Extreme Rainfall Reduces One-twelfth of China's Rice Yield over the Last Two Decades

Overview

Journal Nat Food

Specialties Environmental Health
Nutritional Sciences

Date 2023 May 4

PMID 37142747

Authors

Jin Fu

Yiwei Jian

Xuhui Wang

Laurent Li

Philippe Ciais

Jakob Zscheischler

Yin Wang

Yanhong Tang

Christoph Muller

Heidi Webber

Bo Yang

Yali Wu

Qihui Wang

Xiaoqing Cui

Weichen Huang

Yongqiang Liu

Pengjun Zhao

Shilong Piao

Feng Zhou

Affiliations

Soon will be listed here.

Abstract

Extreme climate events constitute a major risk to global food production. Among these, extreme rainfall is often dismissed from historical analyses and future projections, the impacts and mechanisms of which remain poorly understood. Here we used long-term nationwide observations and multi-level rainfall manipulative experiments to explore the magnitude and mechanisms of extreme rainfall impacts on rice yield in China. We find that rice yield reductions due to extreme rainfall were comparable to those induced by extreme heat over the last two decades, reaching 7.6 ± 0.9% (one standard error) according to nationwide observations and 8.1 ± 1.1% according to the crop model incorporating the mechanisms revealed from manipulative experiments. Extreme rainfall reduces rice yield mainly by limiting nitrogen availability for tillering that lowers per-area effective panicles and by exerting physical disturbance on pollination that declines per-panicle filled grains. Considering these mechanisms, we projected ~8% additional yield reduction due to extreme rainfall under warmer climate by the end of the century. These findings demonstrate that it is critical to account for extreme rainfall in food security assessments.

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