[1] W. Malik,C. Mohan, A.P. Annachhatre, Community based biogas plant utilizing food waste and cow dung, Materials Today: Proceedings, Volume 28, Part 3 (2020) 1910-1915.
[2] O. Sarkar, K. Sai, S. Butti, M. Venkata, Acidogenic biorefinery: food waste valorization to biogas and platform chemicals, Waste Biorefinery Potential Perspect , Elsevier ,2018.
[3] FAO, Food Wastage Footprint: Impacts on Natural Resources, FAO, Rome, 2013.
[4] M.K.O. Ayomoh, S.A. Oke, W.O. Adedeji, O.E. Charles, An approach to tackling the environmental and health impacts of municipal solid waste disposal in developing countries, J. Environ. Manag. 88 (2008) 108–114.
[5] D. Hoornweg, P.B. Tata, What a waste: a global review of solid waste management, Urban Dev Ser Knowl Pap ,2012.
[6] Z. Yousefi, A.I. Amouei, H. Asgharnia, A. Nemati, M.Vaezzadeh. Compost production from household solid wastes by earthworms, Journal of Babol University of Medical Sciences 14 (2012) 30-35.
[7] H. Mashad, R. Zhang. Biogas production from co-digestion of dairy manure and food waste, Bioresource Technology 101 (2010) 4021–4028.
[8] A. R. Pati1, S. Saroha1, A. P. Behera, S. S. Mohapatra1, S. S. Mahanand, The Anaerobic digestion of waste food materials by using cow dung: a new methodology to produce biogas. Journal of The Institution of Engineers (India): Series E volume 100 (2019)111–120.
[9] Z. Wang, Y. Jiang, S. Wang, Y.Zhang , Y. Hu, Z. Hu, G. Wu, X. Zhan, Impact of total solids content on anaerobic co-digestion of pig manure and food waste: Insights into shifting of the methanogenic pathway, Waste Management 114 (2020) 96–106
[10] A. R.nska, B. Karwowsk, Dynamics of changes in coplanar and indicator PCB in sewage sludgeduring mesophilic methane digestion. 323, Part A, 5 (2017) 341-349.
[11] A.Akhiar, A. Battimelli, M.T.Carrere. "Comprehensive characterization of the liquid fraction of digestates from full-scale anaerobic co-digestion." Waste management 59 (2017) 118-128.
[12] Sawatdeenarunat, Chayanon, K. C. Surendra, Devin Takara, Hans Oechsner, and Samir Kumar Khanal. "Anaerobic digestion of lignocellulosic biomass: challenges and opportunities." Bioresource technology 178 (2015): 178-186.
[13] Wahing .I,W.Van,V.J.G.Houba, J.J.Van der lee..Soil and plant analysis,a series of syllabi.part 7,plant analysis procedure.wageningen agriculture university, 1989.
[14] Perkin Elmer, 1982.Analytical methods for atomic absorbtion spectrophotometry, 1989.
[15] APHA, AWWA, WEF. Standard methods for the examination of water and wastewater. 23rd edition, 2017. Washington, DC 20001- 3710.
[16] Lee, D. H., Behera, S. K., Kim, J. W., & Park, H. S. Methane production potential of leachate generated from Korean food waste recycling facilities: a lab-scale study. Waste Management, 29(2)(2009) 876-882.
[17] Horiuchi, J. I., Shimizu, T., Kanno, T., & Kobayashi, M. Dynamic behavior in response to pH shift during anaerobic acidogenesis with a chemostat culture. Biotechnology techniques, 13(3)(1999) 155-157.
[18] Lemmer, A., Merkle, W., Baer, K., & Graf, F. (2017). Effects of high-pressure anaerobic digestion up to 30 bar on pH-value, production kinetics and specific methane yield. Energy, 138, 659-667.
[19] Vongvichiankul, C., Deebao, J., & Khongnakorn, W. Relationship between pH, oxidation reduction potential (ORP) and biogas production in mesophilic screw anaerobic digester. Energy Procedia, 138(2017)877-882.
[20] Gedefaw, M. Biogas production from cow dung and food waste. Glob. J. Pollut. Hazard. Waste Manage,3(1) (2015) 103-108.
[21] Gou, C., Yang, Z., Huang, J., Wang, H., Xu, H., & Wang, L. Effects of temperature and organic loading rate on the performance and microbial community of anaerobic co-digestion of waste activated sludge and food waste. Chemosphere, 105(2014)146-151.
[22] Rosińska, A., & Karwowska, B. Dynamics of changes in coplanar and indicator PCB in sewage sludge during mesophilic methane digestion. Journal of hazardous materials, 323(2017) 341-349.