Add to ORKGTransition metal carbides (TMC) have intriguing physical and chemical properties, especially when structured down to nanoscale. The temperature and chemical resilience of this family of materials made it ideal candidate for electrochemical applications in harsh environment. Among the TMC family, molybdenum carbide has been demonstrated as efficient catalyst for hydrogen evolution reactions (HER). This paper will use density function theory to investigate of the efficiency of molybdenum and tungsten carbide as catalyst for HER in neutral and alkane environment
These studies investigate the chemistry and stability of molybdenum carbides as an electrocatalyst. ...
Demands for sustainable production of hydrogen are rapidly increasing because of environmental consi...
Compound materials, such as transition-metal (TM) carbides, are anticipated to be effective electroc...
Transition metal carbides (TMC) have intriguing physical and chemical properties, especially when st...
The highly efficient electrochemical hydrogen evolution reaction (HER) provides a promising way to s...
Green and renewable energy is the key to overcoming energy-related challenges such as fossil-fuel de...
The electrochemical hydrogen evolution reaction (HER) has been considered as an efficient way of pro...
Monometallic Mo and W carbides as well as highly mixed (Mo,W) carbides with various Mo/W ratios were...
Rational design and synthesis of cheap, noble metal-free, thermal/hydrothermal stable and active cat...
Electrochemical water splitting is a promising approach to generate ‘green’ hydrogen. The efficiency...
It is essential to develop non-precious metal-based alternatives used in hydrogen evolution reaction...
The generation of clean and sustainable hydrogen fuel through water splitting demands efficient and ...
Proton exchange membrane or anion exchange membrane water electrolyzers and fuel cells are still exp...
Molybdenum boride (MoB) and carbide (Mo2C) are excellent catalysts for electrochemical hydrogen evol...
Transition metal carbides are a class of materials widely known for both their interesting physical ...
These studies investigate the chemistry and stability of molybdenum carbides as an electrocatalyst. ...
Demands for sustainable production of hydrogen are rapidly increasing because of environmental consi...
Compound materials, such as transition-metal (TM) carbides, are anticipated to be effective electroc...
Transition metal carbides (TMC) have intriguing physical and chemical properties, especially when st...
The highly efficient electrochemical hydrogen evolution reaction (HER) provides a promising way to s...
Green and renewable energy is the key to overcoming energy-related challenges such as fossil-fuel de...
The electrochemical hydrogen evolution reaction (HER) has been considered as an efficient way of pro...
Monometallic Mo and W carbides as well as highly mixed (Mo,W) carbides with various Mo/W ratios were...
Rational design and synthesis of cheap, noble metal-free, thermal/hydrothermal stable and active cat...
Electrochemical water splitting is a promising approach to generate ‘green’ hydrogen. The efficiency...
It is essential to develop non-precious metal-based alternatives used in hydrogen evolution reaction...
The generation of clean and sustainable hydrogen fuel through water splitting demands efficient and ...
Proton exchange membrane or anion exchange membrane water electrolyzers and fuel cells are still exp...
Molybdenum boride (MoB) and carbide (Mo2C) are excellent catalysts for electrochemical hydrogen evol...
Transition metal carbides are a class of materials widely known for both their interesting physical ...
These studies investigate the chemistry and stability of molybdenum carbides as an electrocatalyst. ...
Demands for sustainable production of hydrogen are rapidly increasing because of environmental consi...
Compound materials, such as transition-metal (TM) carbides, are anticipated to be effective electroc...