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Evaluation of Site-specific Potential for Rice Production in Korea under the Changing Climate  

Chung, U-Ran (Department of Plant Science, Seoul National University)
Cho, Kyung-Sook (Climate Prediction Division, Korea Meteorological Administration)
Lee, Byun-Woo (Department of Plant Science, Seoul National University)
Publication Information
Korean Journal of Agricultural and Forest Meteorology / v.8, no.4, 2006 , pp. 229-241 More about this Journal
Abstract
Global air temperature has risen by $0.6^{\circ}C$ over the last one hundred years due to increased atmospheric greenhouse gases. Moreover, this global warming trend is projected to continue in the future. This study was carried out to evaluate spatial variations in rice production areas by simulating rice-growth and development with projected high resolution climate data in Korea far 2011-2100, which was geospatially interpolated from the 25 km gridded data based on the IPCC SRES A2 emission scenario. Satellite remote sensing data were used to pinpoint the rice-growing areas, and corresponding climate data were aggregated to represent the official 'crop reporting county'. For the simulation experiment, we used a CERES-Rice model modified by introducing two equations to calculate the leaf appearance rate based on the effective temperature and existing leaf number and the final number of leaves based on day-length in the photoperiod sensitive phase of rice. We tested the performance of this model using data-sets obtained from transplanting dates and nitrogen fertilization rates experiments over three years (2002 to 2004). The simulation results showed a good performance of this model in heading date prediction [$R^2$=0.9586 for early (Odaebyeo), $R^2$=0.9681 for medium (Hwasungbyeo), and $R^2$=0.9477 for late (Dongjinbyeo) maturity cultivars]. A modified version of CERES-Rice was used to simulate the growth and development of three Japonica varieties, representing early, medium, and late maturity classes, to project crop status for climatological normal years between 2011 and 2100. In order to compare the temporal changes, three sets of data representing 3 climatological years (2011-2040, 2041-2070, and 2071-2100) were successively used to run the model. Simulated growth and yield data of the three Japonica cultivars under the observed climate for 1971-2000 was set as a reference. Compared with the current normal, heading date was accelerated by 7 days for 2011-2040 and 20 days for 2071-2100. Physiological maturity was accelerated by 15 days for 2011-2040 and 30 days for 2071-2100. Rice yield was in general reduced by 6-25%, 3-26%, and 3-25% per 10a in early, medium, and late maturity classes, respectively. However, mid to late maturing varieties showed an increased yield in northern Gyeonggi Province and in most of Kwangwon Province in 2071-2100.
Keywords
Rice; Climate change; CERES-Rice; Gridded climate data; Japonica rice;
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Times Cited By KSCI : 3  (Citation Analysis)
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1 Chipanshi, A. C., R. Chanda, and O. Totolo, 2003: Vulnerability assessment of the maize and sorghum crops to climate changes in Botswana. Climatic Change 61(3), 339-360   DOI   ScienceOn
2 Chung, U., J. Y. Choi, and J. I. Yun, 2004: Urbanization effect on the observed change in mean monthly temperatures between 1951-1980 and 1971-2000 in Korea. Climatic Change 66, 127-136   DOI   ScienceOn
3 Dodson, R., and D. Marks, 1997: Daily temperature interpolated at high spatial resolution over a large mountainous region. Climate Research 8(1), 1-20   DOI
4 Koo, J. M., S. Y. Hong, and J. I. Yun, 2001: A simple method for classifying land cover of rice paddy at a 1 km grid spacing using NOAA-AVHRR data. Korean Journal of Agricultural and Forest Meteorology 3(4), 215-219.
5 Lee, D. Y., M. H. Kim, K. J. Lee, and B. W. Lee, 2006:Changes in Radiation Use Efficiency of rice canopies under different nitrogen nutrition status. Korean Journal of Agricultural and Forest Meteorology 8(3), 190-198   과학기술학회마을
6 Shim, K. M., Y. S. Lee, Y. K. Shin, K. Y. Kim, and J. T. Lee, 2005: Changes in simulated rice yields under GCM $2_XCO_2$ climate change scenarios. Proceedings ofthe 8th Conference on Agricultural and Forest Meteorology (Sangju University, Korea, 29-30 September 2005), 88-92
7 Yun, J. I., 2000: Estimation of climatological precipitation of North Korea by using a spatial interpolation scheme. Korean Journal ofAgricultural and Forest Meteorology 2(1), 16-23
8 Yun, J. I., and K. H. Lee, 2000: Agroclimatology of North Korea for paddy rice cultivation: Preliminary results from a simulation experiment. Korean Journal of Agricultural and Forest Meteorology 2(2), 47-61
9 Yun, S. H., and J. T. Lee, 2001: Climate change impacts on optimum ripening periods of rice plant and its countermeasure in rice cultivation. Korean Journal of Agricultural and Forest Meteorology 3(1), 55-70
10 Trnka, M., M. Dubrovsky, and Z. Zalud, 2004: Climate change impacts and adaptation strategies in spring barley production in the Czech Republic. Climatic Change 64, 227-255.   DOI
11 Olsyzk, D. M., H. G S. Centeno, L. H. Ziska, J. S. Kern, and R. B. Matthews, 1999: Global climate change, rice productivity and methane emissions: comparison of simulated and experimental results. Agricultural and Forest Meteorology 97(2),87-101   DOI   ScienceOn
12 Yun, J. I., 1990: Analysis of the climatic impact on Korean rice production under the carbon dioxide scenario. Journal of Korean Meteorological Society 26(4), 263-274
13 Hansen, J., W. Lawrence, D. Easterling, T. Peterson, T. Karl, R. Ruedy, M. Sato, and M. Imhoff, 2001: A closer look at United States and global surface temperature change. Journal of Geophysical Research(D: Atmospheres) 106(20),23947-23963   DOI
14 Southworth, J., R. A. Pfeifer, M. Habeck, J. C. Randolpf, O. C. Doering, J. J. Johnston, and D. G Rao, 2002: Changes in soybean yields in the midwestern United States as a result of future changes in climate, climate variability, and $CO_2$ fertilization. Climatic Change 53(4), 447-475   DOI   ScienceOn
15 Gallo, K. P., and T. W. Owen, 1999: Satellite-based adjustments for the urban heat island temperature bias. Journal of Applied Meteorology 38(6), 806-813   DOI
16 Yun, J. I., 2004: Visualization of local climates based on geospatial climatology. Korean Journal of Agricultural and Forest Meteorology 6(4), 272-289.
