Peatland is an important ecosystem in Indonesia. But in almost every dry season, drained peatlands have been subject to detrimental wildfires. As a response, the government has explicitly prohibited the burning of land since 2016. To clear the land of crop residues and conduct zero burning practices, one alternative method is to utilize the waste biomass to support the cultivation of earthworms (vermiculture). This study examined the quality of liquid fertilizers and compost produced from vermiculture using a completely randomized factorial design, consisting of two treatment factors. The first factor was worm type, with two species used in this research named Lumbricus rubellus and Eudrilus eugeniae. The second factor was the type of feed provided to the worms, comprising no feed (control), vegetable waste, and crop residue waste resulting from zero burning land preparation. The type of feed significantly affected the pH value of the liquid fertilizer produced by the vermiculture but did not significantly affect the nutrient contents (N, P, and K). The combination of the types of earthworms and types of feed significantly affected the pH value of the vermicompost. The combination of worm types and feed types had a significant effect on exchangeable Ca, but not on exchangeable Mg, Na, and K. In combination, green vegetable waste and Lumbricus rubellus produced the greatest effect on soil CEC. However, for Base Saturation, the control (no food) and Eudrilus eugeniae showed the highest value. Types of worms and types of feed had a significant effect on the exchangeable Mg, while the other three parameters made no significant differences. Zero burning waste and Eudrilus eugeniae provide a better exchangeable Ca and Mg. In contrast, no-feeding and Eudrilus eugeniae have a better effect on exchangeable Na and K. Types of worms and types of feed did not significantly affect the weight of worm colonies, but the addition of feed increased the weight of worms with the highest weight resulting from the use of zero burning waste feed. The results showed that crop residue wastes were potentially good as a feed for earthworms.
Keywords: liquid organic fertilizer, vermicompost, Lumbricus rubellus, Eudrilus eugeniae, zero burning waste, crop residue, land preparation
DOI: 10.25165/j.ijabe.20201304.4814

Citation: Jaya A, Lautt B S, Antang E U, Sibot S, Dohong S, Surawijaya P, et al. Effects of zero burning waste on the quality of liquid fertilizer and vermicompost. Int J Agric & Biol Eng, 2020; 13(4): 159–165.

liquid organic fertilizer, vermicompost, Lumbricus rubellus, Eudrilus eugeniae, zero burning waste, crop residue, land preparation

Page S E, Rieley J O, Banks C J. Global and regional importance of the tropical peatland carbon pool. Global Change Biol., 2011; 17(2): 798– 818.

Sinha R K. Earthworms vermicompost, a powerful crop nutrient over the conventional compost and protective soil conditioner against the destructive chemical fertilizers for food safety and security Am-Euras. J. Agric. & Environ. Sci., 2009; 5: 1–55.

Pangkulun R. Earthworm cultivation business of Lumbricus rubellus (Indonesian). Penebar Swadaya, Jakarta, 2010.

Munroe G. Manual of on-farm vermicomposting and vermiculture. Organic Agriculture Centre of Canada, Canada, 2003.

Sathianarayanan A, Khan B. An eco-biological approach for resource recycling and pathogen (Rhizoctoniae solani Kuhn.) Suppression. J. of Enviromental Protection Science, 2008; 2: 36–39.

Andhikari N P, Mishra B N. Effect of integrated sources of nitrogen on yield of aromatic rice and their residual effect on succeeding. In Extended Summaries: 2nd International Agronomy Congress, held at New Delhi, India from November 26–30, 2002; pp.63–64.

Behera U K, Sharma A R, Pandey H N. Sustaining productivity of wheat–soybean cropping system through integrated nutrient management practices on the Vertisols of central India Plant Soil, 2007; 97: 185–199.

Winten K T I. Effects of cassava and nitrogen fertilizer dose on growth and yield of lettuce (Lactuca sativa L). Thesis. Program Pascasarjana Universitas Udayana Denpasar, 2006. (in Indonesian)

Srilaba N. Effects of vermicompost doses and phosphate fertilizer doses on sweet corn (Zea mays.Saccharata Strut) production in Andisol Candikuning. Thesis. Denpasar Universitas Udayana, 2013. (in Indonesian)

Liu M, Hu F, Chen X, Huang Q, Jiao J, Zhang B, Li H. Organic amendments with reduced chemical fertilizer promote soil microbial development and nutrient availability in a subtropical paddy field: the influence of quantity, type and application time of organic amendments. Appl. Soil Ecol., 2009; 42: 166–175.

Singh K P, Snman A, Singh P N, Srivastava T K. Improving quality of sugarcane-growing soils by organic amendments under subtropical climatic conditions of India. Biol Fertil Soils, 2007; 44: 367–376.

Padel S, Röcklinsberg H, Schmid O. The implementation of organic principles and values in the European regulation for organic food. Food Policy, 2009; 34: 245–251.

