Impact of Single and Cumulative Applications of Biogas Liquid Digestate on Soil and Plant

Authors
V. Atav 1
O. Yuksel 2
A. Namli 3
1 Department of Plant Nutrition and Soil, Atatürk Soil Water and Agricultural Meteorology Research Institute Kırklareli, Turkey.
2 Department of Soil Science and Plant Nutrition, Faculty of Agriculture, Tekirdag Namık Kemal University, Tekirdağ, Turkey.
3 Department of Soil Science and Plant Nutrition, Faculty of Agriculture, Ankara University, Ankara, Turkey.
10.48311/jast.2025.24124
Abstract
The surge in biogas energy production has resulted in an accumulation of Liquid Digestate (LD), a byproduct with possible agricultural utility. To discern its benefits and shortcomings, a field trial was conducted to evaluate the effects of different doses of LD on maize yield, soil salinity, leaf and grain Nitrogen (N) content. The study included both single-year and consecutive two-year applications of LD at doses of 10, 30, 50, and 70 t ha-1. Based on maize N requirements, any N deficit was supplemented with chemical fertilizers. For the one-year experiment, the highest grain yield was obtained from the chemical fertilization treatment and 70 t ha-1 dose of LD. In the two consecutive years, 70 t.ha-1 dose gave the highest grain yield. LD provided N to the soil as effectively as chemical fertilization and stabilized the soil pH within approximately 1 month. However, high doses of digestate resulted in increased soil salinity and decreased N Use Efficiency (NUE). Consecutive two-year application increased Electrical Conductivity (EC) and pH stabilization in the soil to a greater extent than single-year applications. However, there was no difference in the N content of the plant between single-year and two consecutive applications. In summary, LD provides significant agricultural benefits such as pH stabilization and increased inorganic N levels. However, our findings indicate that overuse can lead to soil salinity and N losses, underscoring the importance of balanced application to maximize its benefits while minimizing potential drawbacks.

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Aimrun, W., Amin, M. S., Rusnam, M., Ahmad, D. E. S. A., Hanaf, M. M., & Anuar, A. R. (2009). Bulk soil electrical conductivity as an estimator of nutrients in the maize cultivated land. European Journal of Scientific Research, 31, 37-51.
Al-Juhaimi, F. Y., Hamad, S. H., Al-Ahaideb, I. S., Al-Otaibi, M. M., & El-Garawany, M. M. (2014). Effects of fertilization with liquid extracts of biogas residues on the growth and forage yield of alfalfa (Medicago sativa L.) under arid zone conditions. Pakistan Journal of Botany, 46(2), 471-475.
Anderson, J. P. E. (1982). Soil respiration. In A. L. Page, D. R. Keeney, D. E. Baker, R. H. Miller, R. Ellis Jr., & J. D. Rhoades (Eds.), Methods of soil analysis, Part 2- Chemical and Microbiological Properties (pp. 831-871). ASA-SSSA.
Anderson, J. P. E., & Domsch, K. H. (1978). A physiological method for the quantitative measurement of microbial biomass in soils. Soil Biology and Biochemistry, 10(3), 215-221.
Anderson, T. H., & Domsch, K. H. (1986). Carbon assimilation and microbial activity in soil. Zeitschrift für Pflanzenernährung und Bodenkunde, 149(4), 457-468.
Angelidaki, I., & Ellegaard, L. (2003). Codigestion of manure and organic wastes in centralized biogas plants. Applied Biochemistry and Biotechnology, 109(1-3), 95-105.
Apha, A., & Wpcf. (2012). Standard methods for the examination of water and wastewater. American Public Health Association, Washington.
Aydın, B., Öztürk, O., Çobanoğlu, F., Çebi, U., Özkan, E., & Özer, S. (2020). Effects of drip irrigation subsidies on silage maize production: A case study from Edirne. International Journal of Agriculture and Wildlife Science, 6(3), 496-505.
Bationo, A., Kihara, J., Vanlauwe, B., Waswa, B., & Kimetu, J. (2007). Soil organic carbon dynamics, functions and management in West African agro-ecosystems. Agricultural systems, 94(1), 13-25.
Bao, S. D. (2005). Soil and Agricultural Chemistry Analysis. Beijing: Agricultural Press.
