[KSCI] Korea Science Citation Index Service

http://dx.doi.org/10.7745/KJSSF.2016.49.2.181

Effect of Carbonized Rice Hull Application on Increasing Soil Carbon Storage and Mitigating Greenhouse Gas Emissions during Chinese Cabbage Cultivation

Park, Woo-Kyun (National Institute of Agricultural Sciences, RDA)
Kim, Gun-Yeob (National Institute of Agricultural Sciences, RDA)
Lee, Sun-Il (National Institute of Agricultural Sciences, RDA)
Shin, Joung-Du (National Institute of Agricultural Sciences, RDA)
Jang, Hee-Young (National Institute of Agricultural Sciences, RDA)
Na, Un-Sung (National Institute of Agricultural Sciences, RDA)
So, Kyu-Ho (National Institute of Agricultural Sciences, RDA)

Publication Information

Korean Journal of Soil Science and Fertilizer / v.49, no.2, 2016 , pp. 181-193 More about this Journal

Abstract

This experiment was conducted to evaluate the effect of carbonized rice hull (CRH) application on soil carbon storage and $N_2O$ emissions from upland soil. It was used at different rates of 0, 5, 10 and $20Mg\;ha^{-1}$ . During the Chinese cabbage cultivation, several soil chemical characteristics such as soil moisture, temperature and soil carbon were observed. Also, $CO_2$ and $N_2O$ emissions were monitored. Soil organic matter contents slightly increased with carbonized rice hull applied in all the treatments. The soil carbon contents with application rate of 0, 5, 10 and $20Mg\;ha^{-1}$ were 0, 1.3, 1.2 and $2.6g\;kg^{-1}$ , respectively. It was observed that soil carbon content was higher with increasing CRH application rate. Total nitrogen contents of soil applied with CRH relatively decreased with the course of time. However, $NO_3$ -N contents in the soil with CRH application rate of 5, 10 and $20Mg\;ha^{-1}$ were 28.6, 25.7 and $21.5mg\;kg^{-1}$ at the end of experiment, respectively. $CO_2$ emission at the $5Mg\;ha^{-1}$ application of CRH was higher about 18.9% than non-treatment, whereas those of $10Mg\;ha^{-1}$ and $20Mg\;ha^{-1}$ treatment were lower 14.4% and 11.8% compared to non-treatment, respectively. Also, it was shown that $N_2O$ emission reduced by 19.9, 28.3 and 54.0% when CRH was applied at 5, 10 and $5Mg\;ha^{-1}$ , respectively.

Keywords

Carbonized rice hull; Soil carbon content; Greenhouse gas; $N_2O$ emission;

Citations & Related Records

Times Cited By KSCI : 4 (Citation Analysis)

