Nexus(标准)
光伏系统
可再生能源
农业
食品加工
农业工程
弹性(材料科学)
生产(经济)
农业生产力
环境科学
生态系统
业务
自然资源经济学
环境资源管理
环境经济学
生态学
工程类
经济
生物
宏观经济学
嵌入式系统
物理
热力学
食品科学
作者
G. Barron-Gafford,Mitchell Pavao‐Zuckerman,R. L. Minor,L. Sutter,Isaiah Barnett-Moreno,Daniel Blackett,Moses Thompson,Kirk Dimond,Andrea K. Gerlak,Gary Paul Nabhan,Jordan Macknick
标识
DOI:10.1038/s41893-019-0364-5
摘要
The vulnerabilities of our food, energy and water systems to projected climatic change make building resilience in renewable energy and food production a fundamental challenge. We investigate a novel approach to solve this problem by creating a hybrid of colocated agriculture and solar photovoltaic (PV) infrastructure. We take an integrative approach—monitoring microclimatic conditions, PV panel temperature, soil moisture and irrigation water use, plant ecophysiological function and plant biomass production within this ‘agrivoltaics’ ecosystem and in traditional PV installations and agricultural settings to quantify trade-offs. We find that shading by the PV panels provides multiple additive and synergistic benefits, including reduced plant drought stress, greater food production and reduced PV panel heat stress. The results presented here provide a foundation and motivation for future explorations towards the resilience of food and energy systems under the future projected increased environmental stress involving heat and drought. Agrivoltaics can achieve synergistic benefits by growing agricultural plants under raised solar panels. In this article, the authors showed that growth under solar panels reduced tomato and pepper drought stress and increased production, while simultaneously reducing photovoltaic panel heat stress.
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