Chinese milk vetch (Astragalussinicus L.) is an environment-friendly green manure used for rice with low carbon/nitrogen (C/N) ratio and high moisture. To improve the added values of milk vetch, the feasibility of co-composting of milk vetch with rice straw was evaluated. The probability of using the milk vetch-based compost as a peat substitute in seeding substrate of vegetable was further tested. The changes in physicochemical properties during co-composting of milk vetch and rice straw were evaluated, depending on three treatments: (1) milk vetch alone (MV), (2) co-composting of milk vetch and rice straws with 4:1 ration (w/w) (MV + S) and (3) MV + S with the addition of 3% (w/w) microbial inoculation (MV + S + M). The entire composting durations were 15 d, 24 d, and 24 d in MV, MV + S, MV + S + M composts. Compare to MV compost, both the MV + S, MV + S + M composts increased the temperature, pH, organic C, total nitrogen (N), total potassium (K) and the germination index (GI) (over 100) during the cooling/mature phase, and decreased total N loss, and generally, the improvements or reductions were greater in the MV + S + M compost than in the MV + S compost. Additionally, the MV + S + M compost was added at a peat substitute rates of 0%, 20%, 40%, 80% and 100% in a pot experiment to testify the utilization of milk vetch-based compost in substrates. The results showed that the substrate with 40% substitute rate increased the cabbage seeding growth, and that the electrical conductivity was the limiting factor of preventing the substitute rate increase. Another pot experiment demonstrated that the substrate with 40% peat substitute increased the cucumber growth as compared to the substrate without compost. In conclusion, the co-composting milk vetch with rice straw was feasible and quick, and microbial inoculation accelerated the composting process and improved the compost quality. The milk vetch-based composts were nutrient-rich and safe, and thus, can replace part of peat in vegetable seeding substrate.
Keywords: Chinese milk vetch (Astragalussinicus L.), compost, peat, seeding substrate
DOI: 10.25165/j.ijabe.20191201.4670

Citation: Chen Y F, Hu C, Liu D H, Li S L, Qiao Y. Co-composting of Chinese milk vetch with rice straw and using the compost as a peat substitute of seeding substrate of vegetables. Int J Agric & Biol Eng, 2019; 12(1): 214–219.

Chinese milk vetch (Astragalussinicus L.), compost, peat, seeding substrate

Lee C H, Park K D, Jung K Y, Ali M A, Lee D, Gutierrez J. Effect of Chinese milk vetch (Astragalussinicus L.) as a green manure on rice productivity and methane emission in paddy soil. Agriculture Ecosystems and Environment, 2010; 138(3-4): 343–347.

Kim S Y, Lee C H, Gutierrez J, Kim P J. Contribution of winter cover crop amendments on global warming potential in rice paddy soil during cultivation. Plant and Soil, 2013; 366(1): 273–286.

Zhu B, Yi L X, Guo L M, Chen G, Hu Y G, Tang H M, et al. Performance of two winter cover crops and their impacts on soil properties and two subsequent rice crops in Dongting Lake Plain, Hunan, China. Soil and Tillage Research; 2012; 124(4): 95–101.

Wang Y F, Liu X M, Butterly C, Tang C X, Xu J M. pH change, carbon and nitrogen mineralization in paddy soils as affected by Chinese milk vetch addition and soil water regime. Journal of Soils and Sediments, 2013; 13(4): 654–663.

Huang Q H, Li D M, Liu K L, Yu X C, Ye H C, Hu H W, et al. Effects of long-term organic amendments on soil organic carbon in a paddy field: A case study on red soil. Journal of Integrative Agriculture, 2014; 13(3): 570–576.

Lin X J, Cao W D, Wu Y Q, Zhang H, Qiu X X, Zhang W G, et al. Advance in Astragalussinicus research. Pratacultural Science, 2011; 28(1): 135–140. (in Chinese)

Bernal M P, Alburquerque J A, Moral R. Composting of animal manures and chemical criteria for compost maturity assessment: A review. Bioresource Technology, 2009; 100(22): 5444–5453.

Ab Muttalib S A, Ismail S N S, Praveena S M. Application of effective microorganism (EM) in food waste composting: A review. Asia Pacific Environmental and Occupational Health Journal, 2016; 2(2): 37–47.

