The negative impact of chemical fertilizers use is soil fertility declining. The situation occurs because of biological, physical, and chemical properties of the soil is decreased. Agricultural waste is a large commodity which utilization can still be optimized, for example by using as raw material for organic liquid fertilizer. Agricultural wastes that have good quality as fertilizer include goat manure, chicken excreta, and coconut husk. The utilization of agricultural waste as organic fertilizer is one way of creating sustainable agriculture. This study aims to test the quality of liquid fertilizer (bioculture) of goat manure and chicken excreta by adding various levels of coconut husk. Bioculture is made by anaerobic fermentation for 21 days. The parameters observed included levels of C-organic, N, P, and K bioculture, as well as germination tests to determine the presence of phytotoxins. The data were analyzed using one way ANOVA. The treatment of P5 (5% coconut husk) showed the highest levels of N and P, while the K content was not significantly different from the treatment of P4 (2.5% coconut husk). The germination test showed no phytotoxin activity in bioculture.

Bioculture; Chicken excreta; Coconut husk; Goat manure; Liquid fertilizer

Abbasiliasi, S., J. S. Tan, T.A. Tengku Ibrahim, F. Bashokouh, N. R. Ramakrishnan, S. Mustafa, and A. B. Ariff. 2017. Fermentation factors influencing the production of bacteriocins by lactic acid bacteria: A review. RSC Adv. 7: 29395–29420.

Almeida, V. R., A. N. Dias, C. F. D. Bueno, F. A. P. Couto, P. A. Rodrigues, W. C. L. Nogueira, and D. E. Faria Filho. 2012. Crude protein and metabolizable energy levels for layers reared in hot climates. Rev. Bras. Cienc. Avic. 14: 203–208.

Alobwede, E., J. R. Leake, and J. Pandhal. 2019. Geoderma Circular economy fertilization : Testing micro and macro algal species as soil improvers and nutrient sources for crop production in greenhouse and field conditions. Geoderma. 334:113–123.

Bethke, C. L. 2008. Nutritional Properties of Agrocoir. F. Chaves, ed. El Majo, LLC, Michigan.

Bonneau, B. X., I. Haryanto, and T. Karsiwan. 2010. Coconut husk ash as a fertilizer for coconut palms on peat. Expl. Agric. 46: 401–414.

Dede, O. H. and H. Ozer. 2018. Enrichment of poultry manure with biomass ash to produce organomineral fertiliser. Environ. Eng. Res. 23: 449–455.

El-Gawad, A. M. A., I. A. Mashaly, M. E. A. Ziada, and M. R. Deweeb. 2015. Phytotoxicity of three Plantago species on germination and seedling growth of hairy beggarticks (Bidens pilosa L.). Egypt. J. Basic Appl. Sci. 2: 303–309.

Etesami, H., S. Emami, and H. A. Alikhani. 2017. Potassium solubilizing bacteria (KSB): Mechanisms, promotion of plant growth, and future prospects - a review. J. Soil Sci. Plant Nutr. 17: 897–911.

Fitriyanto, N. A., D. A. Priyadi, Y. Suranindyah, L. M. Yusiati, Y. Erwanto, N. Kurniawati, and A. Pertiwiningrum. 2019. Biochemical and physical properties of goat feces liquid biofertilizer fermented with chicken excreta combination and different fermentation condition. IOP Conf. Ser. Earth Environ. Sci. 387: 012-108.

Govere, S., B. Madziwa, and P. Mahlatini. 2018. The nutrient content of organic liquid fertilizers in zimbabwe. Int. J. Mod. Engginering Res. 1: 196–202.

Hossain, M. Z., P. V. F. Niemsdorff, and J. Heß. 2017. Effect of different organic wastes on soil properties and plant growth and yield : a review effect of different organic wastes on soil pro-perties and plant growth and yield : a review. Sci. Agric. Bohem. 48: 224–237.

Imatomi, M., P. Novaes, M. A. F. M. Miranda, and S. C. J. Gualtieri. 2015. Phytotoxic effect of aqueous leaf extracts of four Myrtaceae species on three weeds. Maringa. 37: 241–248.

Kizito, S., H. Luo, J. Lu, H. Bah, R. Dong, and S. Wu. 2019. Role of nutrient-enriched biochar as a soil amendment during maize growth : exploring practical alternatives to recycle agricultural residuals and to reduce chemical fertilizer demand. Sustainability. 11: 3211.

Lestari, S. U., E. Mutryarny, and N. Susi. 2019. Azolla mycrophylla fertilizer for sustainable agriculture: Compost and Liquid fertilizer applications. Int. J. Sci. Technol. Res. 8: 542–547.

