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International researchers across the Energy Technologies Area at Lawrence Berkeley National Laboratory (Berkeley Lab) perform game-changing research on energy use and clean energy strategies through extensive analysis, model and tool development. We deploy our findings across a wide variety of sectors in emerging and developed economies, and link U.S. industry with key global opportunities.

Reducing Non-CO2 Climate Pollutants

Reducing Non-CO2 Climate Pollutants

Global Non-CO2 Emission by Gas and Sector in 2015
Source: U.S. EPA, 2019

Methane and fluorinated gasses, as well as anthropogenic black carbon, are short-lived climate pollutants (SLCP) that have relatively short atmospheric lifetimes but trap heat more efficiently than CO2 on a per-unit basis making them potent climate forcers with the potential to significantly warm the atmosphere and ocean. SLCPs have exacerbated other climate change-related impacts – including disrupting seasonal rain patterns, accelerating Arctic melting, and contributing to deadly air pollution. The Intergovernmental Panel on Climate Change has recognized that reducing SLCPs is crucial to limit global temperature rise to below 1.5°C.

Combined, black carbon from fossil-fuel combustion; methane from agriculture and fossil fuel operations; hydrofluorocarbons (HFCs) from cooling, refrigeration and other industrial uses; and tropospheric ozone formed from air pollutants are responsible for up to 45% of current global warming. In addition, the longer-lived nitrous oxide (N2O), is a potent GHG and ozone depleting substance that contributes the equivalent of about 10% of today’s CO2 warming.

Researchers at the International Energy Analysis Department have conducted research in the following areas to understand non-CO2 and SLCP mitigation potential and support mitigation actions. 

Non-CO2 Greenhouse Gas (GHG) Mitigation Scenario Analysis

 

ETA’s international analysis researchers and collaborators have established a novel bottom-up, end-use modeling framework to project future national non-CO2 GHGs emissions, including methane, N2O, and F-gasses. This modeling framework provides an understanding of the sources and drivers for future non-CO2 GHG emissions, and various technological and policy options for specifically addressing these gasses. It has been applied to China to evaluate different scenarios of non-CO2 GHG emission trajectories, based on different adoption of mitigation technologies and measures based on technological feasibility and costs of abatement. The different mitigation scenarios will present policymakers and program implementers with tools and insights to set realistic and achievable near-term and long-term goals and prioritize and initiate actions quickly to combat climate change. 

Non-CO2 Mitigation Scenario Analysis for China
Non-CO2 Mitigation Scenario Analysis for China

Source: Lin et al. 2021. “Opportunities to Tackle Short-lived Climate Pollutants and Other Greenhouse Gases for China.”  

 

Techno-economic and Cost-curve Analysis of Mitigation Options

 

Based on ongoing collaboration, ETA’s international analysis researchers have conducted deep techno-economic analysis of non-CO2 GHG mitigation measures and evaluated the cost-effectiveness of these measures in a country-specific context. The mitigation cost-curves developed based on this research and collaboration help shed light on the potential paces of mitigation by gas and by sector given technical and economic constraints.  

 

China Non-CO2 Mitigation Cost-curve  Source: Lin et al. 2021. “Opportunities to Tackle Short-lived Climate Pollutants and Other Greenhouse Gases for China.”  

China Non-CO2 Mitigation Cost-curve

Source: Lin et al. 2021. “Opportunities to Tackle Short-lived Climate Pollutants and Other Greenhouse Gases for China.”  

Policy Analysis

ETA’s international analysis researchers have analyzed and reviewed international policies, targets, and best practices for mitigating non-CO2 GHG emissions at national, subnational and sectoral levels. We are also actively engaging with global policymakers and stakeholders and conducting other outreach activities to share and publicize our research results to help facilitate the development and implementation of SLCP policies.

Publications

Lin, Jiang, Nina Khanna, Xu Liu, Wenjun Wang, Jennifer Gordan, Fan Dai. 2021. “Opportunities to Tackle Short-lived Climate Pollutants and Other Greenhouse Gases for China.”  CCCI report. https://ccci.berkeley.edu/sites/default/files/Opportunities-to-Tackle-SLCPs-for-China.pdf

Lin, Jiang, Nina Khanna, Xu Liu, Fei Teng, and Xin Wang. "China’s Non-CO2 Greenhouse Gas Emissions: Future Trajectories and Mitigation Options and Potential." Scientific Reports 9.1 (2019).

Wang, Xin, Fei Teng, Jingjing Zhang, Nina Khanna, and Jiang Lin. "Challenges to addressing non-CO2 greenhouse gases in China’s long-term climate strategy." Climate Policy 18.8 (2018) 1059 - 1065.

Interested in Finding out More?

Jiang Lin

Energy/Environmental Policy Staff Scientist/Engineer

(510) 495-8886

J_Lin@lbl.gov



Reducing Non-CO2 Climate Pollutants

 

Pie graph showing global CO2 emissions by gas and sector

Source: U.S. EPA, 2019

 

Methane and fluorinated gasses, as well as anthropogenic black carbon, are short-lived climate pollutants (SLCP) that have relatively short atmospheric lifetimes but trap heat more efficiently than CO2 on a per-unit basis making them potent climate forcers with the potential to significantly warm the atmosphere and ocean. SLCPs have exacerbated other climate change-related impacts – including disrupting seasonal rain patterns, accelerating Arctic melting, and contributing to deadly air pollution. The Intergovernmental Panel on Climate Change has recognized that reducing SLCPs is crucial to limit global temperature rise to below 1.5°C.

Combined, black carbon from fossil-fuel combustion; methane from agriculture and fossil fuel operations; hydrofluorocarbons (HFCs) from cooling, refrigeration and other industrial uses; and tropospheric ozone formed from air pollutants are responsible for up to 45% of current global warming. In addition, the longer-lived nitrous oxide (N2O), is a potent GHG and ozone depleting substance that contributes the equivalent of about 10% of today’s CO2 warming.

Researchers at the International Energy Analysis Department have conducted research in the following areas to understand non-CO2 and SLCP mitigation potential and support mitigation actions.

 

Non-CO2 Greenhouse Gas (GHG) Mitigation Scenario Analysis

ETA’s international analysis researchers and collaborators have established a novel bottom-up, end-use modeling framework to project future national non-CO2 GHGs emissions, including methane, N2O, and F-gasses. This modeling framework provides an understanding of the sources and drivers for future non-CO2 GHG emissions, and various technological and policy options for specifically addressing these gasses. It has been applied to China to evaluate different scenarios of non-CO2 GHG emission trajectories, based on different adoption of mitigation technologies and measures based on technological feasibility and costs of abatement. The different mitigation scenarios will present policymakers and program implementers with tools and insights to set realistic and achievable near-term and long-term goals and prioritize and initiate actions quickly to combat climate change. 

 

Graph
Non-CO2 Mitigation Scenario Analysis for China
Source: Lin et al. 2021. “Opportunities to Tackle Short-lived Climate Pollutants and Other Greenhouse Gases for China.”

 

Techno-economic and Cost-curve Analysis of Mitigation Options

Based on ongoing collaboration, ETA’s international analysis researchers have conducted deep techno-economic analysis of non-CO2 GHG mitigation measures and evaluated the cost-effectiveness of these measures in a country-specific context. The mitigation cost-curves developed based on this research and collaboration help shed light on the potential paces of mitigation by gas and by sector given technical and economic constraints.  

Graph
China Non-CO2 Mitigation Cost-curve
Source: Lin et al. 2021. “Opportunities to Tackle Short-lived Climate Pollutants and Other Greenhouse Gases for China.”