Methane Oxidation via Chemical and Biological Methods: Challenges and Solutions

Samanta, Dipayan; Sani, Rajesh K.

doi:10.3390/methane2030019

Cited by 6 publications

(2 citation statements)

References 151 publications

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“…Another method is the constant percolation of water over fields [98]. This measure results in methane oxidation in water, which keeps methane emissions low [91,[99][100][101]. Methane emissions can also be reduced by reducing the content of carbon-based compounds in the soil [2,102].…”

Section: Mitigation Measures Of Methanementioning

confidence: 99%

Methanotrophy: A Biological Method to Mitigate Global Methane Emission

Rani,

Pundir,

Verma

et al. 2024

Microbiology Research

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Methanotrophy is a biological process that effectively reduces global methane emissions by utilizing microorganisms that can utilize methane as a source of energy under both oxic and anoxic conditions, using a variety of different electron acceptors. Methanotrophic microbes, which utilize methane as their primary source of carbon and energy, are microorganisms found in various environments, such as soil, sediments, freshwater, and marine ecosystems. These microbes play a significant role in the global carbon cycle by consuming methane, a potent greenhouse gas, and converting it into carbon dioxide, which is less harmful. However, methane is known to be the primary contributor to ozone formation and is considered a major greenhouse gas. Methane alone contributes to 30% of global warming; its emissions increased by over 32% over the last three decades and thus affect humans, animals, and vegetation adversely. There are different sources of methane emissions, like agricultural activities, wastewater management, landfills, coal mining, wetlands, and certain industrial processes. In view of the adverse effects of methane, urgent measures are required to reduce emissions. Methanotrophs have attracted attention as multifunctional bacteria with potential applications in biological methane mitigation and environmental bioremediation. Methanotrophs utilize methane as a carbon and energy source and play significant roles in biogeochemical cycles by oxidizing methane, which is coupled to the reduction of various electron acceptors. Methanotrophy, a natural process that converts methane into carbon dioxide, presents a promising solution to mitigate global methane emissions and reduce their impact on climate change. Nonetheless, additional research is necessary to enhance and expand these approaches for extensive use. In this review, we summarize the key sources of methane, mitigation strategies, microbial aspects, and the application of methanotrophs in global methane sinks with increasing anthropogenic methane emissions.

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Section: Mitigation Measures Of Methanementioning

confidence: 99%

Methanotrophy: A Biological Method to Mitigate Global Methane Emission

Rani,

Pundir,

Verma

et al. 2024

Microbiology Research

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“…The temporary temperature effect of removing one year's worth of human-caused methane emissions would be roughly four times greater than that of removing the equivalent amount of carbon dioxide emissions. The main technological pathways for removing methane are the application of catalytic chemical oxidation (thermal, photochemical, electrochemical), the enhancement of atmospheric sinks, and the conversion of methane using microbes [6,8,9]. Herein, we focus on methane conversion by means of thermal, photochemical and electrochemical catalysis.…”

Section: Introductionmentioning

confidence: 99%

Exploring the bounds of methane catalysis in the context of atmospheric methane removal

Tsopelakou,

Stallard,

Archibald

et al. 2024

Environ. Res. Lett.

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Methane, a potent greenhouse gas, is a significant contributor to global warming, with future increases in its abundance potentially leading to an increase of more than 1◦C by 2050 beyond other greenhouse gases if left unaddressed. To remain within the crucial target of limiting global warming to 1.5◦C, it is imperative to evaluate the potential of methane removal techniques. This study presents a scoping analysis of different catalytic technologies (thermal, photochemical and electrochemical) and materials to evaluate potential limitations and energy requirements. An analysis of mass transport and reaction rates is conducted for atmospheric methane conversion system configurations. For the vast majority of catalytic technologies, the reaction rates limit the conversion which motivates future efforts for catalyst development. An analysis of energy requirements for atmospheric methane conversion shows minimum energy configurations for various catalytic technologies within classic tube or parallel plate architectures that have analogs to ventilation and industrial fins. Methane concentrations ranging from 2 ppm (ambient) to 1000 ppm (sources, such as wetlands, fossil-fuel extraction sites, landfills etc.) are examined. The study finds that electrocatalysis offers the most energy efficient approach (∼0.2 GJ/tonne CO2e) for new installations in turbulent ducts, with a total energy intensity <1 GJ/tonne CO2e. Photocatalytic methane removal catalysts are moderately more energy intensive (∼2 GJ/tonne CO2e), but could derive much of their energy input from “free” solar energy sources. Thermal systems are shown to be excessively energy intensive (>100 GJ/tonne), while combining photovoltaics with electrochemical catalysts (∼1 GJ/tonne CO2e) have comparable energy intensity to photocatalytic methane removal catalysts.

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Recent findings in methanotrophs: genetics, molecular ecology, and biopotential

Ahmadi,

Lackner

2024

Appl Microbiol Biotechnol

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Methane Oxidation via Chemical and Biological Methods: Challenges and Solutions

Cited by 6 publications

References 151 publications

Methanotrophy: A Biological Method to Mitigate Global Methane Emission

Methanotrophy: A Biological Method to Mitigate Global Methane Emission

Exploring the bounds of methane catalysis in the context of atmospheric methane removal

Recent findings in methanotrophs: genetics, molecular ecology, and biopotential

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