Energy transition under mineral constraints and recycling: A low-carbon supply peak

IF 4.6 Q2 MATERIALS SCIENCE, BIOMATERIALS

ACS Applied Bio Materials Pub Date : 2023-04-01 DOI:10.1016/j.reseneeco.2023.101356

Simon Chazel , Sophie Bernard , Hassan Benchekroun

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引用次数: 1

Abstract

What are the implications of primary mineral constraints for the energy transition? Low-carbon energy production uses green capital, which requires primary minerals. We build on the seminal framework for the transition from a dirty to a clean energy in Golosov et al. (2014) to incorporate the role played by primary minerals and their potential recycling. We characterize the optimal paths of the energy transition under various mineral constraint scenarios. Mineral constraints limit the development of green energy in the long run: Low-carbon energy production eventually reaches a plateau. We run our simulations using copper as the limiting mineral and we allow for its full recycling. Even in the limiting case of a 100% recycling rate, after five to six decades green energy production is 50% lower than in the scenario with unlimited primary copper, and after 30 decades, GDP is 3–8% lower. In extension scenarios, we confirm that a longer life duration of green capital delays copper extraction and the green energy peak, whereas reduced recycling caps moves the peak in green energy production forward.

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矿产约束与循环利用下的能源转型:低碳供应峰值

初级矿物限制对能源转型的影响是什么？低碳能源生产使用绿色资本，而绿色资本需要初级矿产。我们建立在Golosov等人（2014）关于从肮脏能源向清洁能源过渡的开创性框架的基础上，以纳入初级矿物所发挥的作用及其潜在的回收利用。我们刻画了在各种矿物约束情景下能量转换的最优路径。从长远来看，矿产限制限制了绿色能源的发展：低碳能源生产最终达到平稳期。我们使用铜作为限制性矿物进行模拟，并允许其完全回收。即使在100%回收率的有限情况下，在五到六十年后，绿色能源产量也比一次铜不受限制的情况下低50%，30年后，GDP也低3-8%。在扩展场景中，我们证实，绿色资本的寿命延长会延迟铜提取和绿色能源峰值，而回收上限的降低会推动绿色能源生产的峰值。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

ACS Applied Bio Materials Chemistry-Chemistry (all)

CiteScore

9.40

自引率

2.10%

发文量

464