美国风能和太阳能发电的关键材料需求和回收机会

IF 4.9 3区 环境科学与生态学 Q2 ENGINEERING, ENVIRONMENTAL Journal of Industrial Ecology Pub Date : 2024-03-27 DOI:10.1111/jiec.13479
Tessa Lee, Yuan Yao, Thomas E. Graedel, Alessio Miatto
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引用次数: 0

摘要

可再生能源发电技术的应用预计将在美国迅速增加,其主要驱动力是对灾难性气候变化的担忧。风能和太阳能部署的快速增加将转化为关键材料需求的增加,从而引发供不应求的担忧,导致矿产价格波动,并可能减缓能源转型。本研究提出了一个详细的美国风能和太阳能需求方模型,利用动态材料流分析来计算 15 种元素的需求量:铬、锌、镓、硒、钼、银、镉、铟、锡、碲、镨、钕、铽、镝和铅。结果表明,与 "一切照旧"(BAU)相比,到 2050 年过渡到完全去碳化的美国能源系统可能需要将关键材料的使用流量增加五到七倍,其中某些材料需要的增幅更大。稀土元素 (REE) 在 2050 年进入美国电力部门所需的材料流量可能是 2021 年的 60-300 倍,占全球稀土元素供应总量的 13%-49%。到 2050 年实现净零排放所需的碲化镉可能会超过目前的供应量,这给碲化镉太阳能的广泛应用带来了挑战。我们还研究了几种减少材料需求的策略,包括闭环回收、降低材料强度和改变子技术的市场份额(例如,使用晶体硅太阳能电池板代替碲化镉太阳能电池板)。虽然这些策略可大幅减少关键材料需求,平均减少达 40%,但积极的去碳化仍需要大量关键材料。
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Critical material requirements and recycling opportunities for US wind and solar power generation

The deployment of renewable energy generation technologies, driven primarily by concerns over catastrophic climate change, is expected to increase rapidly in the United States. Rapid increases in the deployment of wind and solar energy will translate to increases in critical material requirements, causing concern that demand could outstrip supply, leading to mineral price volatility and potentially slowing the energy transition. This study presents a detailed demand-side model for wind and solar in the United States using dynamic material flow analysis to calculate the requirements for 15 elements: Cr, Zn, Ga, Se, Mo, Ag, Cd, In, Sn, Te, Pr, Nd, Tb, Dy, and Pb. Results show that transitioning to a completely decarbonized US energy system by 2050 could require a five-to-sevenfold increase in critical material flow-into-use compared with business as usual (BAU), with some materials requiring much larger increases. Rare earth elements (REEs) could require 60–300 times greater material flows into the US power sector in 2050 than in 2021, representing 13%–49% of the total global REE supply. Te requirements for reaching net zero by 2050 could exceed current supply, posing challenges for widespread deployment of cadmium-telluride solar. We also investigate several strategies for reducing material requirements, including closed-loop recycling, material intensity reduction, and changing market share of subtechnologies (e.g., using crystalline silicon solar panels instead of cadmium telluride). Although these strategies can significantly reduce critical material requirements by up to 40% on average, aggressive decarbonization will still require a substantial amount of critical material.

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来源期刊
Journal of Industrial Ecology
Journal of Industrial Ecology 环境科学-环境科学
CiteScore
11.60
自引率
8.50%
发文量
117
审稿时长
12-24 weeks
期刊介绍: The Journal of Industrial Ecology addresses a series of related topics: material and energy flows studies (''industrial metabolism'') technological change dematerialization and decarbonization life cycle planning, design and assessment design for the environment extended producer responsibility (''product stewardship'') eco-industrial parks (''industrial symbiosis'') product-oriented environmental policy eco-efficiency Journal of Industrial Ecology is open to and encourages submissions that are interdisciplinary in approach. In addition to more formal academic papers, the journal seeks to provide a forum for continuing exchange of information and opinions through contributions from scholars, environmental managers, policymakers, advocates and others involved in environmental science, management and policy.
期刊最新文献
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