8 research outputs found

    Impacts of Alternative Emissions Allowance Allocation Methods under a Federal Cap-and-Trade Program

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    This paper examines the implications of alternative allowance allocation designs under a federal cap-and-trade program to reduce emissions of greenhouse gases. We focus on the impacts on industry profits and overall economic output, employing a dynamic general equilibrium model of the U.S. economy. The model's unique treatment of capital dynamics permits close attention to profit impacts. We find that the effects on profits depend critically on the method of allowance allocation. Freely allocating fewer than 15 percent of the emissions allowances generally suffices to prevent profit losses among the eight industries that, without free allowances or other compensation, would suffer the largest percentage losses of profit. Freely allocating 100 percent of the allowances substantially overcompensates these industries, in many cases causing more than a doubling of profits. These results indicate that profit preservation is consistent with substantial use of auctioning and the generation of considerable auction revenue. GDP costs of cap and trade depend critically on how such revenues are used. When these revenues are employed to finance cuts in marginal income tax rates, the resulting GDP costs are about 33 percent lower than when all allowances are freely allocated and no auction revenue is generated. On the other hand, when auction proceeds are returned to the economy in lump-sum fashion (for example, as rebate checks to households), the potential cost-advantages of auctioning are not realized. Our results are robust to cap-and-trade policies that differ according to policy stringency, the availability of offsets, and the extent of opportunities for intertemporal trading of allowances.

    Policy Insights From the EMF 32 Study on U.S. Carbon Tax Scenarios

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    The Stanford Energy Modeling Forum exercise 32 (EMF 32) used 11 different models to assess emissions, energy, and economic outcomes from a plausible range of economy-wide carbon price policies to reduce carbon dioxide (CO2) emissions in the United States. Here we discuss the most policy-relevant results of the study, mindful of the strengths and weaknesses of current models. Across all models, carbon prices lead to significant reduc- tions in CO2 emissions and conventional pollutants, with the vast majority of the reductions occurring in the electricity sector. Importantly, emissions reductions do not significantly depend on the rebate or tax cut used to return revenues to the economy. Expected economic costs, as modeled by either GDP or welfare, are modest, but vary across models. These costs are offset by benefits from avoided climate damages and health benefits from reductions in conventional air pollution. Using revenues to reduce preexisting capital or labor taxes reduces costs in most models relative to lump-sum rebates, but the size of the cost reductions varies significantly. Devoting at least some revenue to household rebates can significantly reduce adverse impacts on low income households. Carbon prices at $25/ton or even lower levels cause significant shifts away from coal as an energy source with responses of other energy sources highly dependent upon technology cost assumptions. Beyond 2030, we conclude that model uncertainties are too large to make quantitative results useful for near-term policy design. We close by describing recommendations for policymakers on interacting with model results in the future

    The Future of U.S. Carbon-Pricing Policy

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