水分条件影响下玉米生产过程的生命周期评价

doi:10.19741/j.issn.1673-4831.2019.0004

摘要/Abstract

摘要： 研究了不同水分条件对玉米种植全过程中的产量和环境排放的影响以及相应改进措施。利用山西省太谷县2002-2016年15 a间的气象数据、玉米种植过程的施肥和灌溉数据、土壤数据以及玉米生长发育数据，采用时间替换空间方法和经本地化校正的DNDC（denitrification-decomposition）模型和数值模拟方法，模拟玉米种植全过程中降水量和施肥量变化下CO₂、NH₃和N₂O排放量及硝酸盐淋洗量，利用生命周期评价方法评价玉米全生长过程对资源消耗和环境排放的定量影响，分析比较了降水量和资源消耗与环境排放的关系，并提出不同降水年型的合理施肥量和灌溉量。结果表明：（1）当降水量处于300~600 mm之间时，降水量与CO₂排放量、硝酸盐淋洗量、N₂O排放量呈显著正相关（P<0.05），与NH₃挥发量呈显著负相关（P<0.05）；（2）年降水量大于560 mm（丰水年）条件下玉米种植全过程的环境影响综合指数为0.19~0.20，年降水量为380~560 mm（平水年）条件下环境影响综合指数为0.17~0.27，年降水量低于380 mm（枯水年）条件下的环境影响综合指数在0.3以上，不同降水年型玉米种植全过程对环境的影响依次为枯水年、平水年和丰水年；（3）数值模拟结果表明降水量小于380 mm时，在施肥量不变条件下，增加灌溉能够增加产量，减少排放，环境影响综合指数降至0.2以下；在无灌溉条件下，将施肥量减少为210~315 kg·hm^-2，环境影响综合指数可降低至0.2~0.3，产量降低幅度为3.15%；平水年施肥量减少到原施肥量的80%~85%时，产量无显著下降，但环境影响显著降低。温室效应、富营养化、能源消耗和环境酸化与降水年型相关。水分对玉米种植全过程的环境影响较大，当水分条件充足时，籽粒产量高且环境影响较小，当水分供给不足时，籽粒产量低且对环境影响升高。在枯水年建议有灌溉条件的地区增加灌溉量，无灌溉条件的地区减少施肥量；在平水年减少施肥量，可降低玉米生长对环境造成的影响。

关键词: 生命周期评价, DNDC模型, 玉米, 水分条件

Abstract: For assessing the impacts of different water conditions on maize yield and environmental emissions of maize production, and for identifying the corresponding improvement measures, the meteorological data, and the data of fertilization, irrigation, soil properties as well as the development of maize growth were all collected in Taigu County, Shanxi Province from 2002 to 2016. The emissions of CO₂, NH₃, N₂O and nitrate leaching during the period of maize growing season with changing amounts of rainfall and fertilization were simulated by using the DNDC model. The life cycle assessment approach was applied to quantitatively evaluate the impact of maize growth on the resource use and environmental emissions; Then the relationships between rainfall and the resource consumption and emission were analyzed, and the reasonable amounts of fertilization and irrigation under different rainfall patterns were recommended. (1) When the rainfall ranged from 300 mm to 600 mm, the rainfall was positively correlated with the emissions of CO₂, nitrate leaching and NH₃ volatilization (P<0.05), while it was negatively correlated with N₂O emission. (2) When the rainfall was above 560 mm, namely abundant rainfall year, the comprehensive impact factor in the whole process of maize production ranged from 0.19 to 0.20, it was in the range of 0.17-0.27 in normal year with the rainfall from 380 to 560 mm, while it was 0.3 in dry year with the rainfall below 380 mm, respectively. The whole process of maize production had much high impacts on the environment in the dry year, followed by the normal year and abundant rainfall year. (3) The results of numerical simulation indicate that when the rainfall was below 380 mm and fertilization rate was fixed, with the increasing of the irrigation amounts, the yield was increased and the environmental emission was reduced, and the comprehensive impact factor declined to less than 0.2. Under rainfed conditions, the comprehensive impact factor will fall to 0.2-0.3 and the yield was only decreased by 3.15% when the fertilization rate was reduced to 210-315 kg·hm^-2; In the normal year, if the fertilization rate was decreased by 15% to 20%, the yield did not drop remarkably, but the impact on the environment was reduced obviously. Global warming potential, eutrophication potential, energy consumption and land use were correlated with the annual rainfall patterns. Irrigation has a great influence on the environment in the whole process of maize production. The sufficient irrigation led to high yield and less environmental impact, while the shortage of water resulted in low yield and much more environmental impact. Therefore, it is suggested to increase the amount of irrigation in dry years, and to decrease fertilization rate to reduce the environmental impact of maize production in rainfed areas.

Key words: life cycle assessment, denitrification-decomposition (DNDC) model, maize, water condition

中图分类号:

X820.3

吴晋波, 张吴平, 王国芳, 卜玉山, 贾若男, 张茜, 张小红. 水分条件影响下玉米生产过程的生命周期评价[J]. 生态与农村环境学报, 2019, 35(11): 1396-1403.

WU Jin-bo, ZHANG Wu-ping, WANG Guo-fang, BU Yu-shan, JIA Ruo-nan, ZHANG Xi, ZHANG Xiao-hong. Life Cycle Assessment of the Maize Production Under Different Water Conditions[J]. Journal of Ecology and Rural Environment, 2019, 35(11): 1396-1403.

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