Publications

Publications

Exploring Direct Electrochemical Fischer–Tropsch Chemistry of C1–C7 Hydrocarbons via Perimeter Engineering of Au–SrTiO3 Catalyst 저널 표지 논문

Exploring Direct Electrochemical Fischer–Tropsch Chemistry of C1–C7 Hydrocarbons via Perimeter Engineering of Au–SrTiO3 Catalyst

Advanced Energy Materials · 2024 Link ↗

Laser-engineered Ag/Ag oxide interfaces for tunable CO2 reduction: Mechanistic insights from experiment and theory

Laser-engineered Ag/Ag oxide interfaces for tunable CO2 reduction: Mechanistic insights from experiment and theory

Materials Today Energy · 2026 Link ↗

Laser ablation-controlled Au/Cu interfaces for modulating C1, C2, and C3+ chemistry in electrochemical CO2 reduction

Laser ablation-controlled Au/Cu interfaces for modulating C1, C2, and C3+ chemistry in electrochemical CO2 reduction

Materials Today Energy · 2025 Link ↗

Modulating electrochemical CO2 reduction products by precise tuning of CuZn surface oxidation states

Modulating electrochemical CO2 reduction products by precise tuning of CuZn surface oxidation states

Materials Today Energy · 2025 Link ↗

Electrochemical CO2 reduction chemistry of C1 and C2+ products on Cu/Zn electrodes via galvanic replacement

Electrochemical CO2 reduction chemistry of C1 and C2+ products on Cu/Zn electrodes via galvanic replacement

Journal of Alloys and Compounds · 2025 Link ↗

Electrochemical CO2/CO reduction on Ag/Cu electrodes and exploring minor Fischer–Tropsch reaction pathways

Electrochemical CO2/CO reduction on Ag/Cu electrodes and exploring minor Fischer–Tropsch reaction pathways

Applied Surface Science · 2024 Link ↗

Ultraviolet Light‐Assisted Decontamination of Chemical Warfare Agent Simulant 2‐Chloroethyl Phenyl Sulfide on Metal‐Loaded TiO2/Ti Surfaces

Ultraviolet Light‐Assisted Decontamination of Chemical Warfare Agent Simulant 2‐Chloroethyl Phenyl Sulfide on Metal‐Loaded TiO2/Ti Surfaces

ChemistryOpen · 2024 Link ↗

CuNiZn vs CuZn Electrodes: Electrochemical CO2 Reduction, Role of Metal Elements, and Insights for C–C Coupling Chemistry

CuNiZn vs CuZn Electrodes: Electrochemical CO2 Reduction, Role of Metal Elements, and Insights for C–C Coupling Chemistry

ACS Applied Energy Materials · 2024 Link ↗

Electrochemical syngas production over Au/SrTiO3 and Fischer–Tropsch synthesis chemistry for long-chain hydrocarbons

Electrochemical syngas production over Au/SrTiO3 and Fischer–Tropsch synthesis chemistry for long-chain hydrocarbons

International Journal of Hydrogen Energy · 2024 Link ↗

Unlocking long-chain hydrocarbons (C2–7) via direct electrochemical CO2 and CO reduction on balanced Au/Ni electrodes

Unlocking long-chain hydrocarbons (C2–7) via direct electrochemical CO2 and CO reduction on balanced Au/Ni electrodes

Nano Energy · 2023 Link ↗

Ag–Sb/Cu by Galvanic Replacement: Electrochemical CO2 Reduction and Unveiling C3+ Hydrocarbon Pathways

Ag–Sb/Cu by Galvanic Replacement: Electrochemical CO2 Reduction and Unveiling C3+ Hydrocarbon Pathways

The Journal of Physical Chemistry C · 2023 Link ↗

Electrochemical CO2 reduction versus CO reduction over Au/Ti electrocatalyts in phosphate buffer condition

Electrochemical CO2 reduction versus CO reduction over Au/Ti electrocatalyts in phosphate buffer condition

Chemical Engineering Journal · 2023 Link ↗

Interfacial Electronic Structures and the Fischer–Tropsch Synthesis Path by Electrochemical CO2/CO Reduction for Ternary CuNiZn Alloys

Interfacial Electronic Structures and the Fischer–Tropsch Synthesis Path by Electrochemical CO2/CO Reduction for Ternary CuNiZn Alloys

ACS Applied Energy Materials · 2023 Link ↗

Electrochemical CO2 Reduction over In Alloy Electrodes and Depth‐Profiled Interfacial Electronic Structures

Electrochemical CO2 Reduction over In Alloy Electrodes and Depth‐Profiled Interfacial Electronic Structures

ChemCatChem · 2023 Link ↗

Eu(III)–BaTiO3 nanoparticles and BaTiO3/TiO2/Ti sheets; photocatalytic and electrocatalytic CO2 reduction

Eu(III)–BaTiO3 nanoparticles and BaTiO3/TiO2/Ti sheets; photocatalytic and electrocatalytic CO2 reduction

Materials Science in Semiconductor Processing · 2023 Link ↗