Modelling of the impact of climate change on the transformation of nitrogen forms in the soil and N2O emissions from the agroecosystems of Eastern Ukraine
A. Polevoy, A. Mykytiuk, L. Bozhko, E. Barsukova, K. Husieva
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引用次数: 0
Abstract
The moisture-temperature regime influences the nitrogen status of the soil and the microbiological processes of the transformation of nitrogen forms. Therefore, we assumed that ongoing climate change may affect the emission of nitrous oxide N2O, which is formed in the course of the transformation of nitrogen forms in the soil and is one of the most aggressive greenhouse gases that determine the global warming potential. To test this hypothesis and make a quantitative assessment of the impact of climate change on the transformation of nitrogen forms in the soil and N2O emissions from the agroecosystem soils, we used a complex model of greenhouse gas emissions from an agroecosystem soil that we developed and the RCP4.5 climate change scenario. The research was performed for the chernozem soils of Eastern Ukraine, with winter wheat being the cultivated crop. ‘Dry’ and ‘wet’ years typical for the period of 2021–2050 were selected among climate conditions in accordance with the climate change scenario. A ‘dry’ year was considered to be a year with a precipitation of 60% or less of the long-term average, a ‘wet’ year was a year with a precipitation of 130% or more of the long-term average for the studied period. The level of ammonification during the growing season for both ‘dry’ and partially ‘wet’ years was mainly controlled by temperature. At the beginning of the period, at negative temperatures below –3 °C ammonification and nitrification almost stopped, and at temperatures above –2 °C they slightly increased. Indices for the intensity of these processes increased with a rise in temperature from 0 °C to 10–11 °C. In the conditions of a ‘dry’ year an increment in temperature to the level of 22.4–27.8 °C caused a sharp increase in the rate of ammonification and caused a high level of the rate of nitrification. For the conditions of a ‘wet’ year with a sufficiently low (compared to a ‘dry’ year) temperature regime, a relatively significant rise in temperature with still quite good humidification increased the intensity of the ammonification process. The dependence of the intensity of the ammonification and nitrification processes on the moisture reserves in the soil is traced. The high level of moisture reserves in the arable layer at the beginning of the growing season in both ‘dry’ and ‘wet’ years formed anaerobic conditions in the upper layer of the soil. Against the background of rising temperatures, this called forth the denitrification process. N2O emission was 0.03–0.29 g N-N2O/ha•day due to the denitrification process in a ‘dry’ year, and 0.7–5.2 g N-N2O/ha•day in a ‘wet’ year. The highest level of N2O emission due to nitrification was observed in a ‘dry’ year in the middle of the vegetation period at high temperatures (22.7–27.8 °С) and amounted to 8.2–11.2 g N-N2O/ha•day. A decrease in soil moisture reserves during the second half of the growing season reduced the level of N2O emissions. Nitrification was the main process producing N2O. The emissions of N2O with moisture reserves greater than 55 mm in the arable layer occurred due to denitrification. A rise in temperature increases the level of N2O emissions. The peculiarities of the influence of moisture and temperature conditions of ‘dry’ and ‘wet’ years on the processes of ammonification, nitrification, denitrification, and N2O emissions from chernozem soils according to the RCP4.5 climate change scenario in Eastern Ukraine were assessed.
湿度-温度状况影响土壤的氮状况以及氮形态转化的微生物过程。因此,我们假设持续的气候变化可能会影响一氧化二氮的排放,这是在土壤中氮形态转化过程中形成的,是决定全球变暖潜力的最具侵略性的温室气体之一。为了检验这一假设,并对气候变化对土壤中氮形态转化和农业生态系统土壤N2O排放的影响进行定量评估,我们使用了我们开发的农业生态系统土地温室气体排放的复杂模型和RCP4.5气候变化情景。这项研究是针对乌克兰东部的黑钙土进行的,种植的作物是冬小麦根据气候变化情景,在气候条件中选择了2021年至2050年的典型干旱和潮湿年份。“干旱”年被认为是降水量为长期平均值60%或以下的年份,“湿润”年被视为降水量为研究期间长期平均值130%或以上的年份。在“干旱”和部分“湿润”年份的生长季节,氨化水平主要受温度控制。在这一时期开始时,在低于-3°C的负温度下,氨化和硝化几乎停止,而在高于-2°C的温度下,它们略有增加。这些过程的强度指数随着温度从0°C上升到10–11°C而增加。在“干旱”年份的条件下,温度升高到22.4–27.8°C的水平会导致氨化速率急剧增加,并导致高水平的硝化速率。对于温度足够低的“潮湿”年份(与“干燥”年份相比),相对显著的温度上升和相当好的加湿增加了氨化过程的强度。追踪了氨化和硝化过程的强度对土壤水分储量的依赖性。在“干旱”和“潮湿”年份的生长季节开始时,耕作层的高水分储量在土壤上层形成了厌氧条件。在温度升高的背景下,这就提出了脱氮过程。在“干旱”年份,由于脱氮过程,N2O排放量为0.03–0.29 g N-N2O/ha•天,在“潮湿”年份,N2O的排放量为0.7–5.2 g N-N2O/ha•天。在高温(22.7–27.8°С)下植被期中期的“干旱”年份,由于硝化作用,N2O排放量最高,达8.2–11.2 g N-N2O/ha•day。生长季节后半段土壤水分储量的减少降低了N2O的排放水平。硝化作用是产生N2O的主要过程。耕作层中水分储量大于55mm的N2O排放是由于反硝化作用造成的。温度升高会增加一氧化二氮的排放量。根据RCP4.5气候变化情景,评估了乌克兰东部“干旱”和“潮湿”年份的水分和温度条件对黑钙土氨化、硝化、反硝化和N2O排放过程的影响特点。