Jashanjeet Kaur Dhaliwal, Dinesh Panday, G Philip Robertson, Debasish Saha
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We used a random forest machine learning model to predict daily N<sub>2</sub>O fluxes, trained separately for each system with 70% of observations, using variables such as crop species, daily air temperature, cumulative 2-day precipitation, water-filled pore space, and soil nitrate and ammonium concentrations. The model explained 29%-42% of daily N<sub>2</sub>O flux variability in the test data, with greater predictability for the corn phase in each system. The long-term rotations showed different controlling factors and threshold conditions influencing N<sub>2</sub>O emissions. In the conventional system, the model identified ammonium (>15 kg N ha<sup>-1</sup>) and daily air temperature (>23°C) as the most influential variables; in the no-till system, climate variables such as precipitation and air temperature were important variables. In low-input and organic systems, where red clover (Trifolium repens L.; before corn) and cereal rye (Secale cereale L.; before soybean) cover crops were integrated, nitrate was the predominant predictor of N<sub>2</sub>O emissions, followed by precipitation and air temperature. In low-input and biologically based systems, red clover residues increased soil nitrogen availability to influence N<sub>2</sub>O emissions. 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引用次数: 0
摘要
在集约化管理的种植系统中,土壤一氧化二氮(N2O)的排放量变化很大,这对我们了解其与控制因素之间复杂的相互作用提出了挑战。我们利用凯洛格生物站长期生态研究(LTER)/长期农业生态系统研究(LTAR)基地 17 年(2003-2019 年)的测量数据,更好地了解了采用常规、免耕、减少投入和生物/有机投入的四种玉米-大豆-冬小麦轮作中一氧化二氮排放的控制因素。我们使用随机森林机器学习模型来预测每天的一氧化二氮通量,该模型使用作物种类、日气温、2 天累积降水量、充满水的孔隙空间以及土壤硝酸盐和铵的浓度等变量,针对每个系统分别进行训练,观测量占 70%。该模型解释了测试数据中 29%-42% 的日一氧化二氮通量变化,对每个系统中玉米阶段的预测能力更强。长期轮作显示了影响 N2O 排放的不同控制因素和阈值条件。在常规系统中,模型确定铵(>15 kg N ha-1)和日气温(>23°C)是影响最大的变量;在免耕系统中,降水和气温等气候变量是重要变量。在低投入和有机系统中,红三叶(Trifolium repens L.,玉米前)和黑麦(Secale cereale L.,大豆前)覆盖作物相结合,硝酸盐是预测一氧化二氮排放量的主要因素,其次是降水和气温。在低投入和以生物为基础的系统中,红三叶草残留物增加了土壤氮的可用性,从而影响了一氧化二氮的排放。长期数据有助于通过机器学习预测 N2O 排放量,以应对不同的控制以及对管理、环境和生物地球化学驱动因素的阈值反应。
Machine learning reveals dynamic controls of soil nitrous oxide emissions from diverse long-term cropping systems.
Soil nitrous oxide (N2O) emissions exhibit high variability in intensively managed cropping systems, which challenges our ability to understand their complex interactions with controlling factors. We leveraged 17 years (2003-2019) of measurements at the Kellogg Biological Station Long-Term Ecological Research (LTER)/Long-Term Agroecosystem Research (LTAR) site to better understand the controls of N2O emissions in four corn-soybean-winter wheat rotations employing conventional, no-till, reduced input, and biologically based/organic inputs. We used a random forest machine learning model to predict daily N2O fluxes, trained separately for each system with 70% of observations, using variables such as crop species, daily air temperature, cumulative 2-day precipitation, water-filled pore space, and soil nitrate and ammonium concentrations. The model explained 29%-42% of daily N2O flux variability in the test data, with greater predictability for the corn phase in each system. The long-term rotations showed different controlling factors and threshold conditions influencing N2O emissions. In the conventional system, the model identified ammonium (>15 kg N ha-1) and daily air temperature (>23°C) as the most influential variables; in the no-till system, climate variables such as precipitation and air temperature were important variables. In low-input and organic systems, where red clover (Trifolium repens L.; before corn) and cereal rye (Secale cereale L.; before soybean) cover crops were integrated, nitrate was the predominant predictor of N2O emissions, followed by precipitation and air temperature. In low-input and biologically based systems, red clover residues increased soil nitrogen availability to influence N2O emissions. Long-term data facilitated machine learning for predicting N2O emissions in response to differential controls and threshold responses to management, environmental, and biogeochemical drivers.
期刊介绍:
Articles in JEQ cover various aspects of anthropogenic impacts on the environment, including agricultural, terrestrial, atmospheric, and aquatic systems, with emphasis on the understanding of underlying processes. To be acceptable for consideration in JEQ, a manuscript must make a significant contribution to the advancement of knowledge or toward a better understanding of existing concepts. The study should define principles of broad applicability, be related to problems over a sizable geographic area, or be of potential interest to a representative number of scientists. Emphasis is given to the understanding of underlying processes rather than to monitoring.
Contributions are accepted from all disciplines for consideration by the editorial board. Manuscripts may be volunteered, invited, or coordinated as a special section or symposium.