CO2 decomposition is a very strongly endothermic reaction where very high temperatures are required to thermally dissociate CO2. Radio frequency inductively-coupled plasma enables to selectively activate and dissociate CO2 at room temperature. Tuning the flow rate and the frequency of the radio frequency inductively-coupled plasma gives high yields of CO under mild conditions. Finally the discovery of a plasma catalytic effect has been demonstrated for CO2 dissociation that shows a significant increase of the CO yield by metallic meshes. The metallic meshes become catalysts under exposure to plasma to activate the recombination reaction of atomic O to yield O2, thereby reducing the reaction to convert CO back to CO2. Inductively-coupled hyb...
Surplus renewable electricity used to convert CO2 into CO, the building block of liquid fuels, advan...
In this work, a novel strategy of the use of dielectric barrier discharge (DBD) plasma-catalysis for...
Reduction of CO2 to CO for sustainable fuel production is studied in high-temperature (>3500 K) m...
CO2 decomposition is a very strongly endothermic reaction where very high temperatures are required ...
The synergy between catalysis and plasma chemistry often enhances the yield of chemical reactions in...
This paper focuses on how the electron temperature and other plasma properties affect optical emissi...
The continual and increasing use of fossil fuels throughout the world has advanced concerns of atmos...
A coaxial dielectric barrier discharge (DBD) reactor has been developed for plasma-catalytic convers...
Anthropogenic greenhouse gas emissions have caused changes to the Earth's climate, resulting in cata...
Carbon dioxide decomposition is a challenging target to combat climate change. Nonthermal plasmas ar...
In the context of novel alternative energy technologies, plasma processing systems are investigated....
The global energy challenges along with global warming are regarded as the most important issues fac...
The current research is focused on the decomposition of carbon dioxide (CO2) into carbon monoxide (C...
The combination of nonthermal plasma (NTP) with catalytic methods has been shown to improve catalyst...
Motivated by environmental applications such as synthetic fuel synthesis, plasma-driven conversion s...
Surplus renewable electricity used to convert CO2 into CO, the building block of liquid fuels, advan...
In this work, a novel strategy of the use of dielectric barrier discharge (DBD) plasma-catalysis for...
Reduction of CO2 to CO for sustainable fuel production is studied in high-temperature (>3500 K) m...
CO2 decomposition is a very strongly endothermic reaction where very high temperatures are required ...
The synergy between catalysis and plasma chemistry often enhances the yield of chemical reactions in...
This paper focuses on how the electron temperature and other plasma properties affect optical emissi...
The continual and increasing use of fossil fuels throughout the world has advanced concerns of atmos...
A coaxial dielectric barrier discharge (DBD) reactor has been developed for plasma-catalytic convers...
Anthropogenic greenhouse gas emissions have caused changes to the Earth's climate, resulting in cata...
Carbon dioxide decomposition is a challenging target to combat climate change. Nonthermal plasmas ar...
In the context of novel alternative energy technologies, plasma processing systems are investigated....
The global energy challenges along with global warming are regarded as the most important issues fac...
The current research is focused on the decomposition of carbon dioxide (CO2) into carbon monoxide (C...
The combination of nonthermal plasma (NTP) with catalytic methods has been shown to improve catalyst...
Motivated by environmental applications such as synthetic fuel synthesis, plasma-driven conversion s...
Surplus renewable electricity used to convert CO2 into CO, the building block of liquid fuels, advan...
In this work, a novel strategy of the use of dielectric barrier discharge (DBD) plasma-catalysis for...
Reduction of CO2 to CO for sustainable fuel production is studied in high-temperature (>3500 K) m...