Vapour Pressure Deficit Determines Critical Thresholds for Global Coffee Production Under Climate Change

Overview

Journal Nat Food

Specialties Environmental Health
Nutritional Sciences

Date 2023 Apr 28

PMID 37117886

Authors

Jarrod Kath

Alessandro Craparo

Youyi Fong

Vivekananda Byrareddy

Aaron P Davis

Rachel King

Thong Nguyen-Huy

Piet J A van Asten

Torben Marcussen

Shahbaz Mushtaq

Roger Stone

Scott Power

Affiliations

Soon will be listed here.

Abstract

Our understanding of the impact of climate change on global coffee production is largely based on studies focusing on temperature and precipitation, but other climate indicators could trigger critical threshold changes in productivity. Here, using generalized additive models and threshold regression, we investigate temperature, precipitation, soil moisture and vapour pressure deficit (VPD) effects on global Arabica coffee productivity. We show that VPD during fruit development is a key indicator of global coffee productivity, with yield declining rapidly above 0.82 kPa. The risk of exceeding this threshold rises sharply for most countries we assess, if global warming exceeds 2 °C. At 2.9 °C, countries making up 90% of global supply are more likely than not to exceed the VPD threshold. The inclusion of VPD and the identification of thresholds appear critical for understanding climate change impacts on coffee and for the design of adaptation strategies.

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