[KSCI] Korea Science Citation Index Service

http://dx.doi.org/10.7745/KJSSF.2017.50.4.259

Yield Potentials of Rice and Soybean As Affected by Cropping Systems in Mid-mountainous Paddy Soils of Korea

Kang, Ui-Gum (National Institute of Crop Science, RDA)
Choi, Jong-Seo (National Institute of Crop Science, RDA)
Kim, Jeong-Ju (National Institute of Crop Science, RDA)
Cho, Ju-Sik (Department of Bio-Environmental Sciences, Sunchon National University)

Publication Information

Korean Journal of Soil Science and Fertilizer / v.50, no.4, 2017 , pp. 259-274 More about this Journal

Abstract

To get some informations for sustainable paddy use, the productivities of soils with two years of cropping systems were estimated through pot experiment using two pretreated groups of not autoclaved 'natural'- and 'autoclaved'-soils without any fertilization. And then the relationship between the productivities, called yield potentials, and the characteristics of soils as affected by cropping systems, such as rice-rice (R-R), ricebarley-rice-barley (R-B-R-B), rice-barley-rice-wheat (R-B-R-W), soybean-barley-soybean-barley (S-B-S-B), of which barley and wheat were composted at a level of $10MT\;ha^{-1}$ , and S-B-S-B without compost, was analyzed. These treatments were established in mid-mountainous loam paddy, which contained exchangeable Ca of $11.8cmol_c\;kg^{-1}$ , located at the altitude of 285 m above sea level in Sangju of Korea. Crops for the estimation of soil productivity were rice cv. 'Seolemi' and soybean cv. 'Chamol'. As a result, under the natural soils condition, rice grain and straw were highly produced in composted S-B-S-B soils (p < 0.05) and lowly in R-R soils (p < 0.05). While soybean grain and stem were higher in R-R soils (p < 0.05) than other soils which not significantly different each other. In case of autoclaved soils, the yield potentials of rice and soybean were high together in either composted R-B-R-B/W or S-B-S-B soils compared to R-R and uncomposted S-B-S-B soils (p < 0.05). In especial, these yield potentials under the natural soils condition were commonly influenced by soil porosity showing negative correlation for rice (p < 0.01); positive for soybean (p < 0.05). And the porosity possibly reversed even the symbiotic contribution of indigenous Bradyrhizobium japonicum for soybean. Under autoclaved soils condition the potentials of rice and soybean showed negative correlations with soil C:N ratio (p < 0.05) similarly to the case of rice in the natural soils.

Keywords

Cropping system; Paddy soils; Yield potentials; Rice; Soybean;

Citations & Related Records

Times Cited By KSCI : 4 (Citation Analysis)