Barduca, L., Wentzel, S., Schmidt, R., Malagoli, M., & Joergensen, R. G. (2021). Mineralisation of distinct biogas digestate qualities directly after application to soil. Biology and Fertility of Soils, 57(2), 235-243.
Barłóg, P., Hlisnikovský, L., & Kunzová, E. (2020). Effect of digestate on soil organic carbon and plant-available nutrient content compared to cattle slurry and mineral fertilization. Agronomy, 10(3), 379.
Barber, K. L., Maddux, L. D., Kissel, D. E., Pierzynski, G. M., & Bock, B. R. (1992). Maize responses to ammonium‐and nitrate‐nitrogen fertilization. Soil Science Society of America Journal, 56(4), 1166-1171.
Brady, N. C., & Weil, R. R. (2008). The soils around us. The nature and properties of soils (14th ed.). Pearson Prentice Hall, New Jersey and Ohio, 1-31.
Bremner, J. T. (1965). Inorganic forms of nitrogen. In Methods of Soil Analysis: Part 2 Chemical and Microbiological Properties (Vol. 9, pp. 1179-1237).
Brito, L. M., Coutinho, J., & Smith, S. R. (2008). Methods to improve the composting process of the solid fraction of dairy cattle slurry. Bioresource Technology, 99(18), 8955-8960.
Canisares, L. P., Do Carmo, J. B., Pitombo, L. M., & Pires, E. C. (2017). Digested bioenergy byproduct with low concentration of nutrients increased greenhouse gas emissions from soil. Geoderma, 307, 81-90.
Chantigny, M. H., Angers, D. A., Bélanger, G., Rochette, P., Eriksen-Hamel, N., Bittman, S., ... & Gasser, M. O. (2008). Yield and nutrient export of grain maize fertilized with raw and treated liquid swine manure. Agronomy Journal, 100(5), 1303-1309.
Chookietwattana, K., Chumpol, J., & Sumphanwanich, P. (2016). Liquid Fermented Organic Products: A Potential Alternative for Chemical Fertilizer and Soil Amendments. In Liquid Organic Fertilizer (pp. 79-100). Springer.
De França, A. A., von Tucher, S., & Schmidhalter, U. (2021). Effects of combined application of acidified biogas slurry and chemical fertilizer on crop production and N soil fertility. European Journal of Agronomy, 123, 126224.
Deviren, H., İlkılıç, C., & Aydın, S. (2017). Biyogaz üretiminde kullanılabilen materyaller ve biyogazın kullanım alanları. Batman Üniversitesi Yaşam Bilimleri Dergisi, 7(2/2), 79-89.
Diacono, M., & Montemurro, F. (2011). Long-term effects of organic amendments on soil fertility. Sustainable Agriculture Volume 2, 761-786.
Du, H., Gao, W., Li, J., Shen, S., Wang, F., Fu, L., & Zhang, K. (2019). Effects of digested biogas slurry application mixed with irrigation water on nitrate leaching during wheat-maize rotation in the North China Plain. Agricultural Water Management, 213, 882-893.
Du, Z., Xiao, Y., Qi, X., Liu, Y., Fan, X., & Li, Z. (2018). Peanut-shell biochar and biogas slurry improve soil properties in the North China Plain: a four-year field study. Scientific Reports, 8(1), 1-9.
El-Khatib, A. A., Al-Muhtaseb, A. H., Al-Makhadmeh, L. A., & Abu-Nameh, E. S. (2018). Impact of liquid fermented organic waste on soil characteristics, plant growth, and yield. Journal of Plant Nutrition, 41(4), 499-508.
Ernst, G., Müller, A., Göhler, H., & Emmerling, C. (2008). C and N turnover of fermented residues from biogas plants in soil in the presence of three different earthworm species (Lumbricus terrestris, Aporrectodea longa, Aporrectodea caliginosa). Soil Biology and Biochemistry, 40(6), 1413-1420.
Fransman, B., & Nihlgård, B. (1995). Water chemistry in forested catchments after topsoil treatment with liming agents in South Sweden. Water, Air, and Soil Pollution, 85(2), 895-900.
Gee, G. W., & Bauder, J. (1986). Particle size analysis. In Methods of Soil Analysis, Part 1, 383-411.
Geisseler, D., & Scow, K. M. (2014). Long-term effects of mineral fertilizers on soil microorganisms–A review. Soil Biology and Biochemistry, 75, 54-63.
