Mathematical modeling of cations from non-edible food waste for the reclamation of sodic and saline soils

Year 2025, Volume: 14 Issue: 1, 38 - 45, 01.01.2025

Md. Rezwanul Islam Qingyue Wang Sumaya Sharmin Weiqian Wang Christian Ebere Enyoh

https://doi.org/10.18393/ejss.1565860

Abstract

Nutritional disparity is a crucial impediment to agricultural productivity that interferes with soil structural stability and plant growth since more than one-fourth of the total land area is affected, especially by sodicity globally. This study assesses the mathematical models of non-edible food waste, including brinjal waste, potato peel, banana peel, orange peel, eggshell, cow bone, chicken bone, and fish bone. After consumption of the food, the resulting non-edible food waste was cleaned, dried, crushed, and stored separately in aluminum zipper bags. Cation concentrations of the considered waste materials were measured using ion chromatography systems. Then the mathematical models such as Exchangeable Sodium Percentage (ESP), Exchangeable Potassium Percentage (EPP), Sodium Adsorption Ratio (SAR), Potassium Adsorption Ratio (PAR), and Cation Ratio of Soil Structural Stability (CROSS) were assessed considering cation concentrations. The results revealed that Na+ concentrations ranged from 0.17±0.001 mg/kg in orange peel to 5.21±0.005 mg/kg in chicken bone; K+ ranged from 0.28±0.003 mg/kg in eggshell to 56.50±0.216 mg/kg in banana peel; Ca2+ ranged from 0.30±0.004 mg/kg in potato peel to 1.37±0.049 mg/kg in eggshell; and Mg2+ ranged from 0.06±0.004 mg/kg in eggshell to 1.12±0.006 mg/kg in banana peel. The overall concentration sequence was K+>Na+>Ca2+>Mg2+. In addition, animal waste biomass had comparatively high ESP and EPP values for the studied waste biomasses. SAR, PAR, and CROSS models for all studied wastes are suitable for application to sodic and saline soils. In conclusion, non-edible food waste biomass might be a reliable source of cations that is important for soil structural stability and ultimately for plant growth and could be utilized in sodic and saline soils based on the analysis of cationic parameters and mathematical models.