Reference
Cited By KSCI

1	Cheng, W., D.W. Johnson, and S. Fu. 2003. Rhizosphere effects on decomposition: controls of plant species, phenology, and fertilization. Soil Sci. Soc. Am. J. 67:1418-1427. DOI
2	Choi, S.C., J. Dyck, and N. Childs. 2016. The rice market in South Korea, RCS-16I-01, Economic Research Service/USDA.
3	Colmer, T.D. 2003. Aerenchyma and an inducible barrier to radial oxygen loss facilitate root aeration in upland, paddy and deep-water rice (Oryza sativa L.). Ann. Bot. 91:301-309. DOI
4	Cook, R.J. 2006. Toward cropping systems that enhance productivity and sustainability. Proc. Natl. Acad. Sci. 103:18389-18394. DOI
5	Cortez, J., E. Garnier, N. Perez-Haguindeguy, M. Debussche, and D. Gillon. 2007. Plant traits, litter quality, and decomposition in a Mediterranean old-field succession. Plant Soil 296:19-34. DOI
6	Cosentino, D., C. Chenub, and Y. Le Bissonnais. 2006. Aggregate stability and microbial community dynamics under drying-wetting cycles in a silt loam soil. Soil Biol. Biochem. 38:2053-2062. DOI
7	Dias, T., A. Dukes, and P.M. Antunes. 2015. Accounting for soil biotic effects on soil health and crop productivity in the design of crop rotations. J. Sci. Food Agric. 95:447-454. DOI
8	Hamza, M.A. and W.K. Anderson. 2005. Soil compaction in cropping systems. A review of the nature, causes and possible solutions. Soil Tillage Res. 82:121-145. DOI
9	Im, J.N. 1978. Soil physical properties and organic matter. Korean J. Soil Sci. Fert. 11:145-160.
10	Kaiser, M., M. Kleber, and A.A. Berhe. 2015. How air-drying and rewetting modify soil organic matter characteristics: an assessment to improve data interpretation and inference. Soil Biol. Biochem. 80:324-340. DOI
11	Kang, S.S., A.S. Roh, S.C. Choi, Y.S. Kim, H.J. Kim, M.T. Choi, B.K. Ahn, H.W. Kim, H.K. Kim, J.H. Park, Y.H. Lee, S.H. Yang, J.S. Ryu, Y.S. Jang, M.S. Kim, Y.K. Sonn, C.H. Lee, S.G. Ha, D.B. Lee, and Y.H. Kim. 2012. Status and changes in chemical properties of paddy soil in Korea. Korean J. Soil Sci. Fert. 45:968-972. DOI
12	Kang, U.G. 1998. Symbiotic potential of Bradyrhizobium japonicum indigenous to arable land in the southern part of Korea. J. Korean Agric. Chem. Biotechnol. 41:247-252.
13	Kang, U.G. 2007. Enhancement of soil productivity by soybean cultivation. Korea Soybean Digest 24:1-13.
14	Kang, U.G., W.C. Shin, J.S. Choi, Y.B. Lee, and Y.H. Lee. 2016. Impacts of cropping systems on the distribution of soil microorganisms in mid-mountainous paddy. Korean J. Soil Sci. Fert. 49:480-488. DOI
15	Kang, U.G., C.Y. Park, M.T. Youn, S.U Choi, and H.S. Ha. 1997. relatedness of naturalized Bradyrhizobium japonicum populations with soill physico-chemical characteristics as affected by paddy-upland rotation. J. Korean Agric. Chem. Biotechnol. 40:438-441.
16	Kang, U.G., H.M. Park, J.Y. Ko, J.S. Lee, W.T. Jeon, C.Y. Park, K.D. Park, and V.K. Chebotar. 2017. Isolation, root colonization and evaluation of some plant growth-promoting rhizobacteria in paddy rice. Korean J. Soil Sci. Fert. 50:135-149. DOI
17	Kang, U.G., P. Somasegaran, H.J. Hoben, and B.B. Bohlool. 1991. Symbiotic potential, competitiveness, and serological properties of Bradyrhizobium japonicum indigenous to Korean soils. Appl. Environ. Microbiol. 57:1038-1045.
18	Kim, C.G, H.K. Jeong, D.H. Moon, and C. Tisdell. 2014. Establishment of sustainable agriculture system in Korea (Year 2 of 2). Krei research report R732. ISBN 978-89-6013-677-9 93520.
19	Kim, H.S., G.S. Chae, S.E. Yoon, and Y.S. Lee. 2015. A study on improving dry-field farming competitiveness in response to the expansion of market opening (Year 1 of 3). KREI research report R760. ISBN 978-89-6013-821-693520.
