Bottom-up estimates of deep decarbonization of U.S. manufacturing in 2050

Ernst Worrell, Gale Boyd

Research output: Contribution to journalArticleAcademicpeer-review

Abstract

The world needs to rapidly reduce emissions of carbon dioxide (CO2) emission to stave off the risks of disastrous climate change. In particular, decarbonizing U.S. manufacturing industries is particularly challenging due to the specific process requirements. This study estimates the potential for future CO2 emission reductions in this important sector. The analysis is a detailed accounting exercise that relies on estimates of emission-reduction potential from other studies and applies those potentials to the manufacturing sector using a bottom-up approach. The actions are grouped into four “pillars” that support deep decarbonization of manufacturing (DDM): Energy Efficiency, Material Efficiency, Industry-Specific, and Power Grid. Based on this bottom-up approach, the analysis shows that an 86% reduction in carbon dioxide emissions from the Reference Case is feasible. No single pillar dominates DDM, although opportunities vary widely by sub-sector. The analysis shows that a strategy incorporating a broad set of elements from each pillar can be effective instead of relying on any single pillar. Some pillars, such as Energy Efficiency and Material Efficiency, have wide applicability; others have key niche roles that are Industry-Specific; the Power Grid pillar requires interaction between grid decarbonization and industry action to switch from fossil fuels to zero-carbon electricity where appropriate.
Original languageEnglish
Article number129758
Pages (from-to)1-15
Number of pages15
JournalJournal of Cleaner Production
Volume330
DOIs
Publication statusPublished - 1 Jan 2022

Keywords

  • Climate change mitigation
  • Decarbonization
  • Electrification
  • Energy efficiency
  • Material efficiency
  • Renewables

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