Linking freshwater hydrology to global food security in the Mekong Basin

Linking freshwater hydrology to global food security in the Mekong Basin

Tropical flood pulse rivers are crucial for global food security, especially in developing nations. The Mekong River basin is one of the world’s most significant agricultural regions, sustaining millions through rice production and export. However, rapid hydrological changes from hydropower developm...

Full description

Saved in:
Bibliographic Details
Main Authors: Joseph Holway, Qi Deng, Sepehr Eslami, Van Pham Dang Tri, P Peng Bun Ngor, John Sabo
Format: Article
Language:English
Published: IOP Publishing 2025-01-01
Series:Environmental Research Letters
Subjects:
food energy water nexus
food security
Mekong
design flows
Online Access:https://doi.org/10.1088/1748-9326/add60c
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:Tropical flood pulse rivers are crucial for global food security, especially in developing nations. The Mekong River basin is one of the world’s most significant agricultural regions, sustaining millions through rice production and export. However, rapid hydrological changes from hydropower development, altered flow regimes, and climate variability threaten the flood pulses essential for rice cultivation. Using a multivariate autoregressive state space analysis, we examined how hydrological variability influences rice production across four lower Mekong basin countries: Cambodia, Laos, Thailand, and Viet Nam. Our study integrated high-resolution hydrologic and agricultural data spanning decades to assess the effects of flood magnitude, duration, and saline intrusion on rice yields. We found significant spatial tradeoffs, particularly in areas affected by flooding and salinity. In Viet Nam, large flood pulses mitigate saline intrusion and expand arable land but reduce cultivation efficiency likely due to fertilizer runoff. In Cambodia, where saline intrusion is minimal, excessive flooding lead to field inundation and reduced arable land, decreasing yields. Our findings reveal the complex interactions between hydrology, land use, and agricultural productivity, emphasizing the need for coordinated transboundary water management. By identifying key tradeoffs, this research informs decision-makers on optimizing agricultural strategies to ensure food system resilience amid changing hydrological and climatic conditions.
ISSN:1748-9326

Similar Items