Research

Research

Controlling electrochemical transformations at catalytic interfaces — from CO2 to fuels, from pollutants to value.

01

01 · Flagship Project

Electrochemical CO2/CO Conversion & e-Fischer–Tropsch

Recycling CO2 and CO into high-value fuels (methane, methanol, and multi-carbon products) using advanced catalytic and electrochemical methods. We pursue electrochemical C–C chain growth — the electrochemical analogue of Fischer–Tropsch synthesis — at dynamic catalyst interfaces.

CO2RR · CORR · C–C coupling · Cu-based catalysts

02

02

Green Hydrogen Production

Generating clean hydrogen and oxygen through electrochemical water splitting, with a focus on earth-abundant electrocatalysts and mechanistic understanding of interfacial processes.

HER / OER · Water splitting · Electrocatalysis

03

03

Electrochemical Ammonia Synthesis

Transforming NOx, nitrite, and nitrate into valuable ammonia (NH3) through innovative electrochemical pathways — turning pollutants into fuel and fertilizer feedstock.

NO3RR · NH3 · Nitrogen cycle

04

04

Photon & Plasma-to-X

Solar, thermal, and plasma-driven chemical conversion: photocatalytic and plasma-chemical routes complementing electrochemistry for energy conversion and environmental remediation.

Photocatalysis · Plasma chemistry · Photoelectrochemistry

05

05

Environment: Water Treatment & Upcycling

Removing water pollutants with advanced photocatalytic processes, developing PET plastic recycling/upcycling methods, and designing catalysts for purification of hazardous air pollutants.

Water purification · Plastic upcycling · Air pollution control

06

06

Advanced Materials & Spectroscopy

Synthesis and physicochemical characterization of functional nanomaterials — phosphors for next-generation displays, lanthanide chemistry, and high-sensitivity sensors — backed by a wide array of spectroscopic tools.

Nanomaterials · Phosphors · Lanthanides · Sensors