20	Kim, J.I., K.H, Rhee, Y.B. Oh, Y.J. Oh, and J.K. Lee. 1993. Crop combinations and rotation years for paddy-upland cropping system in middle part of Korea. Korean J. Crop Sci. 38:304-311.
21	Kim, S.H. and S.K. Lee. 1992. Role of crops and residues, and fertilization to changes of population, soil chemical properties and plant growth I. Microbial population in the habitate. Korean J. Soil Sci. Fert. 25:370-377.
22	Moroyu, H. 1983. Change of physical and chemical properties of paddy soils under the cultivation of upland crops. Jpn J. Soil Sci. Plant Nutr. 54:434-441.
23	Kuykendall, L.D., T.E. Devine, and P.B. Cregan. 1982. Positive role of nodulation on the establishment of Rhizobium japonicum in subsequent crops of soybean. Current Microbiol. 7:79-81. DOI
24	Lee, C.H., U.G. Kang, K.D. Park, D.K. Lee, and P.J. Kim. 2008. Long-term fertilization effects on rice productivity and nutrient efficiency in Korean paddy. Plant Nutr. 31:1496-1506. DOI
25	Miyake, Y. and E. Takahashi. 1985. Effect of silicon on the growth of soybean plants in a solution culture. Soil Sci. Plant Nutr. 31:625-636. DOI
26	Motomatsu, T. 1990. Strategic development in future and results of farmland cultivation project. Symposium of Agricultural Sciences Institute. pp. 161-183.
27	Muthukumarasamy, R., U.G. Kang, K.D. Park, W.T. Jeon, C.Y. Park, Y.S. Cho, S.W. Kwon, J.Y. Song, D.H. Roh, and G. Revathi. 2007. Enumeration, isolation and identification of diazotrophs from wetland rice varieties grown with long-term application of N and compost and their short-term inoculation effect on rice plants. J. Appl. Microbiol. 102:981-991.
28	NICS (National Institute of Crop Science). 2010. Practical research plan for 2010. National Institute of Crop Science, Suwon, Korea.
29	NICS (National Institute of Crop Science). 2014. An analysis handbook for the environment of staple crop. National Institute of Crop Science, Suwon, Korea.
30	Nishida, M. 2016. Decline in fertility of paddy soils induced by paddy rice and upland soybean rotation, and measures against the decline. Jpn. Agric. Res. Q. 50:87-94. DOI
31	Pagliai, M. and M, De Nobili. 1993. Relationships between soil porosity, root development and soil enzyme activity. Geoderma 56:243-256. DOI
32	Nishida, M., H. Sekiya, and K. Yoshida. 2013. Status of paddy soils as affected by paddy rice and upland soybean rotation in northeast Japan, with special reference to nitrogen fertility, Soil Sci. Plant Nutr. 59:208-217. DOI
33	Olk, D.C., G. Brunetti, and N. Senesi. 2000. Decrease in humification of organic matter with intensified lowland rice cropping: A wet chemical and spectroscopic investigation. Soil Sci. Soc. Am. J. 64:1337-1347. DOI
34	Olsson, L. and J. Ardo. 2002. Soil carbon sequestration in degraded semiarid Agro-Ecosystems-Perils and potentials. Ambio 31:471-477. DOI
35	Pagliai, M., M. La Marca, and G. Lucamante. 1983. Micromorphometric and micromorphological investigations of a clay loam soil in viticulture under zero and conventional tillage. J. Soil Sci. 34:391-403. DOI
36	Park, C.Y., U.G. Kang, G.S. Hwang, and Y.T. Jung. 1993. Changes of crop yields according to cropping systems and fertilizing levels in paddy-upland rotation soils. RDA J. Agric. Sci. 35(S & F):281-288.
37	Pezeshki, S.R and R.D. DeLaune. 2012. Soil oxidation-reduction in wetlands and its impact on plant functioning. Biology 1:196-221. DOI
38	Park, C.Y., Y.P. No, G.S. Hwang, Y.T. Jung, and S.K. Lee. 1992. Changes of soil characteristics by paddy-upland rotation and establishment of foundation for that rotation. Year 1992 NYCES (Yeongnam Crop Experiment Station) research report. pp. 609-620.
39	Parr, J.F., R.I. Papendick, S.B. Hornick, and R.E. Meyer. 1992. Soil quality: attributes and relationship to alternative and sustainable agriculture. Am. J. Altern. Agric. 7:5-11. DOI
