Changes in Global Land Use and CO2 Emissions from US Bioethanol Production: What Drives Differences in Estimates between Corn and Cellulosic Ethanol?

IF 2.3 4区经济学 0 ECONOMICS

Climate Change Economics Pub Date : 2022-05-05 DOI:10.1142/s2010007822500087

B. Mignone, Jonathan E Huster, S. Torkamani, Patrick O’Rourke, M. Wise

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引用次数: 2

Abstract

Land use change (LUC) CO2 emissions associated with bioenergy production depend on the amount of land required to produce bioenergy crops, the carbon stored in such crops (including in the leaves, stalk, roots and soil), and the carbon emitted when another land cover is directly or indirectly displaced as a result. In this study, we use a global integrated assessment model [the Global Change Analysis Model (GCAM)] to explore the differences in estimates of LUC CO2 emissions for two crops (corn and switchgrass) used to produce ethanol in the United States under alternative assumptions about natural lands protection. Varying the latter assumptions for corn ethanol results in net LUC CO2 emissions between 7 and 41 gCO2 per MJ of ethanol, whereas varying the same assumptions for switchgrass ethanol results in net emissions between [Formula: see text]26 and 14 gCO2 per MJ of ethanol. The low-end estimate for each occurs when natural lands are assumed to be fully protected everywhere, which leads to significant cropland intensification. The high-end estimate for each occurs when natural lands are assumed to be unprotected everywhere, leading to greater cropland expansion and associated conversion of unmanaged forest and pasture. Results from this study could be used to inform scenarios of future energy system change or life cycle assessment of biofuels for which LUC emissions would be an input.

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美国生物乙醇生产中全球土地利用和二氧化碳排放的变化:是什么导致玉米和纤维素乙醇估算的差异?

与生物能源生产相关的土地利用变化(LUC)二氧化碳排放取决于生产生物能源作物所需的土地数量、这些作物(包括叶片、茎、根和土壤)中储存的碳，以及当另一种土地覆盖被直接或间接取代时排放的碳。在这项研究中，我们使用一个全球综合评估模型[全球变化分析模型(GCAM)]来探索在美国用于生产乙醇的两种作物(玉米和柳枝稷)在不同的自然土地保护假设下的LUC CO2排放量估算差异。改变玉米乙醇的后一种假设会导致每兆焦耳乙醇的LUC CO2净排放量在7至41克之间，而改变柳枝稷乙醇的相同假设会导致每兆焦耳乙醇的净排放量在26至14克之间。在假设自然土地在各地得到充分保护的情况下，两者的低端估计值都出现了，这导致了显著的耕地集约化。在假设自然土地在各地都未受保护的情况下，每种估算的最高值都出现了，这导致了更大的耕地扩张和与之相关的未受管理的森林和牧场的转换。这项研究的结果可以用来为未来能源系统变化的情景提供信息，或者为生物燃料的生命周期评估提供信息，而生物燃料的土地利用碳排放将作为输入。

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

Climate Change Economics Multiple-

CiteScore

5.10

自引率

17.40%

发文量

期刊介绍： Climate Change Economics (CCE) publishes theoretical and empirical papers devoted to analyses of mitigation, adaptation, impacts, and other issues related to the policy and management of greenhouse gases. CCE is specifically devoted to papers in economics although it is understood that authors may need to rely on other fields for important insights. The journal is interested in papers examining the issue at every scale from local to global and papers from around the world are encouraged. CCE is also interested in both original research and review papers and welcomes comments discussing previous articles.