CLIMATE-CHANGE-INDUCED TEMPORAL VARIATION IN PRECIPITATION INCREASES NITROGEN LOSSES FROM INTENSIVE CROPPING SYSTEMS: ANALYSIS WITH A TOY MODEL

IF 3.6 4区农林科学 Q1 AGRONOMY Frontiers of Agricultural Science and Engineering Pub Date : 2022-01-01 DOI:10.15302/j-fase-2022452

Xin-ping Chen, Z. Cui, Xuejun Liu, P. Matson, I. Ortiz-Monasterio, G. Robertson, Fusuo Zhang

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Abstract

A simple model to how increasing temporal variability in precipitation yields are reduced and nitrogen losses are increased levels of precipitation variability. ABSTRACT A simple ‘toy’ model of productivity and nitrogen and phosphorus cycling was used to evaluate how the increasing temporal variation in precipitation that is predicted (and observed) to occur as a consequence of greenhouse-gas-induced climate change will affect crop yields and losses of reactive N that can cause environmental damage and affect human health. The model predicted that as temporal variability in precipitation increased it progressively reduced yields and increased losses of reactive N by disrupting the synchrony between N supply and plant N uptake. Also, increases in the temporal variation of precipitation increased the frequency of floods and droughts. Predictions of this model indicate that climate-change-driven increases in temporal variation in precipitation in rainfed agricultural ecosystems will make it difficult to sustain cropping systems that are both high-yielding and have small environmental and human-health footprints.

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气候变化引起的降水时间变化增加了集约化种植系统的氮损失:用玩具模型分析

一个简单的模型，说明降水产量增加的时间变异性是如何减少的，氮损失是如何增加降水变异性水平的。一个简单的生产力和氮磷循环的“玩具”模型被用来评估由于温室气体引起的气候变化而预测(和观测到)降水的时间变化如何影响作物产量和活性氮的损失，从而导致环境破坏和影响人类健康。该模型预测，随着降水的时间变异性增加，通过破坏氮供应和植物氮吸收之间的同步，它逐渐降低了产量，增加了活性氮的损失。此外，降水时间变化的增加增加了洪水和干旱的频率。该模型的预测表明，气候变化驱动的雨养农业生态系统降水时间变化的增加，将使既高产又对环境和人类健康影响小的种植系统难以维持。

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来源期刊

Frontiers of Agricultural Science and Engineering AGRONOMY-

CiteScore

5.10

自引率

2.70%

发文量

期刊介绍： Frontiers of Agricultural Science and Engineering (FASE) is an international journal for research on agricultural science and engineering. The journal’s aim is to report advanced and innovative scientific proceedings in agricultural field including Crop Science, Agricultural Biotechnology, Horticulture, Plant Protection, Agricultural Engineering, Forestry Engineering, Agricultural Resources, Animal Husbandry and Veterinary Medicine, Applied Ecology, Forestry and Fisheries. FASE is committed to provide a high level scientific and professional forum for researchers worldwide to publish their original findings and to utilize these novel findings to benefit the society.