Low CO content hydrogen production from bio-ethanol using a combined plasma reforming–catalytic water gas shift reactor

“…showed an enhancement in activity with increasing current on applying an electric field to the forward water‐gas shift reaction when the catalyst was also heated to 423–873 K . The water–gas shift reaction has also been reported in close proximity of a plasma source, that is, post plasma catalysis, to enhance the hydrogen production following a plasma activated ethanol reforming system . Therein, the water–gas shift reaction used the heat generated from the plasma system to transform the reformed products.…”

“…Examples include decomposition of volatile organic compounds (VOCs) and hydrogenation reactions . Non‐thermal plasmas have also been widely used with endothermic processes such as reforming processes leading to high H 2 and CO selectivities . Sekine et al.…”

Non‐Thermal Plasma Activation of Gold‐Based Catalysts for Low‐Temperature Water–Gas Shift Catalysis

“…showed an enhancement in activity with increasing current on applying an electric field to the forward water‐gas shift reaction when the catalyst was also heated to 423–873 K . The water–gas shift reaction has also been reported in close proximity of a plasma source, that is, post plasma catalysis, to enhance the hydrogen production following a plasma activated ethanol reforming system . Therein, the water–gas shift reaction used the heat generated from the plasma system to transform the reformed products.…”

“…Examples include decomposition of volatile organic compounds (VOCs) and hydrogenation reactions . Non‐thermal plasmas have also been widely used with endothermic processes such as reforming processes leading to high H 2 and CO selectivities . Sekine et al.…”

Non‐Thermal Plasma Activation of Gold‐Based Catalysts for Low‐Temperature Water–Gas Shift Catalysis

“…[1][2][3][4][5][6][7][8][9][10][11][12] Examples include decomposition of volatile organic compounds (VOCs) and hydrogenation reactions. [4][5][6][7][8][9]12,13] Nonthermal plasmas have also been widely used with endothermic processes such as reforming processes [14][15][16][17] leading to high H 2 and CO selectivities. [14][15][16] Sekine et al showed an enhancement in activity with increasing current on applying an electric field to the forward water-gas shift reaction when the catalyst was also heated to 423-873 K. [2] Thew ater-gas shift reaction has also been reported in close proximity of aplasma source,that is,post plasma catalysis,toenhance the hydrogen production following ap lasma activated ethanol reforming system.…”

“…[14][15][16] Sekine et al showed an enhancement in activity with increasing current on applying an electric field to the forward water-gas shift reaction when the catalyst was also heated to 423-873 K. [2] Thew ater-gas shift reaction has also been reported in close proximity of aplasma source,that is,post plasma catalysis,toenhance the hydrogen production following ap lasma activated ethanol reforming system. [17] Therein, the water-gas shift reaction used the heat generated from the plasma system to transform the reformed products. Close coupling of plasmas with heterogeneous catalysts presents many advantages,i ncluding the possibility of opening up alternative reaction pathways from the plasmagenerated species [13] and structural changes of the active phase due to the plasma;however,the activation mechanism depends on many factors including the type of catalyst, reactants,r eaction conditions.…”

Non‐Thermal Plasma Activation of Gold‐Based Catalysts for Low‐Temperature Water–Gas Shift Catalysis

“…From 1980s, non-thermal plasma started to flourish in surface modification 3 , environmental governance 4 5 6 7 8 , clean energy 9 10 , biomedicine 11 12 13 and many other fields. So the research direction of multi-disciplinary cross has formed 14 15 .…”

Qualitation and Quantitation on Microplasma Jet for Bacteria Inactivation