土地利用和土地覆盖变化对温度相关死亡率的影响。

IF 3.3 Q2 ENVIRONMENTAL SCIENCES Environmental Epidemiology Pub Date : 2024-10-21 eCollection Date: 2024-12-01 DOI:10.1097/EE9.0000000000000337
Anton Orlov, Steven J De Hertog, Felix Havermann, Suqi Guo, Iris Manola, Quentin Lejeune, Carl-Friedrich Schleussner, Wim Thiery, Julia Pongratz, Florian Humpenöder, Alexander Popp, Kristin Aunan, Ben Armstrong, Dominic Royé, Ivana Cvijanovic, Eric Lavigne, Souzana Achilleos, Michelle Bell, Pierre Masselot, Francesco Sera, Ana Maria Vicedo-Cabrera, Antonio Gasparrini, Malcolm N Mistry
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引用次数: 0

摘要

背景:土地利用和土地覆被变化(LULCC)可通过生物地球化学和生物地球物理效应对气候产生重大影响。在此,我们研究了在温室气体浓度较低的背景气候下,两种截然不同的 LULCC 情景对未来温度-死亡率的影响。第一种 LULCC 情景意味着全球可持续的土地利用和社会经济发展(可持续性)。在第二种 LULCC 情景中,可持续性只在经济合作与发展组织国家(不平等)中实现:方法:我们利用多国多城市(MCC)数据集估算了 52 个国家和地区 823 个地点的温度-死亡率暴露-反应函数(ERF)。LULCC 和 noLULCC 情景在三个完全耦合的地球系统模型 (ESM) 中实现:共同体地球系统模式、马克斯-普朗克研究所地球系统模式和欧洲财团地球系统模式。接下来,我们利用 ESMs 模拟的温度和估计的特定地点 ERF,评估了本世纪中叶和末期 LULCC 和 noLULCC 情景下温度对死亡率的影响:在可持续性条件下,到 2050-2059 年,所有地点的多模型平均超额死亡率变化范围为-1.1 到 +0.6 个百分点,到 2090-2099 年为-1.4 到 +0.5 个百分点。在不平等的情况下,到 2050-2059 年,超额死亡率从-0.7 到+0.9 个百分点不等,到 2090-2099 年,从-1.3 到+2 个百分点不等:不平等的社会经济发展和不可持续的土地利用可能会增加大多数地区与热有关的死亡率,而全球可持续的土地利用则有可能减少某些地区与热有关的死亡率。然而,由于温度与死亡率之间的非线性关系,对死亡率的总体(寒冷和炎热)影响因地而异,并在很大程度上取决于基本的气候变化情景。
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Impacts of land-use and land-cover changes on temperature-related mortality.

Background: Land-use and land-cover change (LULCC) can substantially affect climate through biogeochemical and biogeophysical effects. Here, we examine the future temperature-mortality impact for two contrasting LULCC scenarios in a background climate of low greenhouse gas concentrations. The first LULCC scenario implies a globally sustainable land use and socioeconomic development (sustainability). In the second LULCC scenario, sustainability is implemented only in the Organisation for Economic Cooperation and Development countries (inequality).

Methods: Using the Multi-Country Multi-City (MCC) dataset on mortality from 823 locations in 52 countries and territories, we estimated the temperature-mortality exposure-response functions (ERFs). The LULCC and noLULCC scenarios were implemented in three fully coupled Earth system models (ESMs): Community Earth System Model, Max Planck Institute Earth System Model, and European Consortium Earth System Model. Next, using temperature from the ESMs' simulations and the estimated location-specific ERFs, we assessed the temperature-related impact on mortality for the LULCC and noLULCC scenarios around the mid and end century.

Results: Under sustainability, the multimodel mean changes in excess mortality range from -1.1 to +0.6 percentage points by 2050-2059 across all locations and from -1.4 to +0.5 percentage points by 2090-2099. Under inequality, these vary from -0.7 to +0.9 percentage points by 2050-2059 and from -1.3 to +2 percentage points by 2090-2099.

Conclusions: While an unequal socioeconomic development and unsustainable land use could increase the burden of heat-related mortality in most regions, globally sustainable land use has the potential to reduce it in some locations. However, the total (cold and heat) impact on mortality is very location specific and strongly depends on the underlying climate change scenario due to nonlinearity in the temperature-mortality relationship.

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来源期刊
Environmental Epidemiology
Environmental Epidemiology Medicine-Public Health, Environmental and Occupational Health
CiteScore
5.70
自引率
2.80%
发文量
71
审稿时长
25 weeks
期刊最新文献
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