Reference
Cited By KSCI

1	Park, W.K., G.Y. Kim, S.I. Lee, J.D. Shin, H.Y. Jang, and K.H. So. 2014. Characteristics of greenhouse gas emission in the upland soil applied with agricultural biomass, Korean J. Soil Sci. Fert. 47(5):381-389. DOI
2	Park, W.K., N.B. Park, J.D. Shin, S.G. Hong, and S.I. Kwon. 2011. Estimation of Biomass resource conversion factor and potential production in agricultural sector, Korean J Environ Agric. 30(3):252-260. DOI
3	Parton, W.J., A.R. Mosier, D.O. Ojima, D.W. Valentine, D.S. Schimel, K. Weier, and A.E. Kulmala. 1996. Generalized model for $N_2$ and $N_2O$ production from nitrification and denitrification. Global Biochem. Cycles. 10:401-412. DOI
4	RDA. 2010. Fertilizer recommendation standards for various crops. Sanglok-sa. 24-28 (In Korean).
5	Stevens, R.J., R.J. Laughlin, L.C. Burns, J.R.M. Arah, and R.C. Hood. 1997. Measuring the contributions of nitrification and denitrification to the flux of nitrous oxide from soil. Soil. Biol. Biochem. 29:139-151. DOI
6	Vant't Hoff, J. H. 1898. Lectures on theoretical and physical chemistry, Part 1. Chemical dynamics. Edward Arnold, London, UK., 227.
7	Yagi, K. 1991. Emission of biogenic gas compounds from soil ecosystem and effect of global environment. 2. Methane emission from paddy fields. Soil and Fert. Japan. 62(5): 556-562.
8	Yanai, Y., K. Toyota, and M. Lkazaki. 2007. Effect of charcoal addition on $N_2O$ emissions from soil resulting from resetting air-dried soil in short-term laboratory experiments. Soil Sci. Plant Nutri. 53:181-188. DOI
9	Yoo, S.-H. 2002. Soil dictionary. Seoul National University Press. ISBN 89-521-0204-5, p. 362-365. (In Korean).
10	Yun B.K., I.J. Park, Y.K. Yoo, W.N. Hou, B.W. Kim, and Y.W. Kim. 2004. The effect of application levels of wood charcoal powder on onion (Allium cepa L.) growth and soil physico-chemical properties. Korean J. Intl. Agri. 16(2):162-167.
11	Zwieten, L.V., B. Singh, S. Joseph, S. Kimber, A. Cowie, and K.Y. Chan. 2009. Biochar and emissions of non- $CO_2$ greenhouse gases from soil. In Lehmann, J. and Joseph, S. (eds.): Biochar for Environmental Management. Earthscan, London, UK. pp. 227-249.
12	Arnone, J.A. III and P.J. Bohlen. 1998. Stimulated $N_2O$ flux from intact grassland monoliths after two growing seasons under elevated atmospheric $CO_2$ . Oecologia. 116:331-335. DOI
13	Arrhenius, S. 1889. Uber die Reaktionsgeschwindigkeit bei der Inversion von ohrzucker durch Sauren. Z. Phys. Chem,. 4, 226-248.
14	Ascough P.L., C.J. Sturrock, and M.I. Bird. 2010. Investigation of growth responses in saprophytic fungi to charred biomass. Isotopes Environ. Health Stud. 46:64-77. DOI
15	Batjes, N.H. 1996, Total carbon and nitrogen in soils of the world. European J. Soil Sci. 47, 151-163. DOI
16	Cho, S.J., C.S. Park, and D.I. Uhm. 1991. Soil science. 3nd ed. p. 137-143. Hyangmunsa, Seoul, Korea.
17	Bouwman, A.F. 1990. Exchange of greenhouse gases between terrestrial ecosystems and the atmosphere. p. 61-127. In: A.F. Bouwman (ed.) Soils and the greenhouse effect. John Wiley and Sons. New York
18	Case, S.D.C., N.P. McNamara, D. S. Reay, and J. Whitaker, 2013. Can biochar reduce soil greenhouse gas emissions from a Miscanthus bioenergy crop?. GCB Bioenergy. doi: 10.1111/gcbb.12052 DOI
19	Chan Y.K., L. Van Zwieten, I. Meszaros, A. Downie, and S. Joseph. 2008. Using poultry litter biochar as soil amendments. Aust. J. Soil Res. 46:437-444. DOI
20	Davidson, E.A. 1991. Fluxes of nitrous oxide and nitric oxide from terrestrial ecosystems. In: Microbial Production and Consumption of Greenhouse Gases: Methane, Nitrous Oxide and Halomethanes (eds Rogers JE, Whitman WB), American Soc. of Microbiol., Washington, D.C. 219-235.
21	Duxbury, J.M., L.A. Haper, and A.R. Mosier. 1993. Contributions of agroecosystems to global climate change. p. 1-18. In: D.E. Rolston et al. (ed.) Agricultural ecosystem effects on trace gases and global climate change, ASA special Publication 55. ASA, CSSA and SSSA. Madison. USA.
22	Firestone, M.K., and E.A. Davidson. 1989. Microbiological basis of NO and $N_2O$ production and consumption in soil. In: Andreae, M.O., Schimel, D.S. (Eds.), Exchange of Trace Gases between Terrestrial Ecosystems and the Atmosphere. Wiley, New York.
23	Frolking, S.E., A.R. Mosier, and D.S. Ojima. 1998. Comparison of $N_2O$ emissions from soils at three temperate agricultural sites: simulations of year-round measurements by four models. Nutrient Cycling in Agroecosystems. 52:77-105. DOI
24	Gu, J., X. Zheng, and W. Zhang. 2009. Background nitrous oxide emissions from croplands in China in the year 2000. Plant Soil. 320:307-320. DOI
25	Gale, E.S., D.M. Sullivan, C.G. Cogger, A.I. Bary, D.D. Hemphill, and E.A. Myhre. 2006. Estimation plant-available nitrogen release from manures, composts, and specialty products. J. Environ. Qual. 35:2321-2332. DOI
