What question did this study set out to answer?

The research aims to explore the effectiveness of Nb2O5-Nb2CTx Schottky heterostructures in photothermal catalytic CO2 dissociation.

February 8, 2026

Photothermal Catalytic CO 2 Dissociation Over Nb 2 O 5 –Nb 2 CT x Schottky Heterostructures

Key Points

The research aims to explore the effectiveness of Nb2O5-Nb2CTx Schottky heterostructures in photothermal catalytic CO2 dissociation.
Designed Nb2O5-Nb2CTx Schottky heterostructures for photothermal CO2 dissociation.
Conducted CO2 dissociation reactions at 300°C under light irradiation.
Measured CO production rates and analyzed reaction mechanisms.
Achieved CO production rate of 70.1 μmol g−1 h−1 with the heterostructures.
Demonstrated threefold increase in production rate compared to pristine Nb2O5.
Identified superior photothermal conversion efficiency and enhanced charge transfer kinetics.

Abstract

Solar‐driven CO 2 dissociation reaction via a two‐step thermochemical cycle is a promising option, but it requires extremely high reaction temperatures (>1000°C). Herein, we designed Nb 2 O 5 –Nb 2 CT x Schottky heterostructures that could achieve photoinduced thermochemical CO 2 dissociation reaction at 300°C. Under light irradiation, the CO production rate of Nb 2 O 5 –Nb 2 CT x reaches to 70.1 μmol g −1 h −1 , which is three times higher than that of pristine Nb 2 O 5 . The high activity arose from the superior photothermal conversion efficiency of Nb 2 CT x , fast charge separation and transfer kinetics from the Schottky heterostructures, increased surface CO 2 adsorption sites from photoinduced oxygen vacancies, and efficient redox cycling ability. This work presents a feasible strategy to fabricate photothermal synergistic catalysts which could achieve stable CO 2 dissociation performance at mild reaction temperature.

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Cite This Study

Deng et al. (Tue,) studied this question.

synapsesocial.com/papers/698828ab0fc35cd7a88484de https://doi.org/https://doi.org/10.1002/adsc.70310

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