40	Pedersen, P. and J.G. Lauer. 2004. Soybean growth and development response to rotation sequence and tillage system. Agron. J. 96:1005-1012. DOI
41	Ponnamperuma, F.N. 1984. Effects of flooding on soils. In: T.T. Kozlowski ed. Flooding and plant growth. New York: Academic Press, pp. 9-45.
42	Power, J.F. 1987. Legume: their potential role in agricultural production. Amer. J. Altern. Agric. 2:69-73. DOI
43	Regelink, I.C., C.R. Stoof, S. Rousseva, L. Weng, G.J. Lair, P. Kram, N.P. Nikolaidis, M. Kercheva, S. Banwart, and R.N.J. Comans. 2015. Linkages between aggregate formation, porosity and soil chemical properties. Geoderma 247-248:24-37. DOI
44	Ryu, I.S., Y.S. Kim, and C.S. Park. 1971. Studies on the relationship between productivity of paddy soils, and their physical and chemical properties. RDA. J. Agri. Sci. 14(S & F):1-16.
45	USDA NRCS. 2011. Carbon to nitrogen ratios in cropping systems. Available at: http://www.nrcs.usda.gov/wps/PA_NRCSConsumption/download?cid=nrcs142p2_052823&ext=pdf. Accessed in June 2017.
46	Statistics Korea. 2016. Annual trends of food grain consumption, 2015. KOSTAT database. Available at: http://kostat.go.kr/portal/english/surveyOutlines/8/4/index.static. Accessed in June 2017.
47	Tisdall, J.M. and J.M. Oades. 1982. Organic matter and water stable aggregates in soils. J. Soil Sci. 33:141-163. DOI
48	Turral, H., J. Burke, and J.M. Faures. 2011. Climate change, water and food security. Available at: http://www.fao.org/docrep/014/i2096e/i2096e.pdf. Accessed in June 2017.
49	Vanotti, M.B. and L.G. Bundy. 1995. Soybean effects on soil nitrogen availability in crop rotations. Agron. J. 87:676-680. DOI
50	Vincent, J.M. 1970. A manual for the practical study of root nodule-bacteria. Blackwell Scientific Publication, Oxford.
51	Alves, B.J.R., L. Zotarelli, W.A.R. Lara-Cabezas, E. Torres, M. Hungria, S. Urquiaga, and R.M. Boddey. 2001. Benefit of legume-fixed N in crop rotations under zero-tillage. Nitrogen fixation: from molecules to crop productivity. pp. 533-534.
52	Wang, Q., Y. Li, and A. Alva. 2010. Cropping systems to improve carbon sequestration for mitigation of climate change. J. Environ. Prot. 1: 207-215. DOI
53	Yoo, C.H., C.H. Yang, K.B. Lee, J.G. Kim, T.Y. Uhm, J.D. So, and G.S. Rhee. 1995. Studies on paddy-upland rotation at fulvio-marine paddy soil 2. The change of yield and soil properties on cropping systems at paddy-upland rotation cultivation. RDA. J. Agric. Sci. 37(S & F):271-278.
54	Zhang, J., A.M. Blackmer, and T.M. Blackmer. 2008. Differences in physiological age affect diagnosis of nitrogen deficiencies in corn fields. Pedosphere 18:545-553. DOI
55	AgSource. 2015. Soil phosphorus reactions. Available at: http://documents.crinet.com//AgSource-Cooperative-Services/Agronomy/F-10957-15-v2Phos-Rxn-FS-GENERIC.pdf. Accessed in June 2017.
56	Ahn, S.B., T. Motomatsu, Y.S. Kim, K.S. Lee, and S.W. Hwang. 1992. Studies on rice productivity and mineral nutrients on the paddy-upland rotation system. Korean J. Soil Sci. Fert. 25:334-341.
57	Bartlova, J., B. Badalikova, L. Pospisilova, E. Pokorny, and B. Sarapatka. 2015. Water stability of soil aggregates in different systems of tillage. Soil Water Res. 10:147-154.
58	Bunt, A.C. and Z.J. Kulwiec. 1970. The effect of container porosity on root environment and plant growth: I. Temperature. Plant Soil 32:65-80. DOI
59	Buresh, R.J., K.R. Reddy, and C. van Kessel. 2008. Nitrogen transformations in submerged soils. pp. 401-436. In J.S. Scheper and W.R. Raun (ed.) Nitrogen in Agricultural Systems. Agron. Monogr. 49, ASA, CSSA, and SSSA. Madison, WI, USA.
60	Cameron, K.C., H.J. Di, and J.L. Moir. 2013. Nitrogen losses from the soil/ plant system: a review. Ann. Appl. Biol. 162:145-173. DOI