of Co‐composting of Municipal Solid Waste and Pigeon Pea Biochar on Heavy Metal Mobility in Soil and Translocation to Leafy Vegetable Spinach. Bulletin of Environmental Contamination and Toxicology volume 106, pages 536–544 (2021)
[25] Rattan R.K., Datta S.P., Chhonkar P.K. Suribabu K. Singh A.K. (2005). Long-term impact of irrigation with sewage effluents on heavy metal content in soils, crops and groundwater—a case study. Agriculture, Ecosystems and Environment 109 (2005) 310—322