固定成本驱动发电的Hotelling模型

Pollution eJournal Pub Date : 2012-12-05 DOI:10.2139/ssrn.2185378

A. Renz, C. Weber

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引用次数: 1

摘要

本文将霍特林的理论与经典的容量规划框架联系起来，将其应用于排放受限的环境中，以描述电力生产中的投资组合时间路径。排放目标是通过污染存量的上限来考虑的。作为现有技术的一个子集，我们提出了高效生产组合的条件。然后，我们得出可再生能源、化石能源和碳捕获技术的潜在生产组合时间路径，这些路径根据其固定成本和可变成本、效率和污染特征而有所不同。我们认为，化石能源的比重将持续下降，稀缺资源将被充分利用。在每条受约束的路径上，污染存量将在不为零欧元的时间段内保持在上限。排放目标降低了稀缺性租金，碳捕获的选择将降低社会成本并维持稀缺性租金。

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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A Hotelling Model for Fixed-Cost Driven Power Generation

This paper links Hotelling's theory, in recent literature applied to an emission constrained environment, with the classical capacity planning framework to describe portfolio timeâ€ paths in electricity production. Emission targets are considered by a ceiling on the stock of pollution. We propose conditions for an efficient production portfolio as a subset of available technologies. We then derive potential production portfolio timeâ€ paths for a renewable, a fossil and a carbon capturing technology that differ according to their fixed and variable costs, their efficiency and their polluting characteristics. We conclude that the share of the fossil technology will continuously decrease, the scarce resource will be fully exploited. On each constrained path, the stock of pollution will remain at the ceiling for a nonâ€ zero time period. Emission targets push down scarcity rents, an option for carbon capturing would decrease societal costs and uphold scarcity rents.

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Pollution eJournal

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