Looking For Bonds: Turning CO2 From Air Into Fuels For The Future - Alma Paola Hernandez

Princeton University
2026
Carbon Dioxide Conversion
CO2 Reduction
Sustainable Fuels
electrochemistry
catalysis
hydrocarbons
renewable energy
carbon capture
Fuel Synthesis
materials science
porous materials
Energy Innovation
climate solutions
green technology
chemical engineering

This research explores converting CO₂ into fuel by designing surfaces that promote carbon–carbon bonding. Using porous materials to concentrate CO₂, it increases reaction efficiency and enables formation of longer hydrocarbon chains. This approach could transform atmospheric carbon into usable fuels, offering a sustainable pathway for future energy production.

Clearing the Roads for Carbon Dioxide - Evangelos Kostarelos

Toronto Metropolitan University
Carbon Dioxide Electrolysis
clean energy
renewable energy
Gas Diffusion Layer
electrochemistry
carbon capture
Carbon Utilization
sustainable technology
climate change solutions
energy conversion
computational modelling
porous materials
microstructure
Transport Phenomena
fluid dynamics
Electrolyte Flooding
materials science
chemical engineering
Reaction Engineering
CO2 Conversion
industrial chemistry
Energy Systems
environmental engineering
green technology
Fuel Synthesis
Connectivity
porosity
Mass Transport
Electrochemical Devices
decarbonization

This research uses a traffic analogy to explain gas transport challenges in carbon dioxide electrolysis devices. Despite identical porosity, microstructural connectivity determines performance under flooding conditions. Computational modelling reveals how pathway structure affects efficiency, guiding design improvements that enhance CO₂ conversion into fuels and chemicals, supporting scalable and cleaner energy technologies.

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