CLC number: X7
On-line Access: 2024-08-27
Received: 2023-10-17
Revision Accepted: 2024-05-08
Crosschecked: 2010-05-07
Cited: 8
Clicked: 5459
Dong-lei Wu, Ping Liu, Yan-zhang Luo, Guang-ming Tian, Qaisar Mahmood. Nitrogen transformations during co-composting of herbal residues, spent mushrooms, and sludge[J]. Journal of Zhejiang University Science B, 2010, 11(7): 497-505.
@article{title="Nitrogen transformations during co-composting of herbal residues, spent mushrooms, and sludge",
author="Dong-lei Wu, Ping Liu, Yan-zhang Luo, Guang-ming Tian, Qaisar Mahmood",
journal="Journal of Zhejiang University Science B",
volume="11",
number="7",
pages="497-505",
year="2010",
publisher="Zhejiang University Press & Springer",
doi="10.1631/jzus.B0900271"
}
%0 Journal Article
%T Nitrogen transformations during co-composting of herbal residues, spent mushrooms, and sludge
%A Dong-lei Wu
%A Ping Liu
%A Yan-zhang Luo
%A Guang-ming Tian
%A Qaisar Mahmood
%J Journal of Zhejiang University SCIENCE B
%V 11
%N 7
%P 497-505
%@ 1673-1581
%D 2010
%I Zhejiang University Press & Springer
%DOI 10.1631/jzus.B0900271
TY - JOUR
T1 - Nitrogen transformations during co-composting of herbal residues, spent mushrooms, and sludge
A1 - Dong-lei Wu
A1 - Ping Liu
A1 - Yan-zhang Luo
A1 - Guang-ming Tian
A1 - Qaisar Mahmood
J0 - Journal of Zhejiang University Science B
VL - 11
IS - 7
SP - 497
EP - 505
%@ 1673-1581
Y1 - 2010
PB - Zhejiang University Press & Springer
ER -
DOI - 10.1631/jzus.B0900271
Abstract: sewage sludge composting is an important environmental measure. The reduction of nitrogen loss is a critical aim of compost maturation, and the addition of spent mushrooms (SMs) and herbal residues (HRs) may be helpful. To evaluate the nitrogen transformations during co-composting of sewage sludge, SMs, and HRs, windrows were constructed in a residual processing plant. Dewatered sewage sludge and sawdust were mixed with SMs and HRs at two proportions on a fresh weight basis, 3:1:1 (sewage sludge:sawdust:SMs or HRs) and 3:1:2 (sewage sludge:sawdust:SMs or HRs). The mixture was then composted for 40 d. Changes in the physicochemical characteristic of sewage sludge during composting were recorded and analyzed. Addition of SMs and HRs accelerated the temperature rise, mediating a quicker composting maturation time compared to control. The addition also resulted in lower nitrogen losses and higher nitrate nitrogen levels in the compost products. Among the windrows, SM and HR addition improved the nitrogen status. The total nitrogen (TN) and nitrogen losses for SM and HR treatments ranged from 22.45 to 24.99 g/kg and from 10.2% to 22.4% over the control values (18.66–21.57 g/kg and 40.5%–64.2%, respectively). The pile with the highest proportion of SMs (3:1:2 (sewage sludge:sawdust:SMs)) had the highest TN level and the lowest nitrogen loss. The germination index (GI) values for all samples at maturity were above 80%, demonstrating optimal maturity. The addition of SMs and HRs augments sewage composting.
[1]APHA, 2005. Standard Methods for the Examination of Water and Wastewater, 21st Ed. American Public Health Association (APHA) Inc., New York, USA.
[2]Bao, S.D., 2005. Soil Agricultural Analysis. China Agriculture Press, Beijing, China (in Chinese).
[3]Bernai, M.P., Paredes, C., Sánchez-Monedero, M.A., Cegarra, J., 1998. Maturity and stability parameters of composts prepared with a wide range of organic wastes. Bioresource Technology, 63(1):91-99.
[4]Bishop, P.L., Godfrey, C., 1983. Nitrogen transformations during sludge composting. Biocycle, 24:34-39.
[5]Buijsman, E., Maas, H.F.M., Asman, W.A.H., 1987. Anthropogenic NH3 emissions in Europe. Atmospheric Environment (1967), 21(5):1009-1022.
[6]Cao, X.T., Huang, W.Y., Chang, Z.Z., 2004. Nitrogen loss during chicken manure composting process and mechanism to reduce nitrogen loss. Jiangsu Journal of Agricultural Sciences, 20(2):106-110 (in Chinese).
[7]Cordovil, C.M.D.S., Cabral, F., Coutinho, J., 2007. Potential mineralization of nitrogen from organic wastes to ryegrass and wheat crops. Bioresource Technology, 98(17):3265-3268.
[8]Dewes, T., 1996. Effect pH, temperature, amount of litter and storage density on ammonia emission from stable manure. The Journal of Agricultural Science, 127(4):501-509.
[9]Ekinci, K., Keener, H.M., Elwell, D.L., 2002. Composting short paper fiber with broiler litter and additives. Part 1: effects of initial pH and carbon/nitrogen ratio on ammonia emission. Compost Science & Utilization, 8(2):160-172.
