可再生电力的全球技术、经济和可行性潜力

IF 15.5 1区 环境科学与生态学 Q1 ENVIRONMENTAL SCIENCES
Nils Angliviel de La Beaumelle, Kornelis Blok, Jacques A. de Chalendar, Leon Clarke, Andrea N. Hahmann, Jonathan Huster, Gregory F. Nemet, Dhruv Suri, Thomas B. Wild, Inês M.L. Azevedo
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引用次数: 0

摘要

可再生能源发电需要迅速扩大规模,以应对气候变化和其他环境挑战。要有效地做到这一点,就需要了解资源的可用性。我们回顾了对全球技术潜力的可再生电力的估计,其定义为在考虑地理和技术限制以及转换效率的情况下,使用当前技术可以生产的电量;经济潜力,也包括成本;可行的潜力,这说明了社会和环境的限制。我们考虑了公用事业规模和屋顶太阳能光伏发电、聚光太阳能发电、陆上和海上风能、水力发电、地热能发电和海洋(波浪、潮汐、海洋热能转换和盐度梯度能源)技术。我们发现,所报道的每种能源的技术潜力在不同的技术和技术范围内都有好几个数量级的差异。因此,我们还讨论了解释作者得出如此不同结果的主要因素。根据这篇综述和最可靠的研究,我们发现,公用事业规模的太阳能光伏发电、聚光太阳能发电、陆上风能和海上风能的技术潜力都在100千瓦时/年以上。水电、地热能、海洋热能转换技术潜力均在10pwh /年以上。屋顶太阳能光伏、波浪和潮汐能的技术潜力在1千瓦时/年以上。盐度梯度的技术潜力高于0.1 PWh/年。评估可再生能源全球经济潜力的文献(考虑了每种可再生资源的成本)表明,经济潜力高于当前和近期的电力需求。很少有研究计算了考虑社会和环境制约因素的全球可行潜力。虽然这些范围对评估可用能源的规模是有用的,但它们可能忽略了大规模可再生能源组合的挑战。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
The Global Technical, Economic, and Feasible Potential of Renewable Electricity
Renewable electricity generation will need to be rapidly scaled to address climate change and other environmental challenges. Doing so effectively will require an understanding of resource availability. We review estimates for renewable electricity of the global technical potential, defined as the amount of electricity that could be produced with current technologies when accounting for geographical and technical limitations as well as conversion efficiencies; economic potential, which also includes cost; and feasible potential, which accounts for societal and environmental constraints. We consider utility-scale and rooftop solar photovoltaics, concentrated solar power, onshore and offshore wind, hydropower, geothermal electricity, and ocean (wave, tidal, ocean thermal energy conversion, and salinity gradient energy) technologies. We find that the reported technical potential for each energy resource ranges over several orders of magnitude across and often within technologies. Therefore, we also discuss the main factors explaining why authors find such different results. According to this review and on the basis of the most robust studies, we find that technical potentials for utility-scale solar photovoltaic, concentrated solar power, onshore wind, and offshore wind are above 100 PWh/year. Hydropower, geothermal electricity, and ocean thermal energy conversion have technical potentials above 10 PWh/year. Rooftop solar photovoltaic, wave, and tidal have technical potentials above 1 PWh/year. Salinity gradient has a technical potential above 0.1 PWh/year. The literature assessing the global economic potential of renewables, which considers the cost of each renewable resource, shows that the economic potential is higher than current and near-future electricity demand. Fewer studies have calculated the global feasible potential, which considers societal and environmental constraints. While these ranges are useful for assessing the magnitude of available energy sources, they may omit challenges for large-scale renewable portfolios.
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来源期刊
Annual Review of Environment and Resources
Annual Review of Environment and Resources 环境科学-环境科学
CiteScore
24.10
自引率
1.80%
发文量
33
审稿时长
>24 weeks
期刊介绍: The Annual Review of Environment and Resources, established in 1976, offers authoritative reviews on key environmental science and engineering topics. It covers various subjects, including ecology, conservation science, water and energy resources, atmosphere, oceans, climate change, agriculture, living resources, and the human dimensions of resource use and global change. The journal's recent transition from gated to open access through Annual Reviews' Subscribe to Open program, with all articles published under a CC BY license, enhances the dissemination of knowledge in the field.
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