Improved estimation methods for surface coal mine methane emissions for reporting, beneficial use, and emission reduction purposes and relative to Australia's safeguard mechanisms

Methane is responsible for 30% of global warming, with coal mining contributing 31% of 2023 methane emissions in the energy sector. Australia's Bowen Basin is the largest metallurgical coal (MC) producing region with a need to reduce fugitive coal mine methane (CMM) emissions, most notably from...

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Bibliographic Details
Published in:Journal of environmental management 2025-03, Vol.376, p.124366, Article 124366
Main Authors: Alarcon Vigil, Daniel, Johnson Jr, Raymond L., Tauchnitz, James
Format: Article
Language:English
Subjects:
CMM
Coal mine methane
Coal mining
Emissions reductions
Mine pre-drainage
Safeguard mechanisms
Subterranean barriers
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Summary:Methane is responsible for 30% of global warming, with coal mining contributing 31% of 2023 methane emissions in the energy sector. Australia's Bowen Basin is the largest metallurgical coal (MC) producing region with a need to reduce fugitive coal mine methane (CMM) emissions, most notably from surface coal mining operations, as underground mines have increased pre-drainage with flaring or beneficial use. Australia's regulatory framework is moving to mine-specific models, based on measured data and reservoir modelling, to evaluate CMM emissions more effectively and quantify the benefit of projects that reduce emissions. This paper highlights the definitions, classifications, and determinations in the Australian Safeguard Mechanisms to define surface mining and underground CMM emissions. While underground mining has a broad range of potential mitigation strategies, open-cut MC mine mitigation strategies are more limited and will be the focus of this paper. Australian-specific open-cut MC mine examples will illustrate the potential reductions in emissions and positive cash-flow benefits possible by implementing pre-drainage and new technologies (e.g., subterranean barriers). Six CMM scenarios, based on representative data from Australia's Bowen Basin coal mines and typical beneficial use strategies, show that a typical pre-drainage strategy at a surface mine can reduce CMM emissions by 38% without any further beneficial use of produced gas. Further, implementing a pre-drainage strategy with subterranean barriers can reduce emissions by 46%, a 10% improvement over pre-drainage alone. The emissions estimation methodology proposed can be applied to other carbon pricing frameworks and regions to define the impacts and benefits of implementing emissions reduction strategies. [Display omitted] •Methodologies are presented to more effectively estimate coal mine methane emissions from open-cut metallurgical coal mines.•Bowen Basin cases illustrate the inadequacy of various methods of reporting emissions under Australia’s Safeguard Mechanisms.•Implementing open-cut mine pre-drainage with new technologies (e.g., barriers) can reduce mine methane emissions by up to 46%.•TCash flow improvements can result from surface mine operations that employ emissions reductions and beneficial use strategies.•The methodologies presented are easily adaptable to other mining areas, carbon pricing environments and regulatory frameworks.
ISSN:0301-4797
1095-8630
1095-8630
DOI:10.1016/j.jenvman.2025.124366