Carbon capture at its core is among the biggest and most complex chemical separations due to challenge of how to selectively remove what is best described as a kinetically and thermodynamically inert molecule (CO2) from dilute and complex gas mixtures…
As part of the consortium for Computational Physics and Chemistry we have conducted a collaboration with PNNL and ORNL scientists who are independently developing catalysts to produce butenes from ethanol derived from renewable sources…
While water electrolysis (H2O(l) → H2 + ½ O2; ΔH° = 286 kJ/mol H2 ) holds promise for the generation of CO2-free hydrogen (H2), the high energy intensity and cost of electricity hinder their widespread utilization for H2 generation…
Massive and immediate deployment of carbon capture, utilization, and storage (CCUS) technologies are required to meet our climate change mitigation goals. But significant improvements in cost and performance of current CCUS technologies are needed for its widespread implementation…
While water electrolysis (H2O(l) → H2 + ½ O2; ΔH° = 286 kJ/mol H2 ) holds promise for the generation of CO2-free hydrogen (H2), the high energy intensity and cost of electricity hinder their widespread utilization for H2 generation…
Electronic regulation of MoS2 edge sites based on (Ni, Co) d electrons transfer to improve the activity of CO sulfur-resistant methanation, Tianjin University, China
While water electrolysis (H2O(l) → H2 + ½ O2; ΔH° = 286 kJ/mol H2 ) holds promise for the generation of CO2-free hydrogen (H2), the high energy intensity and cost of electricity hinder their widespread utilization for H2 generation…
Electronic regulation of MoS2 edge sites based on (Ni, Co) d electrons transfer to improve the activity of CO sulfur-resistant methanation, Tianjin University, China
While water electrolysis (H2O(l) → H2 + ½ O2; ΔH° = 286 kJ/mol H2 ) holds promise for the generation of CO2-free hydrogen (H2), the high energy intensity and cost of electricity hinder their widespread utilization for H2 generation…
Electronic regulation of MoS2 edge sites based on (Ni, Co) d electrons transfer to improve the activity of CO sulfur-resistant methanation, Tianjin University, China
Massive and immediate deployment of carbon capture, utilization, and storage (CCUS) technologies are required to meet our climate change mitigation goals. But significant improvements in cost and performance of current CCUS technologies are needed for its widespread implementation…
While water electrolysis (H2O(l) → H2 + ½ O2; ΔH° = 286 kJ/mol H2 ) holds promise for the generation of CO2-free hydrogen (H2), the high energy intensity and cost of electricity hinder their widespread utilization for H2 generation…
Electronic regulation of MoS2 edge sites based on (Ni, Co) d electrons transfer to improve the activity of CO sulfur-resistant methanation, Tianjin University, China
Massive and immediate deployment of carbon capture, utilization, and storage (CCUS) technologies are required to meet our climate change mitigation goals. But significant improvements in cost and performance of current CCUS technologies are needed for its widespread implementation…
While water electrolysis (H2O(l) → H2 + ½ O2; ΔH° = 286 kJ/mol H2 ) holds promise for the generation of CO2-free hydrogen (H2), the high energy intensity and cost of electricity hinder their widespread utilization for H2 generation…
Massive and immediate deployment of carbon capture, utilization, and storage (CCUS) technologies are required to meet our climate change mitigation goals. But significant improvements in cost and performance of current CCUS technologies are needed for its widespread implementation…
To achieve our climate change mitigation goals, the large-scale deployment of carbon capture, utilization, and storage (CCUS) technologies is essential. However, significant advancements in the cost and performance of current CCUS technologies are necessary for widespread adoption…