17 Lee, C. K., B. W. Lee, J. C. Shin, and Y. H. Yoon, 2001b: Heading date and final leaf number as affected by sowing date and prediction of heading date based on leaf appearance model in rice. Korean Journal of Crop Science 46(3), 195-201
18 권원태, 2004: 기후변화와의 과학적 현황과 전망 . 환경부 . 기상청 . 한국기상학회 공동주관 제 2 차 기후변화 학술대회 초록집 1-4. (2004 년 II 월 18-19 일, 대구 ).
19 Ritchie, J. T., D. C. Godwin, and U. Singh, 1990: Soil and weather inputs for IBSNAT crop models. In: Proceedings of IBSNAT Symposium: Decision Support System for Agrotechnology Transfer. University of Hawaii, Honolulu, USA
20 Kim, Y. H., H. D. Kim, S. W. Han, J. Y. Choi, J. M. Koo, U. Chung, J. Y. Kim, and Jin I. Yun, 2002: Using spatial data and crop growth modeling to predict performance of South Korean rice varieties grown in western coastal plains in North Korea. Korean Journal of Agricultural and Forest Meteorology 4(4), 224-236.
21 Lemaire, G, F. Gastal, and F. Salette, 1989: Analysis of the effect of N nutrition on dry matter yield of a sward by reference to potential yield and optimum N content. In: Proceedings of the 16th International Grassland Congress. (Nice, France), 179-180
22 Choi, J. Y., U. Chung, and J. I. Yun, 2003: Urban-effect correction to improve accuracy of spatially interpolated temperature estimates in Korea. Journal of Applied Meteorology 42(12), 1711-1719   DOI   ScienceOn
23 Yun, J. I., 2003: Predicting regional rice production in South Korea using spatial data and crop-growth modeling. Agricultural Systems 77(1), 23-38   DOI   ScienceOn
24 Lee, C. K., B. W. Lee, Y. H. Yoon, and J. C. Shin, 2001a: Temperature response and prediction model of leaf appearance rate in rice. Korean Journal of Crop Science 46(3), 202-208
25 Ulrich, A. 1952: Physiological bases for assessing the nutritional requirements of plants. Annual Review of Plant Physiology 3,207-228   DOI
26 Bum, Y., K. J. Lee, and B. W. Lee, 2006: Comparison of traits related to dry matter production and grain yield among rice cultivars released in different years. Korean Journal of Agricultural and Forest Meteorology 8(3), 183-189   과학기술학회마을
27 Peterson, T. C., A. Huang, D. A. Mckittrick, K. P. Gallo, J. Lawrimore, and T. W. Owen, 1999: Global rural temperature trends. Geophysical Research Letters 26(3), 329-332   DOI   ScienceOn
28 Gallo, K. P., J. O. Adegoke, T. W. Owen, and C. D. Elvidge, 2002: Satellite-based detection of global urban heat-island temperature influence. Journal of Geophysical Research (D: Atmosphere) 107, ACLJ6-1-ACLJ6-6
29 기상연구소 기후연구설, 2005: 한반도 기후 100년 변화와 미래 전망. 제 3차 기후변화학술대회 및 제 2차 기후변화 정책 포럼 CD-ROM (2005년 9월 7-8일, 서울)
30 Cui, R. X., M. H. Kim, J. H. Kim, H. S. Nam, and B. W. Lee, 2002: Determination of critical nitrogen concentration and dilution Curve for rice growth. Korean Journal of Crop Science 47(2), 127-131
31 Nalder, I. A., and R. W. Wein, 1998: Spatial interpolation of climatic normals: test of a new method in the Canadian boreal forest. Agricultural and Forest Meteorology 92(4), 211-225   DOI   ScienceOn
32 Thomson, A. M., R. A. Brown, S. J. Ghan, R. C.lzaurralde, N. J. Rosenberg, and L. R. Leung, 2002: Elevation dependence of winter wheat production in eastern Washington State with climate change: a methodological study. Climatic Change 54, 141-164   DOI   ScienceOn
33 Pickering, N. B., J. W. Hansen, J. W. Jones, H. Chan, and D. Godwin, 1994: WeatherMan: a utility for managing and generating daily weather data. Agronomy Journal 86, 332-337   DOI   ScienceOn