Methane Catalytic Combustion under Lean Conditions over Pristine and Ir-Loaded La1−xSrxMnO3 Perovskites: Efficiency, Hysteresis, and Time-on-Stream and Thermal Aging Stabilities

Drosou, Catherine; Nikolaraki, Ersi; Georgakopoulou, Theodora; Fanourgiakis, Sotiris; Zaspalis, Vassilios T.; Yentekakis, Ioannis V.

doi:10.3390/nano13152271

Nanomaterials

2023

DOI: 10.3390/nano13152271

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Methane Catalytic Combustion under Lean Conditions over Pristine and Ir-Loaded La1−xSrxMnO3 Perovskites: Efficiency, Hysteresis, and Time-on-Stream and Thermal Aging Stabilities

Catherine Drosou,

Ersi Nikolaraki,

Theodora Georgakopoulou

et al.

Abstract: The increasing use of natural gas as an efficient, reliable, affordable, and cleaner energy source, compared with other fossil fuels, has brought the catalytic CH4 complete oxidation reaction into the spotlight as a simple and economic way to control the amount of unconverted methane escaping into the atmosphere. CH4 emissions are a major contributor to the ‘greenhouse effect’, and therefore, they need to be effectively reduced. Catalytic CH4 oxidation is a promising method that can be used for this purpose. D… Show more

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Cited by 2 publications

References 92 publications

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Exploring Iridium's Catalytic Role in Redox Reactions: A Concise Review

Sahgal,

Yadav

2024

CPC

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Abstract:: Transition metals exhibit a remarkable capacity to catalyse redox processes, playing a crucial role in various natural, biological, and chemical transformations. Among all the elements in the periodic table, iridium stands out with the broadest range of oxidation states. With its electronic configuration of 5d76s2, iridium displays a range of oxidation states, fluctuating from —3 in [Ir (CO)3]3- to +9 in [IrO4]2+. The utilization of iridium as a catalyst stems from its capability to adopt these variable oxidation states. Notably, Iridium (III) complexes exhibit significant catalytic activity in both acidic and basic environments, facilitating a diverse array of organic and inorganic chemical transformations. The catalytic mechanism adapts according to the specific conditions under which the catalysts are employed. Iridium's catalytic efficiency is notably enhanced in an acidic environment, as highlighted in the review, compared to its performance in a basic medium. Iridium stands as the sole reported catalyst with the capability to harness sunlight and transform it into chemical energy, offering promising prospects for application in artificial energy systems. The high surface-to-volume ratio of IrNPs contributes to their excellent catalytic performance. As research in Nanocatalysis continues to evolve, iridium remains a key player in shaping the future of sustainable and efficient chemical processes.

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Exploring Iridium's Catalytic Role in Redox Reactions: A Concise Review

Sahgal,

Yadav

2024

CPC

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Advances in Nanomaterials for Energy Conversion and Environmental Catalysis

Qi,

Liu

2024

Nanomaterials

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Methane Catalytic Combustion under Lean Conditions over Pristine and Ir-Loaded La1−xSrxMnO3 Perovskites: Efficiency, Hysteresis, and Time-on-Stream and Thermal Aging Stabilities

Cited by 2 publications

References 92 publications

Exploring Iridium's Catalytic Role in Redox Reactions: A Concise Review

Exploring Iridium's Catalytic Role in Redox Reactions: A Concise Review

Advances in Nanomaterials for Energy Conversion and Environmental Catalysis

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