Effects of Climatic Change on Maize Varieties Distribution in the Future of Northeast China
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摘要: 为探求未来气候变化对我国东北玉米品种布局的影响,基于玉米生产潜力和气候资源利用率,结合区域气候模式输出的2011—2099年RCP_4.5,RCP_8.5两种气候背景气象资料和1961—2010年我国东北地区91个气象站的观测数据,分析了未来气候变化情况下,东北玉米品种布局、生产潜力、气候资源利用率的时空变化。结果表明:未来东北地区玉米可种植边界北移东扩,南部为晚熟品种,新扩展区域以早熟品种为主,不能种植区域减少。未来玉米生产潜力为南高北低,增加速率均高于历史情景,水分适宜度最低,而历史情景下温度是胁迫玉米生产的关键因子。未来东北玉米对气候资源利用率整体下降,其中RCP8.5情景利用率最低。Abstract: Rising ground temperature as a part of climate change has a considerable influence on the climate and environment. Northeast China, as one major grain area ensuring the food security in China, suffers serious impacts of the climate change. Traditional cultivation ways cannot adapt the new situation, leading to an increasing instability of the agricultural system. The planting system, structure and layout cannot match the original climatic resources. The research adopts the RCPs situation instead of the original SRES scenarios data, to provide a reasonable variety selection, and a scientific basis for dealing with the climate change in the future. To explore effects of future climate change on maize varieties and climatic potential productivity in Northeast China, simulations are carried out with regional climate model, using two emission scenarios RCP4.5, RCP8.5 during 2011-2099, and daily observations of 91 stations during 1961-2010. A series of analysis are carried out on the temporal and spatial distribution of maize variety, climatic potential productivity, resource utilization ratio under the situation of climate change in the future. The result shows that in the baseline scenario (1961-2010), the late maturing varieties can be planted in smaller southern areas, while they cannot grow in northern areas. Under the condition of RCP4.5 and RCP8.5(2011-2099), suitable areas for late maturing varieties will expand, and in RCP8.5, the suitable areas are the largest. The climatic potential productivity in Northeast China is high in the south while low in the north. In the baseline scenario, the annual production is 10492.54 kg·hm-2, and in RCP4.5 it increases to 10697.16 kg·hm-2, while in RCP8.5 it drops to 9410.17 kg·hm-2. The maize potential productivity increases with this climate change trend in the whole area. In the baseline scenario, the radiation suitability is highest but the temperature suitability is lowest for maize production. With the climate change, the radiation suitability and temperature suitability both increase, but the water suitability will decrease to 0.63 and 0.48 in scenarios of RCP4.5 and RCP8.5, which will become a main factor that restricts the production of crop in Northeast China. In the baseline scenario, the resource utilization rate is 0.826, and its growth rate is 0.009/(10 a). In the situation of RCP4.5, RCP8.5, they are 0.804 and 0.647, and growth rates are 0.010/(10 a) and -0.002/(10 a). Suitable areas for late maturing varieties expand evidently, but the potential productivity of maize and resources utilization declines. It should also be noted that the regional climate model may bring uncertainties to results.
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表 1 不同品种玉米及各生育阶段热量指标(单位:℃·d)
Table 1 Heat index of various maize growing stages(unit:℃·d)
品种 播种-出苗期 出苗-拔节期 拔节-抽雄期 抽雄-成熟期 播种-成熟期 早熟 209.7 576.6 413.8 1045.2 2245.3 中熟 226.3 912.7 385.5 1130.0 2645.5 中晚熟 248.1 967.8 493.5 1234.0 2943.4 晚熟 231.1 994.4 538.4 1321.1 3085.0 表 2 东北玉米三基点温度(单位:℃)
Table 2 Three-fundamental-point temperature of maize in Northeast China(unit:℃)
界限温度 播种-出苗期 出苗-拔节期 拔节-抽雄期 抽雄-成熟期 生长上限温度 10 12 16 15 最适上限温度 20 22 27 22 最适下限温度 28 26 30 27 生长下限温度 35 35 35 35 表 3 1961—2099年东北玉米年平均光照、温度、水分年平均适宜度
Table 3 Averaged annual radiation suitability, temperature suitability and water suitability of maize of Northeast China in 1961-2099
情景 气候适宜度 光照 温度 水分 历史情景 0.9345 0.6639 0.7558 RCP4.5情景 0.9540 0.7312 0.6372 RCP8.5情景 0.9559 0.7612 0.4839 -
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