Environmental Impact Modeling for a Small-Scale Field Test of Methane Removal by Iron Salt Aerosols

Sturtz, Timothy M.; Jenkins, Peter T.; Richter, Renaud de

doi:10.3390/su142114060

Cited by 5 publications

(1 citation statement)

References 39 publications

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“…They observed a substantial reduction in CH 4 levels, with removal rates ranging from 46% (at 1.2 kg H 2 SO 4 ) to 96% (at 6.0 kg H 2 SO 4 ) and concluded that employing low-dose acidification proves to be a promising and viable strategy for mitigating CH 4 emissions [100]. Highly interesting ironsalt aerosol method, which is a mimic of natural reactions related to mineral dust particles, is capable of direct atmospheric CH 4 removal [101,102]. This method generates CH 4 depleting chlorine atoms in the tropospheric atmosphere, thereby capable of removing the total atmospheric CH 4 to some extent [103].…”

Section: Traditional Methods For Direct Atmospheric Methane Removalmentioning

confidence: 99%

Methane Oxidation via Chemical and Biological Methods: Challenges and Solutions

Samanta

Sani

2023

Methane

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Methane, a potent greenhouse gas, has gained significant attention due to its environmental impact and economic potential. Chemical industries have focused on specialized catalytic systems, like zeolites, to convert methane into methanol. However, inherent limitations in selectivity, irreversibility, and pore blockages result in high costs and energy requirements, thus hindering their commercial viability and profitability. In contrast, biological methane conversion using methanotrophs has emerged as a promising alternative, offering higher conversion rates, self-renewability, improved selectivity, and economically feasible upstream processes. Nevertheless, biological methane oxidation encounters challenges including the difficulty in cultivating methanotrophs and their slow growth rates, which hinder large-scale bioprocessing. Another highlighted limitation is the limited mass transfer of methane into liquid in bioreactors. Practical strategies to enhance methane oxidation in biological systems, including optimizing reactor design to improve mass transfer, altering metal concentrations, genetic engineering of methane monooxygenases, enzyme encapsulation, and utilizing microbial consortia are discussed. By addressing the limitations of chemical approaches and highlighting the potential of biological methods, the review concluded that the utilization of genetically engineered methanotrophic biofilms on beads within a biotrickling reactor, along with enhanced aeration rates, will likely enhance methane oxidation and subsequent methane conversion rates.

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Section: Traditional Methods For Direct Atmospheric Methane Removalmentioning

confidence: 99%

Methane Oxidation via Chemical and Biological Methods: Challenges and Solutions

Samanta

Sani

2023

Methane

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Potential Air Quality Side-Effects of Emitting H₂O₂ to Enhance Methane Oxidation as a Climate Solution

Mayhew,

Haskins

2025

Environ. Sci. Technol.

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Evaluating the potential of iron-based interventions in methane reduction and climate mitigation

Meidan,

Li,

Cuevas

et al. 2024

Environ. Res. Lett.

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Keeping global surface temperatures below international climate targets will require substantial measures to control atmospheric CO2 and CH4 concentrations. Recent studies have focused on interventions to decrease CH4 through enhanced atmospheric oxidation. Here for the first time using a set of models, we evaluate the effect of adding iron aerosols to the atmosphere to enhance molecular chlorine production, and thus enhance the atmospheric oxidation of methane and reduce its concentration. Using different iron emission sensitivity scenarios, we examine the potential role and impact of enhanced iron emissions on direct interactions with solar radiation, and on the chemical and radiative response of methane. Our results show that the impact of iron emissions on CH4 depends sensitively on the location of the iron emissions. In all emission regions there is a threshold in the amount of iron that must be added to remove methane. Below this threshold CH4 increases. Even once that threshold is reached, the iron-aerosol driven chlorine-enhanced impacts on climate are complex. The radiative forcing of both methane and ozone are decreased in the most efficient regions but the direct effect due to the addition of absorbing iron aerosols tends to warm the planet. Adding any anthropogenic aerosol may also cool the planet due to aerosol cloud interactions, although these are very uncertain, and here we focus on the unique properties of adding iron aerosols. If the added emissions have a similar distribution as current shipping emissions, our study shows that the amount of iron aerosols that must be added before methane decreases is 2.5 times the current shipping emissions of iron aerosols, or 6 Tg Fe/yr in the most ideal case examined here. Our study suggests that the photoactive fraction of iron aerosols is a key variable controlling the impact of iron additions and poorly understood. More studies of the sensitivity of when, where and how iron aerosols are added should be conducted. Before seriously considering this method, additional impacts on the atmospheric chemistry, climate, environmental impacts and air pollution should be carefully assessed in future studies since they are likely to be important.

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Environmental Impact Modeling for a Small-Scale Field Test of Methane Removal by Iron Salt Aerosols

Cited by 5 publications

References 39 publications

Methane Oxidation via Chemical and Biological Methods: Challenges and Solutions

Methane Oxidation via Chemical and Biological Methods: Challenges and Solutions

Potential Air Quality Side-Effects of Emitting H₂O₂ to Enhance Methane Oxidation as a Climate Solution

Evaluating the potential of iron-based interventions in methane reduction and climate mitigation

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Environmental Impact Modeling for a Small-Scale Field Test of Methane Removal by Iron Salt Aerosols

Cited by 5 publications

References 39 publications

Methane Oxidation via Chemical and Biological Methods: Challenges and Solutions

Methane Oxidation via Chemical and Biological Methods: Challenges and Solutions

Potential Air Quality Side-Effects of Emitting H2O2 to Enhance Methane Oxidation as a Climate Solution

Evaluating the potential of iron-based interventions in methane reduction and climate mitigation

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Potential Air Quality Side-Effects of Emitting H₂O₂ to Enhance Methane Oxidation as a Climate Solution