Life cycle assessment of lignite-fueled ultra-supercritical coal-fired power plant with evaluation of solar energy integration

•Ultra-supercritical pulverized coal technology handles high moisture, low calorific coal.•Gate-to-gate LCA evaluates the environmental impacts of a lignite-fueled power plant.•Operational stage contributes most to the overall life cycle impacts of the plant.•Lignite coal has the highest climate cha...

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Bibliographic Details
Published in:Fuel (Guildford) 2025-04, Vol.385, Article 134079
Main Authors: Yousuf, Muhammad Uzair, Siddiqui, Mubashir Ali, Kumar, Munesh, Umair, Muhammad
Format: Article
Language:English
Subjects:
Climate change potential
Emissions
Lignite
Pakistan
Solar
Ultra-supercritical
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Summary:•Ultra-supercritical pulverized coal technology handles high moisture, low calorific coal.•Gate-to-gate LCA evaluates the environmental impacts of a lignite-fueled power plant.•Operational stage contributes most to the overall life cycle impacts of the plant.•Lignite coal has the highest climate change impact.•Solar energy integration increases USC plant efficiency by 0.71% to 0.97%. Coal-fired power plants significantly contribute to global greenhouse gas emissions and air pollution. This study performs a comprehensive Life Cycle Assessment (LCA) of an ultra-supercritical coal-fired power plant (USC CFPP) in Pakistan, focusing on the environmental impacts of using local Thar lignite and imported Indonesian lignite. Key impact categories analyzed include Climate Change Potential, Human Toxicity Potential, Particulate Matter Formation, and Terrestrial Acidification. Results indicate that the Climate Change Potential of local coal is nearly double that of imported coal due to its higher sulfur content and lower heating value. Conversely, the transportation of imported coal contributes significantly to Human Toxicity Potential from particulate matter release. Blending local and imported coal demonstrates substantial environmental benefits, reducing Climate Change Potential by 18.43%, Terrestrial Acidification by 61.51%, Photochemical Oxidant Formation by 36.86%, Human Toxicity Potential by 36.86%, and Particulate Matter Formation by 56.51%. Additionally, integrating solar energy with the USC CFPP enhances plant efficiency by 0.71% to 0.97%, offering a hybrid approach to lower emissions and improve resource efficiency. The Life Cycle Savings (LCS) analysis shows that high inflation rates, discount rates, and capital costs can reduce LCS. Sensitivity analysis further reveals that high capital costs and discount rates can extend the payback period. These findings emphasise the potential of solar-integrated USC CFPPs for reducing environmental impacts and improving economic efficiency, representing a sustainable approach to coal-based power generation.
ISSN:0016-2361
DOI:10.1016/j.fuel.2024.134079