Hydrogen Production through Water Vapors using Optimized Corona-DBD Hybrid Plasma Micro-Reactor

Hydrogen as secondary energy carrier is one of the promising routes to meet renewable and sustainable energy demand. Hydrogen production using water plasmolysis, so far, has been considered as energy intensive. How-ever, recent developments in the field of microplasmas has reduced energy requirement of water plasmolysis on par with electrolysis. However, there's still room for improvement as water vapors dissociation efficiencies are less than thermodynamic and kinetic limits. One of the ways to do that is to split microchannel in plasma into sub-micron channels by packing beads inside the reactor. The current study investigates the plasmolysis of water vapours (steam) and argon gas with (1) empty channel plasma reactor and (2) glass beads packed plasma reactor. A custom-made Corona-DBD hybrid microplasma reactor has been designed and employed for water steam plasmolysis. This study aims to investigate the feasibility of water vapors dissociating into hydrogen at a rela-tively small interelectrode gap at atmospheric pressure. The minimum breakdown voltage has been found to be 3.7 kVpk-pk at 5 mA current. The maximum hydrogen production rate was observed 23.9 g/kWh at optimized conditions for the glass beads packed plasma reactor. So, in current study glass beads packed plasma micro -reactor yielded 23.9g of H2/kWh which is significantly higher than any previously published study

Automated summary

Hydrogen as a secondary energy carrier has great potential in meeting renewable and sustainable energy demand. Recent developments in microplasmas have reduced the energy requirement of water plasmolysis to be on par with electrolysis. However, there is still room for improvement in the dissociation efficiency of water vapors. This study investigates the plasmolysis of water vapors with both empty channel plasma reactor and glass beads packed plasma reactor. The results show that the glass beads packed plasma micro-reactor achieved a hydrogen production rate of 23.9 g/kWh, significantly higher than previous studies.