Characterizing multi-pollutant emission impacts of sulfur reduction strategies from coal power plants

• Published in: Environmental research letters Vol. 19; no. 8; pp. 84009 - 84021
• Main Authors: Wu, Xinran, Holloway, Tracey, Meier, Paul, Edwards, Morgan
• Format: Journal Article
• Language: English
• Published: Bristol IOP Publishing 01.08.2024
• Subjects: Air pollution; Air pollution control; Air pollution effects; Air quality; Carbon; Carbon dioxide; Climate change; Climate change mitigation; Climate policy; Coal; Coal-fired power plants; Combustion; Cost benefit analysis; Costs; Electrical loads; Electricity; Electricity generation; Emission analysis; emission reduction; Emissions; Emissions control; Energy costs; Environmental policy; Flue gas; Fuel combustion; fuel switching; Industrial plant emissions; multi-pollutant; Natural gas; net benefits; Nitrogen oxides; Organic compounds; Outdoor air quality; Particulate emissions; Particulate matter; Pollutants; Pollution control; Power plants; Renewable energy sources; Sulfur; Sulfur dioxide; Switching; VOCs; Volatile organic compounds
• ISSN: 1748-9326; 1748-9326
• DOI: 10.1088/1748-9326/ad5ab6

Abstract Fuel combustion for electricity generation emits a mix of health- and climate-relevant air emissions, with the potential for technology or fuel switching to impact multiple emissions together. While there has been extensive research on the co-benefits of climate policies on air quality improvements, few studies have quantified the effect of air pollution controls on carbon emissions. Here we evaluate three multi-pollutant emission reduction strategies, focused on sulfur dioxide (SO 2 ) controls in the electricity sector. Traditional ‘add-on’ pollution controls like flue gas desulfurization (FGD) reduce SO 2 emissions from coal combustion but increase emissions of nitrogen oxides (NO X ), volatile organic compounds (VOCs), fine particulate matter (PM 2.5 ), and carbon dioxide (CO 2 ) due to heat efficiency loss. Fuel switching from coal to natural gas and renewables potentially reduces all pollutants. We identified 135 electricity generation units (EGUs) without SO 2 controls in the contiguous US in 2017 and quantified the unit-level emission changes using pollution control efficiencies, emission rates, fuel heat input, and electricity load. A cost-benefit analysis is conducted, considering pollution control costs, fuel costs, capital and operation and maintenance (O&M) costs, the monetized health benefits from avoided multi-pollutant, and the social cost of carbon as the benefit for carbon reduction. We find that add-on SO 2 controls result in an average annual net benefit of $179.3 million (95% CI: $137.5-$221.0 million) per EGU, fuel switching from coal to natural gas, $432.7 million (95% CI: $366.4-$498.9 million) per EGU; and fuel switching from coal to renewable energy sources, $537.9 million (95% CI: $457.1-$618.9 million) per EGU. Our results highlight multi-pollutant emission reduction strategy as a cost-effective way to synergistically control air pollution and mitigate climate change.