Lingga P, Marsono, Manual for fertilizers applications. Pupuk, Penebar Swadaya, Jakarta, 2000. (in Indonesian)

Wang D H, Shi Q H, Wang X F, Wei M, Hu J Y, Liu J, et al. Influence of cow manure vermicompost on the growth, metabolite contents, and antioxidant activities of Chinese cabbage (Brassica campestris ssp. chinensis). Biol Fertil Soils, 2010; 46: 689–696.

Musnamar E I. Liquid and solid organic fertilizers, production and application. Penebar Swadaya, Jakarta, 2007. (in Indonesian)

Djuarnani N, Kristian, Setiawan B D. Quick ways to produce compost. Cetakan Pertama. Agromedia Pusaka, Jakarta, 2005. (in Indonesian)

Suin N M. Soil animal ecology. Bumi Aksara, Jakarta, 1997. (in Indonesian)

Pangkulun R. Success of earthworms cultivation of Lumbricus rubellus. Penebar Swadaya, Jakarta, 1999. (in Indonesian)

Hartati S B. Application of bokashi fertilizer and azolla microphylla based liquid organic fertilizer in pakcoy plants (Brassica chinensis L.). Pascasarjana, Universitas Jendral Sudirman, Purwokerto, 2012. (in Indonesian)

Wulandari D. Growth and breeding of eisenia foetida savigny's earthworm in the cow manure media containing mushroom waste (Indonesian). Undergraduate thesis. Jurusan Biologi, FMIPA, IPB, Bogor, 2000.

Rozaq A, Novianto G. Utilization of water hyacinth plants as liquid fertilizer. Undergraduate thesis. Skripsi. Jurusan Teknik Kimia Fakultas Teknologi Industri, Universitas Pembangunan Nasional “Veteran”, Jawa Timur, 2010. (in Indonesian)

Mulahartani R. Effects of feed type on the quality of liquid organic fertilizer compost of Lumbricus rubellus. Undergraduate thesis. Jurusan Budidaya Pertanian, Fakultas Pertanian, Universitas Palangka Raya, 2017. (in Indonesian)

Arifah S M. Food composition analysis of Lumbricus sp. on the quality of vermicompost and its application in mustard plants. Jurnal Gamma, 2014; 9(2): 63–72. (in Indonesian)

Dwiyantono, R., Sutaryo and Purnomoadi, A. Comparison of the quality of vermicompost produced from cattle feces and buffalo feces. Animal Agriculture Journal, 2014; 3(2): 147–154. (in Indonesian)

Nurdini L, Amanah R D, Utami A U. Processing of cabbage waste into compost using Takakura method. Prosiding Seminar Nasional Teknik Kimia, Yogyakarta, 2016; ISSN 1693-4393. (in Indonesian)

Imanudin O, Kurnani T B A, Wahyuni S. Effects of C/N ratio mix of duck feces and sawdust (Albizzia falcata) on the quality of liquid organic fertilizer, vermicompost and earthworm biomass. Available: http://repository.unpad.ac.id/22130/1/Journal-Tesis-.pdf. 2016. (in Indonesian)

Sucipta N K S P, Kartini N L, Soniari N N. Effect of Earthworm Populations and Media Types on the Quality of Organic Fertilizers. E-Jurnal Agroekoteknologi Tropika, 2015; 4(3): 213–223.

Sutanto. Determinants factor of compost quality. Available:http://www.vedcmalang.com/pppptkboemlg/index.php/artikel-coba-2/plh/ 565 peduli-kesehatan-ii. 2002. (in Indonesian) Accessed on [2014-06-16]

Alves M R, Landgraf M D, Resende M O O. Absorption and desorption of herbicide alaclor on humic acid fractions obtained from two vermicompost. J Environ Sci Health, 2001; 36: 797–808.

Jordao C P, Pereira M G, Einloft R, Santana M B, Bellato C R, Vargas de Mello J W. Removal of Cu, Cr, Ni, Zn and Cd from electroplating wastes and synthetic solutions by vermicompost of cattle manure. J Environ Sci Health, 2002; 37: 875–892.

Albanell E, Plaixats J, Cabrero T. Chemical changes during vermicomposting (Eisenia fetida) of sheep manure mixed with cotton industrial wastes. Biol Fertil Soils, 1988; 6: 266–269.

Grapelli A, Tomati U, Galli E. Vermicomposting of combined sewage sludge and municipal refuse. Proc. Int. Symp. on Agricultural and Environmental Prospects in Earthworm Farming, Rome, Italy, 1983; pp.73–80.

Paradelo R, Cendón Y, Moldes A B, Barral M T. A pot experiment with mixtures of slate processing fines and compost. Geoderma, 2007; 141: 363–369.