Assessing the potential benefits of methane oxidation technologies using a concentration-based framework

Abstract: Lowering the atmospheric methane concentration is critical to reducing short-term global warming because of methane’s high radiative forcing and relatively short lifetime. Methane could be destroyed at its emissions sources or removed from the atmosphere by oxidizing it to carbon dioxide and water vapor, greatly lowering the warming effect. Here we provide, to the best of our knowledge, the first estimate of the amount of methane that is emitted at a given concentration. We use this to assess the potential ben… Show more

“…Abernathy et al [17] found that light-based reactors must have a quantum yield for methane removal of at least 9 ± 8%, in order for the economic benefit of removing methane to exceed the energy cost. Given the demonstrated performance of MEPS with an AQY of 0.83% and anticipated improvements, the possibility that MEPS will meet the target set by Abernathy et al cannot be excluded.…”

“…A recent paper by Abernethy et al [17] has assessed methane oxidation technologies using a concentration based framework. This paper estimates, for the first time, the amount of methane emitted at a given concentration, showing that around 3/4 of methane emissions occur at a concentration below 1000 ppm.…”

A high efficiency gas phase photoreactor for eradication of methane from low-concentration sources

“…Abernathy et al [17] found that light-based reactors must have a quantum yield for methane removal of at least 9 ± 8%, in order for the economic benefit of removing methane to exceed the energy cost. Given the demonstrated performance of MEPS with an AQY of 0.83% and anticipated improvements, the possibility that MEPS will meet the target set by Abernathy et al cannot be excluded.…”

“…A recent paper by Abernethy et al [17] has assessed methane oxidation technologies using a concentration based framework. This paper estimates, for the first time, the amount of methane emitted at a given concentration, showing that around 3/4 of methane emissions occur at a concentration below 1000 ppm.…”

A high efficiency gas phase photoreactor for eradication of methane from low-concentration sources

“…the chemical or biological conversion to carbon dioxide and water). Because methane is 43 times more potent than carbon dioxide per molecule, this conversion substantially reduces warming [15]. Roughly 95% of the methane sink is due to highly reactive atmospheric radicals (mainly hydroxyl, with a minor contribution from chlorine), while ∼5% is due to soil methanotrophs (methaneconsuming microbes) [5].…”

“…To be cost-effective at atmospheric concentrations, however, substantial breakthroughs are needed. For heat-based reactors, the operating temperature likely must be reduced from the current low of 300 • C down to below 30 • C [15]. For light-based reactors, including those that use photocatalysts and photolysis-based radical generation, the quantum efficiency (the ratio of oxidized methane molecules to incident photons) will need to be increased-from the current high of 0.8% potentially to at least 9% [15,19].…”

“…For heat-based reactors, the operating temperature likely must be reduced from the current low of 300 • C down to below 30 • C [15]. For light-based reactors, including those that use photocatalysts and photolysis-based radical generation, the quantum efficiency (the ratio of oxidized methane molecules to incident photons) will need to be increased-from the current high of 0.8% potentially to at least 9% [15,19]. For bioreactors, substantial technological breakthroughs are required to lower the lowest concentration at which they can operate from ∼500 ppm down to 1.9 ppm [20].…”

Atmospheric methane removal may reduce climate risks

Utilisation of low methane concentrations by methanotrophs