Keywords

Cationic parameters, food waste, soil structural stability, plant growth

References

• Abdelazem, R.E., Hefnawy, H.T., Gehan, A.E., 2021. Chemical composition and phytochemical screening of Citrus sinensis (orange) peels. Zagazig Journal of Agricultural Research 48 (3): 793-804.
• Aboelsoud, H.M., Engel, B., Gad, K.I., 2020. Effect of planting methods and gypsum application on yield and water productivity of wheat under salinity conditions in north Nile Delta. Agronomy 10(6): 853.
• Ajala, E.O., Eletta, O., Ajala, M.A., Oyeniyi, S.K., 2018. Characterization and evaluation of chicken eggshell for use as a bio-resource. Arid Zone Journal of Engineering, Technology and Environment 14 (1): 26-40.
• Al-Hadidi, K.E., Al-Ubaydi, M.A., 2021. Impact of cation ratio structure stability (CROSS)‎ on the hydraulic conductivity saturation and clay dispersion for some calcareous soils in north Iraq. Kirkuk University Journal for Agricultural Sciences 12 (1): 37–47.
• Al-awwal, N.Y., Ali, U.L., 2015. Proximate analyses of different samples of eggshells obtained from Sokoto market in Nigeria. International Journal of Science and Research 4(3): 564-566.
• Anwar, M., Patra, D.D., Singh, D.V., 1996. Influence of soil sodicity on growth, oil yield and nutrient accumulation in Vetiver (Vetiveria zizanioides). Annals of Arid Zone 35(1): 49-52.
• Arnon, D.I., Stout, P.R., 1939. The essentiality of certain elements in minute quantity for plants with special reference to copper. Plant Physiology 14: 371-375.
• Barłóg, P., Szczepaniak, W., Grzebisz, W., Pogłodziński, R., 2018. Sugar beet response to different K, Na and Mg ratios in applied fertilizers. Plant, Soil and Environment 64 (4): 173–179.
• Chen, Y., Banin, A., Borochovitch, A., 1983. Effect of potassium on soil structure in relation to hydraulic conductivity. Geoderma 30 (1–4): 135-147.
• Chen, J., Wang, Y., 2024. Understanding the salinity resilience and productivity of halophytes in saline environments. Plant Science 346: 112171.
• Chhipa, B.R., Lal, P., 1995. Na/K Ratios as the basis of salt tolerance in wheat. Australian Journal of Agricultural Research 46(3): 533–539.
• Dexter, A.R., Czy, A.R., 2000. Effects of soil management on the dispersibility of clay in a sandy soil. International Agrophysics 14 (3): 269–272.
• Enyoh, C.E., Isiuku, B.O., 2020. Characterisation of some soils from flood basin in Amakohia, Owerri, Nigeria. International Journal of Environmental Analytical Chemistry 102 (16): 3766-3785.
• Fageria, N.K., 2009. The use of nutrients in crop plants. CRC Press, Boca Raton, FL. 448p.
• FAO, 2021. Global Map of Salt-affected Soils (GSASmap). FAO Soils Portal. Food and Agriculture Organization of the United Nations. Available at Access date: 23.05.2024: https://www.fao.org/soils-portal/data-hub/soil-maps-and-databases/global-map-of-salt-affected-soils/en/
• Farahani, E., Emami, H., Thomas, K., 2018. Impact of monovalent cations on soil structure. Part II. Results of Two Swiss Soils. International Agrophysics 32 (1): 69–80.
• Filho, J.N.O., Junior, M.J.D., Medeiros, J.F., Vieira, R.C., 2020. Yield and leaf concentrations of nutrients of melon crop and fertility of soil fertigated with N and K. Revista Brasileira de Engenharia Agrícola e Ambiental 24 (11): 749–55.
• Hooi, M.T., Eunice, S.W.P., Yow, H.Y., David, E., Kim N.X., Choo, H.L., 2021. FTIR spectroscopy characterization and critical comparison of poly(vinyl)alcohol and natural hydroxyapatite derived from fish bone composite for bone-scaffold. Journal of Physics: Conference Series 2120: 012004.
• Hopmans, J.W., Qureshi, A.S., Kisekka, I., Munns, R., Grattan, S.R., Rengasamy, P., Ben-Gal, A., Assouline, S., Javaux, M., Minhas, P.S., Raats, P.A.C., Skaggs, T.H., Wang, G., Lier, Q.J., Jiao, H., Lavado, R.S., Lazarovitch, N., Li, B., Taleisnik, E., 2021. Critical knowledge gaps and research priorities in global soil salinity. Advances in Agronomy 169: 1–191.
• Islam, M.R., Wang, Q., Guo, Y., Wang, W., Sharmin S., Enyoh, C.E., 2023. Physico-chemical characterization of food wastes for potential soil application. Processes 11 (1): 250.
