A global-scale drought assessment considering vegetation response to atmospheric CO2 changes

Daeha Kim

doi:10.3741/JKWRA.2025.58.9.781

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2025 Vol.58, Issue 9 Preview Page Next Page

Research Article

A global-scale drought assessment considering vegetation response to atmospheric CO₂ changes 식생의 대기 중 이산화탄소 반응을 고려한 전지구 가뭄위험 평가

30 September 2025. pp. 781-792

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Abstract

Climate change is increasing atmospheric evaporative demand (E_p), a key driver of future drought. However, conventional E_p estimation methods neglect the physiological responses of vegetation to rising atmospheric carbon dioxide concentration and vapor pressure deficit. To assess this impact, we projected future agricultural drought risk by applying two E_p models to outputs from 10 Coupled Model Intercomparison Project Phase 6 Earth System Models: a conventional formula (E_p-RC) and a two-source model (E_p-Veg) that dynamically considers changes in surface and aerodynamic resistances. We then used these E_p estimates to drive a precipitation-based (Standardized Precipitation-Evapotranspiration Index, SPEI) and an evaporation-based (Evaporative Stress Index, ESI) drought index. The resulting projections of drought duration and area through 2100 under different Shared Socioeconomic Pathways were compared against a benchmark soil moisture-based index (SSI). Our results show that E_p-RC consistently overestimates future drought severity and area compared to E_p-Veg. The projections using E_p-Veg were more consistent with the SSI benchmark, confirming that accounting for the water-saving effects of vegetation provides a more realistic risk assessment. However, a significant and growing discrepancy between the ESI and SSI projections remains, even when using the refined E_p-Veg model. This suggests that while modeling vegetation physiology is crucial, inherent structural limitations within the E_p framework, driven by land-atmosphere interactions, are also major uncertainty sources in future drought assessments.

Keywords

Atmospheric evaporative demand

Vegetation physiological responses

Two-source model

Drought risk assessment

기후변화에 따른 대기증발요구량(E_p) 증가는 미래 가뭄 위험 평가의 핵심 요소이지만, 전통적인 E_p 산정 방식은 상승하는 대기 중 이산화탄소 농도와 Vapor Pressure Deficit에 대한 식생의 생리적 반응을 무시한다. 본 연구에서는 식생 반응이 농업가뭄 위험 전망에 미치는 영향을 평가하기 위해 전통적인 공식(E_p-RC)과 지면저항의 동적 변화를 고려하는 two-source E_p 모형(E_p-Veg)을 Coupled Model Intercomparison Project Phase 6 10개 지구시스템 모형에 적용해 미래 E_p를 산정하고 가뭄위험을 전망하였다. 두 E_p 전망치를 이용해 강수 기반의 Standardized Precipitation- Evapotranspiration Index (SPEI)와 증발산량 기반의 Evaporative Stress Index (ESI)을 산정한 후 Shared Socioeconomic Pathways 배출경로에 따른 2100년까지의 가뭄 지속기간과 면적 변화를 전망하고, 토양수분 기반 Standardized Soil moisture Index (SSI)와 비교하였다. 분석 결과, E_p-RC는 E_p-Veg에 비해 미래 가뭄의 심도와 면적을 일관되게 과대평가하는 것으로 나타났다. E_p-Veg기반의 가뭄 전망은 SSI가 나타내는 토양수분 변화와 더 높은 일관성을 보여, 식생의 수분 보존 효과를 고려하는 것이 더 현실적인 위험 평가를 가능하게 함을 확인했다. 하지만 식생 반응을 고려했음에도 불구하고, 특히 ESI와 SSI의 미래 전망 사이에는 시간이 갈수록 커지는 상당한 불일치가 여전히 존재했다. 이는 식생의 생리적 반응을 고려하는 것이 미래 가뭄 위험의 과대평가를 완화하는 중요한 단계이기는 하지만, 지면-대기상호작용과 같은 E_p 산정방식 자체에 내재된 구조적 한계 또한 중요한 불확실성 요인임을 시사한다.

키워드

대기증발요구량

식생 생리적 반응

Two-source 모형

가뭄위험평가

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Information

Publisher :KOREA WATER RESOURECES ASSOCIATION
Publisher(Ko) :한국수자원학회
Journal Title :Journal of Korea Water Resources Association
Journal Title(Ko) :한국수자원학회 논문집
Volume : 58
No :9
Pages :781-792
Received Date : 2025-08-13
Revised Date : 2025-08-30
Accepted Date : 2025-09-08
DOI :https://doi.org/10.3741/JKWRA.2025.58.9.781

Journal of Korea Water Resources Association ISSN:2799-8746(Print) 2799-8754(Online) 한국수자원학회 논문집

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