Radio-frequency induction heating powered low-temperature catalytic CO2 conversion via bi-reforming of methane

Nguyen, Hoang M.; Phan, Chi; Liu, Shaomin; Pham‐Huu, Cuong; Nguyen-Dinh, Lam

doi:10.1016/j.cej.2021.132934

Cited by 24 publications

(5 citation statements)

References 63 publications

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“…172 All evaluations are based on lab-scale experiments and are in the research and development stage without industrial validation. 172 Induction-heated systems for reforming processes are developed in the context of steam methane reforming, [174][175][176] dry methane reforming, 174,175 or POX 177 for natural gas or biogas. Catalyst development focuses on high educt conversion and efficient heat dissipation at the same time.…”

Section: Reviewmentioning

confidence: 99%

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Electrification of gasification-based biomass-to-X processes – a critical review and in-depth assessment

Dossow,

Klüh,

Umeki

et al. 2024

Energy Environ. Sci.

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Section: Reviewmentioning

confidence: 99%

“…Induction-heated systems for reforming processes are developed in the context of steam methane reforming, 174–176 dry methane reforming, 174,175 or POX 177 for natural gas or biogas. Catalyst development focuses on high educt conversion and efficient heat dissipation at the same time.…”

Section: Direct Electrification Of Btx Processes (Ebtx)mentioning

confidence: 99%

Electrification of gasification-based biomass-to-X processes – a critical review and in-depth assessment

Dossow,

Klüh,

Umeki

et al. 2024

Energy Environ. Sci.

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“…This precise targeting is essential for accurately monitoring CO 2 conversion. Proper frequency adjustment maximizes the e ciency of exciting the targeted nuclei while minimizing interference from other species [18][19][20].…”

Section: Effect Of Experimental Parameters On Co2 Cracking E Ciencymentioning

confidence: 99%

Exploration of Electromagnetic Resonance for Advanced CO2 Molecular Cracking: Towards a Revolution in Carbon Emission Management.

Mnaouer,

Mghaiouini,

Mouden

2023

Preprint

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This study focuses on optimizing the efficiency and selectivity of the CO2 cracking process using the method of experimental design and leveraging electromagnetic resonance. In a context where the utilization of CO2 as a valuable raw material is gaining increasing interest, the CO2 cracking process activated by electromagnetic resonance offers promising prospects. The experimental design method is implemented to deeply analyze the influential factors and their interactions within this process. Through a series of carefully designed experiments, the optimal parameters for achieving maximum CO2 conversion and increased product selectivity are determined. The results highlight the effectiveness of using electromagnetic resonance to facilitate the CO2 cracking process, while also highlighting its potential for the creation of high-value carbon-based products. This research contributes to the development of more efficient and sustainable methods for the utilization of CO2

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“…For the same results, the newly prepared catalyst requires about 15% lower magnetic field strength than that applied with the common CoNi catalyst. Nguyen et al [80] used binary Cu-Ni, Cu−Co, and ternary Cu−Ni−Co catalysts for methane double reforming process to produce hydrogen by using induction heating technology. As shown in Figure 13.…”

Section: Endothermic Steam Reforming For Hydrogen Productionmentioning

confidence: 99%

Research Progress on Magnetic Catalysts and Its Application in Hydrogen Production Area

Wang

Guan

et al. 2022

Energies

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The noncontact heating technology of IH targets heat directly where it is needed through the electromagnetic energy adsorption and conversion of magnetic materials. Unlike conventional heating methods, the heat generated by electromagnetic induction of magnetic materials can be applied directly into the reactor without heating the entire device; this new heating method is not only more energy efficient but also safer, cleaner and more sustainable if renewable electricity is adopted; moreover, magnetic catalysts can be recovered and reused by separating chemical reactants and products from the catalyst by the application of a magnetic field, and it can provide the required heat source for the reaction without altering its catalytic properties. Magnetic catalysts with an electric field have been applied to some industrial areas, such as the preparation of new materials, catalytic oxidation reactions, and high-temperature heat absorption reactions. It is a trend that is used in the hydrogen production process, especially the endothermic steam reforming process. Therefore, in this paper, the heat release mechanism, properties, preparation methods and the application of magnetic catalysts were presented. Highlights of the application and performance of magnetic catalysts in the hydrogen production area were also discussed.

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Radio-frequency induction heating powered low-temperature catalytic CO2 conversion via bi-reforming of methane

Cited by 24 publications

References 63 publications

Electrification of gasification-based biomass-to-X processes – a critical review and in-depth assessment

Electrification of gasification-based biomass-to-X processes – a critical review and in-depth assessment

Exploration of Electromagnetic Resonance for Advanced CO2 Molecular Cracking: Towards a Revolution in Carbon Emission Management.

Research Progress on Magnetic Catalysts and Its Application in Hydrogen Production Area

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