• Jamil, A., Riaz, S., Ashraf, M., Foolad, M.R., 2011. Gene expression profiling of plants under salt stress. Critical Reviews in Plant Sciences 30 (5): 435–458.
• Jekayinfa, S.O., Bernd, L., Ralf, P., 2015. Biogas production from selected crop residues in Nigeria and estimation of its electricity value. International Journal of Renewable Energy Technology 6 (2): 101-118.
• Johnston, M., Grof, C.P., Brownell, P.F., 1988. The effect of sodium nutrition on the pool sizes of intermediates of the C4 photosynthetic pathway. Australian Journal of Plant Physiology 15: 749-760.
• Khalil, S., 2018. Analysis of bone of chicken Gallus gallus domesticus. International Journal of Innovative Research in Science, Engineering and Technology 7 (5): 6243–46.
• Kumar, D., Singh, K., Chauhan, H.S., Prasad, A., Beg, S.U., Singh, D.V., 2006. Ameliorative potential of Palma rosa for reclamation of sodic soils. Communications in Soil Science and Plant Analysis 35 (9–10): 1197–1206.
• Machado, R.M.A., Serralheiro, R.P., 2017. Soil salinity: effect on vegetable crop growth. management practices to prevent and mitigate soil salinization. Horticulturae 3 (2): 30.
• Marchuk, A., Rengasamy. P., 2010. Cation ratio of soil structural stability (CROSS). Proceedings of 19th World Congress of Soil Science, Soil Solutions for a Changing World. 1 -6 August 2010, Brisbane, Australia. pp.9-11.
• Marschner, H., 1971. Why can sodium replace potassium in plants? Proceedings of 8th Colloquium of the International Potash Institute. Potassium in Biochemistry and Physiology. 15-17 June 1971. Skokloster-Uppsala, Sweden. pp. 50–63.
• Nwankwo, I.H., Nwaiwu, N., Nwabanne. J.T., 2018. Production and characterization of activated carbon from animal bone. American Journal of Engineering Research 7 (7): 335–341.
• Prasad, A., Chattopadhyay, A., Chand, S., Naqvi, A.A., Yadav, A., 2007. Effect of soil sodicity on growth, yield, essential oil composition, and cation accumulation in rose‐scented geranium. Communications in Soil Science and Plant Analysis 37(13–14): 1805–1817.
• Pyar, H., Peh, K.K., 2018. Chemical compositions of banana peels (Musa sapientum) fruits cultivated in Malaysia using proximate analysis. Research Journal of Chemistry and Environment 22: 108–113.
• Qadir, M., Oster, J.D., Schubert, S., Noble, A.D., Sahrawat, K.L., 2007. Phytoremediation of sodic and saline‐ sodic Soils. Advances in Agronomy 96: 197–247.
• Quamruzzaman, A.K.M., Khatun, A., Islam, F., 2020. Nutritional content and health benefits of Bangladeshi eggplant cultivars. European Journal of Agriculture and Food Sciences 2 (4).
• Rath, K.M., Fierer, N., Murphy, D.V., Rousk, J., 2019. Linking bacterial community composition to soil salinity along environmental gradients. The ISME Journal 13: 836–846.
• Ravina, I., Markus, Z., 1975. The effect of high exchangeable potassium percentage on soil properties and plant growth. Plant and Soil 42 (3): 661–672.
• Rengasamy, P., Marchuk, A., 2011. Cation Ratio of Soil Structural Stability (CROSS). Soil Research 49 (3): 280–285.
• Richards, L.A., 1954. Diagnosis and improvement of saline and alkaline soils. Agriculture Handbook, Vol. 60, United States Department of Agriculture (USDA), Washington DC, 160 p.
• Roșca, M., Mihalache, G., Stoleru, V., 2023. Tomato responses to salinity stress: From morphological traits to genetic changes. Frontiers in Plant Science 14: 1118383.
• Stavi, I., Thevs, N., Priori, S., 2021. Soil salinity and sodicity in drylands: A review of causes, effects, monitoring, and restoration measures. Frontiers of Environmental Science 9: 712831.
• Trapp, S., Feificova, D., Rasmussen, N.F., Gottwein. P.B., 2008. Plant uptake of NaCl in relation to enzyme kinetics and toxic effects. Environmental and Experimental Botany 64 (1): 1–7.
• UN, 2015. What are the Sustainable Development Goals? United Nations Development Programme. Available at Access date: 23.05.2024: https://www.undp.org/sustainable-development-goals
• USDA, 2007. Soil survey manual Chapter 3: Examination and description of soils. United States Department of Agriculture (USDA), Natural Resources Conservation Service. Available at Access date: 23.05.2024: https://www.nrcs.usda.gov/sites/default/files/2022-09/SSM-ch3.pdf