Głowacka, A., Szostak, B., & Klebaniuk, R. (2020). Effect of biogas digestate and mineral fertilisation on the soil properties and yield and nutritional value of switchgrass forage. Agronomy, 10(4), 490.
Gürbüz, M. A., & Öz, T. A. (2016). Ayçiçeğinin Azotlu Gübreleme Önerilerinde İndeks Olarak Kullanılabilecek Parametrelerin Araştırılması [Investigation of Parameters that can be Used as an Index in Nitrogen Fertilization Recommendations for Sunflower]. Çukurova Tarım ve Gıda Bilimleri Dergisi, 31(3), 147-152.
Holm-Nielsen, J. B., Al Seadi, T., & Oleskowicz-Popiel, P. (2009). The future of anaerobic digestion and biogas utilization. Bioresource Technology, 100(22), 5478-5484.
IBM Corp. (2017). IBM SPSS Statistics for Windows, Version 25.0. Armonk, NY: IBM Corp.
Insam, H., Franke-Whittle, I. H., Knapp, B. A., & Plank, R. (2009). Use of wood ash and anaerobic sludge for grassland fertilization: Effects on plants and microbes. Die Bodenkultur, 60(2), 39-50.
Jackson, M. L. (1979). Soil Chemical Analysis: Advanced Course. Dept. Soil Science, University of Wisconsin, Madison, WI, USA.
Jia, Y., Sun, G. X., Huang, H., & Zhu, Y. G. (2013). Biogas slurry application elevated arsenic accumulation in rice plant through increased arsenic release and methylation in paddy soil. Plant and Soil, 365(1), 387-396.
Jurgutis, L., Šlepetienė, A., Amalevičiūtė-Volungė, K., Volungevičius, J., & Šlepetys, J. (2021). The effect of digestate fertilisation on grass biogas yield and soil properties in field-biomass-biogas-field renewable energy production approach in Lithuania. Biomass and Bioenergy, 153, 106211.
Kacar, B., & İnal, A. (2010). Bitki analizleri. Nobel Yayın Dağıtım.
Karimi, B., Sadet-Bourgeteau, S., Cannavacciuolo, M., Chauvin, C., Flamin, C., Haumont, A., ... & Ranjard, L. (2022). Impact of biogas digestates on soil microbiota in agriculture: A review. Environmental Chemistry Letters, 20(5), 3265-3288.
Köster, J. R., Cárdenas, L., Senbayram, M., Bol, R., Well, R., Butler, M., ... & Dittert, K. (2011). Rapid shift from denitrification to nitrification in soil after biogas residue application as indicated by nitrous oxide isotopomers. Soil Biology and Biochemistry, 43(8), 1671-1677.
Loeppert, R. H., & Suarez, D. L. (1996). Carbonate and gypsum. Methods of soil analysis: Part 3 chemical methods, 5, 437-474.
Marschner, P., Kandeler, E., & Marschner, B. (2003). Structure and function of the soil microbial community in a long-term fertilizer experiment. Soil Biology and Biochemistry, 35(3), 453-461.
Massé, D. I., Croteau, F., & Masse, L. (2007). The fate of crop nutrients during digestion of swine manure in psychrophilic anaerobic sequencing batch reactors. Bioresource technology, 98(15), 2819-2823.
Turkish State Meteorological Service [TSMSM]. (2020). Resmi istatistikler. Retrieved from https://www.mgm.gov.tr/veridegerlendirme/il-ve-ilceler-istatistik.aspx?k=A&m=KIRKLARELI
Moll, R. H., Kamprath, E. J., & Jackson, W. A. (1982). Analysis and interpretation of factors which contribute to efficiency of nitrogen utilization. Agronomy Journal, 74(3), 562-564.
Möller, K. (2015). Effects of anaerobic digestion on soil carbon and nitrogen turnover, N emissions, and soil biological activity. A review. Agronomy for Sustainable Development, 35(3), 1021-1041.
Möller, K., & Müller, T. (2012). Effects of anaerobic digestion on digestate nutrient availability and crop growth: A review. Engineering in Life Sciences, 12(3), 242-257.
Nkoa, R. (2014). Agricultural benefits and environmental risks of soil fertilization with anaerobic digestates: a review. Agronomy for Sustainable Development, 34(2), 473-492.
Nyberg, K., Sundh, I., Johansson, M., & Schnürer, A. (2004). Presence of potential ammonia oxidation (PAO) inhibiting substances in anaerobic digestion residues. Applied Soil Ecology, 26(2), 107-112.