Mowa, E., L. Akundabweni, P. Chimwamurombe, E. Oku, and H. A. Mupambwa. 2017. The influence of organic manure formulated from goat manure on growth and yield of tomato (Lycopersicum esculentum). African J. Agric. Res. 12: 3061–3067.

Nurdiawati, A., C. Suherman, Y. Maxiselly, M. Ali, A. Bayu, and A. Purwoko. 2019. Liquid feather protein hydrolysate as a potential fertilizer to increase growth and yield of patchouli (Pogostemon cablin Benth) and mung bean (Vigna radiata). Int. J. Recycl. Org. Waste Agric. 8: 221–232.

Olle, M. and I. Williams. 2015. The Influence of Effective Microorganisms on the Growth and Nitrate Content of Vegetable Transplants. J. Adv. Agric. Technol. 2: 2–6.

Paul, S., D. Onduru, B. Wouters, L. Gachimbi, J. Zake, P. Ebanyat, K. Ergano, M. Abduke, and H. van Keulen. 2009. Cattle Manure Management in East Africa: Review of Manure Quality and Nutrient Losses and Scenarios for Cattle and Manure Management. Wageningen UR Livestock Research, Lelystad.

Pretty, J. 2008. Agricultural sustainability : Concepts, principles and evidence Agricultural sustainability : concepts , principles and evidence. Phil. Trans. R. Soc. B. 363: 447–465. doi:10.1098/rstb.2007.2163.

Pujiastuti, E. S., J. R. Tarigan, and E. Sianturi. 2018. The effect of chicken manure and beneficial microorganisms of EM-4 on growth and yield of kale (Brassica oleraceae acephala) grown on Andisol. IOP Conf. Ser. Earth Environ. Sci. 205:012020.

Pyakurel, A., B. R. Dahal, and S. Rijal. 2019. Effect of molasses and organic fertilizer in soil fertility and yield of spinach in Khotang, Nepal. Int. J. Appl. Sci. Biotechnol. 7: 49–53.

Rahman, K. M. A. and D. Zhang. 2018. Effects of fertilizer broadcasting on the excessive use of inorganic fertilizers and environmental sustainability. Sustainability. 10: 759.

Samsuddin, M. F., H. M. Saud, M. R. Ismail, M. H. Omar, S. Habib, M. Bhuiyan, and H. Kausar. 2014. Effect of different combinations of coconut coir dust and compost on rice grown under soilless culture. J. Food Agric. Environ. 12: 1280–1283.

Sastro, Y., B. Bakrie, and N. R. Sudolar. 2013. The effect of fermentation method , microbes inoculation and carbon source proportion on the quality of organic fertilizer made from liquid wastes of chicken slaughterhouse. J. Indones. Trop. Anim. Agric. 38: 257–263.

Shaheen, A. M., F. A. Rizk, E. H. Abd El-Samad, S. H. Mahmoud, and D. M. Salama. 2018. Chicken Manure Tea and Effective Micro-organisms Enhanced Growth and Productivity of Common Bean Plants. Middle East J. Agric. Res. 7: 1419–1430.

Shahid, M., M. F. Saleem, H. Z. Khan, M. A. Wahid, and M. Sarwar. 2015. Improving wheat (Triticum aestivum L.) yield and quality by integration of urea with poultry manure. Soil Environ. 34: 148–155.

Sharma, N. and R. Singhvi. 2017. Effects of chemical fertilizers and pesticides on human health and environment : a review. Int. J. Agric. Environ. Biotechnol. 10: 675–679.

Sorathiya, L. M., A. B. Fulsoundar, K. K. Tyagi, M. D. Patel, and R. R. Singh. 2014. Eco-friendly and modern methods of livestock waste recycling for enhancing farm profitability. Int. J. Recycl. Org. Waste. Agric. 3: 50.

Sunaryo, Y., D. Purnomo, M. T. Darini, and V. R. Cahyani. 2018. Effects of goat manure liquid fertilizer combined with AB-MIX on foliage vegetables growth in hydroponic. IOP Conf. Ser. Earth Environ. Sci. 129: 1–5.

Tripolskaja, L., D. Romanovskaja, A. Slepetiene, A. Razukas, and G. Sidlauskas. 2014. Effect of the chemical composition of green manure crops on humus formation in a Soddy-Podzolic soil. Eurasian Soil Sci. 47: 310–318.

Wuta, M. and P. Nyamugafata. 2012. Management of cattle and goat manure in Wedza smallholder farming area, Zimbabwe. African J. Agric. Research 7: 3853–3859.

Zhang, L., C. Yan, Q. Guo, J. Zhang, J. Ruiz-menjivar, F. Studies, C. Sciences, and O. F. Systems. 2018. The impact of agricultural chemical inputs on environment : global evidence from informetrics analysis and visualization. Int. J. Low-Carbon Technol. 13: 338–352.