Litcius/Paper detail

Plasma-enhanced microwave-driven methane pyrolysis for hydrogen and carbon production

Francisco Cepeda, Luke Di Liddo, L. Mendoza, Murray J. Thomson

2025Journal of the Energy Institute6 citationsDOIOpen Access PDF

Abstract

Microwave-driven methane pyrolysis is a promising pathway for low-GHG hydrogen production. In this process, carbon particles absorb microwave radiation, heat the gas phase, and promote the decomposition of methane. Previous studies hypothesize that localized microplasmas, formed by arcing between conductive particles, may enhance pyrolysis by creating non-thermal excitation of methane molecules. However, the role of microplasmas has not been systematically isolated or quantified. This study investigates the impact of non-thermal plasma discharges on methane conversion and hydrogen yield using a microwave-driven fluidized-bed reactor. Graphitized carbon particles and tungsten electrodes were used to generate intense controlled plasma discharges while maintaining constant microwave power and bulk temperature. Results show that microplasmas induced by graphite alone do not significantly affect methane conversion. In contrast, the addition of unpowered electrodes results in a marked increase in methane conversion (up to 20%) and hydrogen yield. Carbon products formed in the plasma region were characterized by SEM, Raman, and XPS, revealing nanostructured, disordered carbon distinct from thermal film deposits. These findings suggest that only intense, electrode-driven discharges substantially enhance pyrolysis and carbon black production, informing reactor design strategies for efficient hydrogen generation. • Non-thermal plasma boosts thermal CH 4 pyrolysis without increasing power or temperature. • Microplasmas alone show negligible effect on CH 4 conversion or H 2 yield. • Electrode discharges increase conversion by an absolute 20% at constant microwave input. • Plasma yields nanoscale, disordered carbon distinct from thermal film deposits. • Reactor zones can be decoupled to optimize hydrogen and carbon product quality.

Topics & Concepts

HydrogenPyrolysisMethaneCarbon fibersMaterials scienceNonthermal plasmaGraphitePlasmaChemical engineeringCarbon blackCarbon monoxideHydrogen productionInorganic chemistryTungstenChemistryThermal decompositionAnalytical Chemistry (journal)Hydrogen purifierOxygenElectrodeMicrowaveThermalSyngasYield (engineering)Plasma Applications and DiagnosticsCatalysts for Methane ReformingThermochemical Biomass Conversion Processes