Li J, Ren L, Fu B. Research progress on compost microbiology and microbial inoculates. The Fourth National Symposium on Microbial Fertilizer Production, Changsha, 2010. (in Chinese)

Li J, Peng S P. The practical handbook of composting engineering. Chemical Industry Press, Beijing, 2011. (in Chinese)

Eudoxie G D, Alexander I A. Spent mushroom substrate as a transplant media replacement for commercial peat in tomato seedling production. Journal of Agricultural Science, 2011; 3(4): 41–49.

Moral R, Paredes C, Bustamante M A, Marhuenda-Egea F, Bernal M P. Utilisation of manure composts by high-value crops: safety and environmental challenges. Bioresource Technology, 2009; 100(22): 5454–5460.

Jayasinghe G Y, Arachchi I D L, Tokashiki Y. Evaluation of containerized substrates developed from cattle manure compost and synthetic aggregates for ornamental plant production as a peat alternative. Resources Conservation and Recycling, 2010; 54(12): 1412–1418.

Fan R, Luo J, Yan S H, Wang T, Liu L Z, Gao Y, et al. Use of water hyacinth compost as a peat substitute in soilless growth media. Compost Science and Utilization, 2015; 23(4): 237–247.

Ostos J C, López-Garrido R, Murillo J M, López R. Substitution of peat for municipal solid waste- and sewage sludge-based composts in nursery growing media: effects on growth and nutrition of the native shrub Pistacialentiscus L. Bioresource Technology, 2008; 99(6): 1793–1800.

Bao S D. Agricultural chemical analysis in soil(3rd edition).China Agriculture Press, Beijing, 2005. (in Chinese)

Tiquia S M, Richard T L, Honeyman M S. Carbon, nutrient, and mass loss during composting. Nutrient Cycling in Agroecosystems, 2002; 62(1): 15–24.

NY/T2118-2012. Plug seeding substrate of vegetables. Beijing: Ministry of Agriculture, China, 2012. (in Chinese)

Mehta C M, Palni U, Frankewhittle I H, Sharma A K. Compost: its role, mechanism and impact on reducing soil-borne plant diseases. Waste Management, 2014; 34(3): 607–22.

Tweib S A K, Ekhmaj A I. Co-composting of sewage sludge with food waste using bin composter. Al-Mukhtar Journal of Sciences, 2017; 33(1): 24–35.

Brinton W F. Volatile organic acids in Compost: production and odorant aspects. Compost Science and Utilization, 1998; 6(1): 75–82.

Jusoh M L C, Manaf L A, Latiff P A. Composting of rice straw with effective microorganisms (EM) and its influence on compost quality. Iranian Journal of Environmental Health Science and Engineering, 2013; 10(1): 17–17.

NY525-2012. Organic fertilizer, Beijing: Ministry of Agriculture, China, 2012. (in Chinese)

Batham M, Arya R, Tiwari A. Time efficient co-composting of water hyacinth and industrial wastes by microbial degradation and subsequent vermicomposting. Journal of Bioremediation and Biodegradation, 2014; 5(3): 1–10.

Michel Jr. F C, Pecchia J A, Rigot J, Keener H M. Mass and nutrient losses during the composting of dairy manure amended with sawdust or straw. Compost Science and Utilization, 2004; 12(4): 323–334.

Eghball B, Power J F, Gilley J E, Doran J W. Nutrient, carbon, and mass loss during composting of beef cattle feedlot manure. Journal of Environmental Quality, 1997; 26(1): 189–193.

Huang X D, Han Z Y, Shi D Z, Huang X, Wu W X, Liu Y X. Nitrogen loss and its control during livestock manure composting. Chinese Journal of Applied Ecology, 2010; 21(1): 247–254. (in Chinese)

Qian X Y, Shen G X, Wang Z Q, Guo C X, Liu, Y Q, Lei Z F, et al. Co-composting of livestock manure with rice straw: characterization and establishment of maturity evaluation system. Waste Management, 2014; 34(2): 530–535.

Tian S X, Chen Q, Gong J Y, Li G X, Jia X H, Li Y M. Effect of reproducing compound substrate for cucumber seedling by mushroom residue and garden waste compost. China Vegetables, 2011; 12: 37–41. (in Chinese)