26	Godde, M. and R. Conrad. 1999. Immediate and adaptational temperature effects on nitric oxide production and nitrous oxide release from nitrification and denitrification in two soils. Biol. Fertil. Soils. 30:33-40. DOI
27	Goldberg E.D. 1985. Black carbon in the environment: Properties and distribution. John Wiley & Sons, New York.
28	Guanhui, L. and R.E. James, 1999. Elevated $CO_2$ and temperature impacts on different components of soil $CO_2$ efflux in Douglas-fir terracosms. Global Change Biol., 5, 157-168. DOI
29	Hossain M.K, V. Strezov, K.Y. Chan, and P.F. Nelson. 2010. Agronomic properties of wastewater sludge biochar and bioavailability of metals in production of cherrytomato (Lycopersicon esculentum). Chemosphere 78:1167-1171. DOI
30	Hou, A., H. Akiyama, Y. Nakajima, S. Sudo, and H. Tsuruta. 2000. Effects of urea form and soil moisture on $N_2O$ and NO emissions from Japanese Andosols. Chemosphere - Global Change Science. 2:321-327. DOI
31	IPCC (Intergovernmental Panel on Climate Change). 2006. 2006 IPCC Guidelines for National Greenhouse Gas Inventories, Volume 4. (Agriculture, Forestry and Other Land Use) Prepared by the National Greenhouse Gas Inventories Programme, Eggleston H.S., Buendia L., Miwa K., Ngara T. and Tanabe K. (eds). Published: IGES, Japan.
32	Jeong, H.C., G.Y. Kim, S.B. Lee, J.S. Lee, J.H. Lee, and K.H. So. 2012. Evaluation of Greenhouse Gas Emissions in Cropland Sector on Local Government Levels based on 2006 IPCC Guideline. Korean J. Soil Sci. Fert. 45(5): 842-847. DOI
33	IPCC (Intergovernmental Panel on Climate Change). 2007. Contribution of Working Groups I, II and III to the Fourth Assessment Report of the Intergovernmental Panel on Climate Change, Geneva, Switzerland, pp. 104.
34	IPCC (Intergovernmental Panel on Climate Change). 2014. Climate Change 2014, Synthesis Report. Contribution of Working Groups I, II and III to the Fifth Assessment Report of the Intergovernmental Panel on Climate Change [Core Writing Team, R.K. Pachauri and L.A. Meyer (eds.)]. IPCC, Geneva, Switzerland, pp. 151
35	Jang I.B., D.Y. Hyun, E.H. Lee, K.C. Park, Y. Jin, H.W. Park, S.W. Lee, and G.H. Kim. 2014. Analysis of growth characteristics and physiological disorder of Korean Ginseng affected by application of decomposing plant residues in paddy-converted field, Korean J. Medicinal Crop Sci. 22(2):140-146. DOI
36	Kammann, C.I., S. Linsel, J.W. GoBling, and H.W. Koyro. 2011. Influence of biochar on drought tolerance of Chenopodium quinoa Willd and on soil-plant relations. Plant Soil. 345:195-210. DOI
37	Kim, S.H., C.H. Lee, J.H. Park, D.C. Seo, J.S. Cho, and J.S. Heo. 2013. Chemical characteristics of biochar obtained from pyrolysis of agricultural waste in drum biochar apparatus. Proceedings of 2013 KJSSF Spring Meeting, Seoul, Korea. 330-330.
38	Laird D, P. Fleming, B. Wang, R. Horton, and D. Karlen. 2010a. Biochar impact on nutrient leaching from a Midwestern agricultural soil. Geoderma 158:436-442. DOI
39	Laird D, P. Fleming, D.D. Davis, and R. Horton. 2010b. Impact of biochar amendments on the quality of a typical Midwestern agricultural soil. Geoderma 158:443-449. DOI
40	Lal, R. 2007. Carbon management in agricultural soils. Mitigation and Adaptation Strategies for Global Change 12: 303-322 DOI
41	Lal, R. 2008. Crop residues and soil carbon. Proceedings of the Conservation Agriculture Carbon Offset Consultation, Lafayette, IN, USA, 2330.
42	Lehmann J., J. Gaunt, and M. Rondon. 2006. Biochar sequestration in terrestrial ecosystems - A review. Mitig. Adapt. Strateg. Glob. Change. 11:403-427. DOI
43	Lemke, R.L., R.C. Izaurralde, S.S. Malhi, M.A. Arshad, and M. Nyborg. 1998. Nitrous oxide emissions from agricultural soils of the Boreal and Parkland regions of Alberta. Soil Sci. Soc. Am. J. 62:1096-1102. DOI
44	Mo, Y.M, S.H. Lim, Y.K. Shin, and G.Y. Kim. 2013. Effect of Nitrogen Fertilization Level on the Emission of $N_2O$ Gas in the Field grown with Chinese Cabbage. Proceedings of 2013 KJSSF Spring Meeting, Seoul, Korea. 330-330.
45	Mueller, T., L.S. Jensen, N.E. Nielsen, and J. Magie, 1998. Turnover of carbon and nitrogen in a sandy loam soil following incorporation of chopped maize plants, barley straw, and blue grass in the field. Soil Biol. Biochem. 30, 561-571. DOI
46	NAAS (National Academy of Agricultural Science). 2010. Methods of Soil Chemical Analysis. Sam-Mi press, 20-214.
47	Nichols GJ, JA Cripps, ME Collinson and AD Scott. 2000. Experiments in waterlogging and sedimentology of charcoal: Results and implications. Paleogeogr. Paleoclimatol. Paleoecol. 164:43-56. DOI
48	Novak J.M., W.J. Busscher, D.L. Laird, M. Ahmedna, D.W. Watts, and MAS Niandou. 2009. Impact of biochar amendment on fertility of a southeastern coastal palin soil. Soil Sci. 174:105-112. DOI