[10]Eklind, Y., Kirchmann, H., 2000. Composting and storage of organic household waste with different litter amendments. II: Nitrogen turnover and losses. Bioresource Technology, 74(2):125-133.
[11]Fang, M., Wong, J.W.C., 1999. Co-composting of sewage sludge and coal fly ash: nutrient transformation. Bioresource Technology, 67(1):19-24.
[12]GB 7959-87. Sanitary Standard for the Non-hazardous Treatment of Night Soil. National Standards of the People’s Republic of China (in Chinese).
[13]Goldstein, N., Steuteville, R., 1993. Biosolids composting makes healthy progress. Biocycle, 34:48-57.
[14]He, L., Zhao, X.L., Li, C.B., 2007. Impact of different packing on nitrogen transformation in composting process of municipal sewage sludge. Journal of Southwest China Normal University, 32(2):54-58 (in Chinese).
[15]Hiraku, S., Gen, M., Hanatsu, S., Jun, N., Msaaki, S., Takako, S., Minoru, O., Yutaka, N., 2004. Distribution of ammonia assimilating bacteria in the composting process. Compost Science & Utilization, 12(2):108-113.
[16]Hirsch, M.P., 1998. Availability of sludge-borne silver to agriculture crops. Environmental Toxicology and Chemistry, 17(4):610-616.
[17]Hu, T.J., Zeng, G.M., Huang, G.H., 2004. Produce and concentration change of ammonia in aerobic compost. Transactions of Nonferrous Metals Society of China, 14(1):109-115 (in Chinese).
[18]Huang, G.F., Wong, J.W.C., Wu, Q.T., Nagar, B.B., 2004. Effect of C/N on composting of pig manure with sawdust. Waste Management, 24(8):805-813.
[19]Inoko, A., Miyamatsu, K., Sugahara, K., Harada, Y., 1979. On some organic constituents of city refuse composts produced in Japan. Soil Science Plant Nutrition, 25(2):225-234.
[20]Kirchmann, H., Witter, E., 1989. Ammonia volatilization during aerobic and anaerobic manure decomposition. Plant and Soil, 115(1):35-41.
[21]Lhadi, E.K., Tazi, H., Aylaj, M., Tambone, F., Adani, F., 2004. Co-composting separated MSW and poultry manure in morocco. Compost Science & Utilization, l21(2):37-144.
[22]Lin, Y.P., Huang, G.H., Lu, H.W., He, L., 2008a. A simulation-aided factorial analysis approach for characterizing interactive effects of system factors on composting processes. Science of the Total Environment, 402(2-3):268-277.
[23]Lin, Y.P., Huang, G.H., Lu, H.W., He, L., 2008b. Modeling of substrate degradation and oxygen consumption in waste composting processes. Waste Management, 28(8):1375-1385.
[24]Ma, N., Chen, L., Xiong, F., 2003. Disposal and reuse of city sludge in China. Ecology and Environment, 12(1):92-95 (in Chinese).
[25]Martins, O., Dewes, T., 1992. Loss of nitrogenous compounds during composting of animal wastes. Bioresource Technology, 42(2):103-111.
[26]Meijide, A., Diez, J.A., Sanchez-Martin, L., Lopez-Femandez, S., Vakkejo, A., 2007. Nitrogen oxide emissions from an irrigated maize crop amended with treated pig slurries and composts in a Mediterranean climate. Agriculture Ecosystems & Environment, 121(4):383-394.
[27]Morisaki, N., Nakasaki, K., Nakasaki, K., Shoda, M., Kubota, H., 1989. Nitrogen transformation during thermophilic composting. Journal of Fermentation and Bioengineering, 67(1):57-61.
[28]Peter, F.S., 1985. Effect of temperature on bacteria species diversity in thermophilic solid-waste composting. Applied and Environmental Microbiology, 50(4):899-905.
[29]Pichtel, J.R., 1990. Microbial respiration in fly ash-sewage sludge amended soils. Environmental Pollution, 63(3):225-227.
[30]Steniford, E., 1987. Recent Developments in Composting. In: de Bertoldi, M., Ferranti, M., Zucconi, F. (Eds.), Compost, Production, Quality and Use. Elsevier, London, p.52-60.
[31]Wong, J.W.C., Li, G.X., Wong, M.H., 1996. The growth of Brassica chinensis in heavy metal contaminated sewage sludge compost from Hong Kong. Bioresource Technology, 58(3):309-313.
[32]Zeng, G.M., Huang, G.H., Yuan, Z.X., Yang, Z.H., Hu, T.J., 2006. Environmental Biology and Control of Compost. Science Press, Beijing, China (in Chinese).
[33]Zhou, Q.X., 2006. Researching trends and prospect of agro-environment science in the world. Journal of Agro-Environment Science, 25(1):1-6 (in Chinese).
[34]Zucconi, F., Forte, M., Bertoldi, M.D., 1981. Biological evaluation of compost maturity. Biocycle, 22(1):27-29.
Open peer comments: Debate/Discuss/Question/Opinion
<1>