Pan, W. L., Camberato, J. J., Moll, R. H., Kamprath, E. J., & Jackson, W. A. (1995). Altering source–sink relationships in prolific maize hybrids: Consequences for nitrogen uptake and remobilization. Crop Science, 35(3), 836-845.
Panuccio, M. R., Romeo, F., Mallamaci, C., & Muscolo, A. (2021). Digestate application on two different soils: Agricultural benefit and risk. Waste and Biomass Valorization, 12(8), 4341-4353.
Piccoli, I., Francioso, O., Camarotto, C., Delle Vedove, G., Lazzaro, B., Giandon, P., & Morari, F. (2022). Assessment of the short-term impact of anaerobic digestate on soil C stock and CO2 emissions in shallow water table conditions. Agronomy, 12(2), 504.
Rawoof, S. A. A., Kumar, P. S., Vo, D. V. N., & Subramanian, S. (2021). Sequential production of hydrogen and methane by anaerobic digestion of organic wastes: a review. Environmental Chemistry Letters, 19, 1043-1063.
Ren, T., Yu, X., Liao, J., Du, Y., Zhu, Y., Jin, L., ... & Ruan, H. (2020). Application of biogas slurry rather than biochar increases soil microbial functional gene signal intensity and diversity in a poplar plantation. Soil Biology and Biochemistry, 146, 107825.
Robles-Aguilar, A. A., Temperton, V. M., & Jablonowski, N. D. (2019). Maize silage digestate application affecting germination and early growth of maize modulated by soil type. Agronomy, 9(8), 473.
Rohila, A. K., Maan, D., Kumar, A., & Kumar, K. (2017). Impact of agricultural practices on environment. Asian Journal of Microbiology, Environmental Science, 19(2), 145-148.
SAPEA. (2012). Facheverhan biogas. Retrieved from http://www.biogas.org/edcom/webfvb.nsf/id/DE_Branchenzahlen
Shi, L., Simplicio, W. S., Wu, G., Hu, Z., Hu, H., & Zhan, X. (2018). Nutrient recovery from digestate of anaerobic digestion of livestock manure: a review. Current Pollution Reports, 4, 74-83.
Singh, A., Agrawal, M., & Marshall, F. M. (2010). The role of organic vs. inorganic fertilizers in reducing phytoavailability of heavy metals in a wastewater-irrigated area. Ecological Engineering, 36(12), 1733-1740.
Soil Survey Lab Staff. (1975). Soil Taxonomy: A basic system of soil classification for making and interpreting soil surveys (No. 436.4 So3). US Govt. Print. Off.
Sutherland, R. A. (2018). Guidelines for the use of ICP-OES for the characterisation of urban road-deposited sediment particle size fractions. Environmental Pollution, 238, 926–939.
Sürmen, M., & Kara, E. (2022). High-Quality Fertilizers from Biogas Digestate. Environment and Climate-smart Food Production, 319-347.
Urra, J., Alkorta, I., & Garbisu, C. (2019). Potential benefits and risks for soil health derived from the use of organic amendments in agriculture. Agronomy, 9(9), 542.
Yakan, H., & Sağlam, T. (1997). Kırklareli koşullarında yetiştirilen hıbrıt mısır azotlu ve fosforlu gübrelemenin dane verimi ve bazı kalite özelliklerine etkisi [Doctoral thesis, Trakya University Faculty of Agriculture]. Edirne.
Yaraşır, N. (2018). The Effect Of Different Doses of Liquıd Biogas Wastes on Yield and Quality of Wheat (Triticum aestivum L.) (Master's thesis, Adnan Menderes University Graduate School of Natural and Applied Sciences).
Zhao, Q., Cheng, J., Zhang, T., Cai, Y., Sun, F., Li, X., & Zhang, C. (2022). Biogas slurry increases the reproductive growth of oilseed rape by decreasing root exudation rates at bolting and flowering stages. Plant and Soil, 1–16.
Zhong, W., Gu, T., Wang, W., Zhang, B., Lin, X., Huang, Q., & Shen, W. (2010). The effects of mineral fertilizer and organic manure on soil microbial community and diversity. Plant and Soil, 326(1), 511–522.
Journal of Agricultural Science and Technology
Volume 27, Issue 5
July and August 2025
Pages 1061-1077