Standard

Unraveling the Carbon Footprint: How Ti3C2Tx MXene Stability Affects CO2 Photoreduction on TiO2. / Vasilchenko, Danila; Nikolaev, Vladislav; Alekseev, Roman et al.

In: Inorganic Chemistry, Vol. 65, No. 26, 21.06.2026, p. 15212-15224.

Research output: Contribution to journalArticlepeer-review

Harvard

Vasilchenko, D, Nikolaev, V, Alekseev, R, Gerasimov, E, Popovetskiy, P, Kolesov, B, Mishchenko, D, Zhurenok, A & Kozlova, E 2026, 'Unraveling the Carbon Footprint: How Ti3C2Tx MXene Stability Affects CO2 Photoreduction on TiO2', Inorganic Chemistry, vol. 65, no. 26, pp. 15212-15224. https://doi.org/10.1021/acs.inorgchem.6c02232

APA

Vasilchenko, D., Nikolaev, V., Alekseev, R., Gerasimov, E., Popovetskiy, P., Kolesov, B., Mishchenko, D., Zhurenok, A., & Kozlova, E. (2026). Unraveling the Carbon Footprint: How Ti3C2Tx MXene Stability Affects CO2 Photoreduction on TiO2. Inorganic Chemistry, 65(26), 15212-15224. https://doi.org/10.1021/acs.inorgchem.6c02232

Vancouver

Vasilchenko D, Nikolaev V, Alekseev R, Gerasimov E, Popovetskiy P, Kolesov B et al. Unraveling the Carbon Footprint: How Ti3C2Tx MXene Stability Affects CO2 Photoreduction on TiO2. Inorganic Chemistry. 2026 Jun 21;65(26):15212-15224. doi: 10.1021/acs.inorgchem.6c02232

Author

Vasilchenko, Danila ; Nikolaev, Vladislav ; Alekseev, Roman et al. / Unraveling the Carbon Footprint: How Ti3C2Tx MXene Stability Affects CO2 Photoreduction on TiO2. In: Inorganic Chemistry. 2026 ; Vol. 65, No. 26. pp. 15212-15224.

BibTeX

@article{3c38a1dcfae1439eaf177f69fd917e8a,
title = "Unraveling the Carbon Footprint: How Ti3C2Tx MXene Stability Affects CO2 Photoreduction on TiO2",
abstract = "MXenes are promising cocatalysts for CO2 photoreduction (CO2RR) on semiconductors like TiO2. However, their inherent hydrolytic instability can produce carbonaceous gases that are identical to the target products. This study systematically investigates this interplay for a model Ti3C2Tx/TiO2 system. We first demonstrate that aqueous Ti3C2Tx ink undergoes continuous hydrolysis under ambient conditions, releasing CH4, CO, CO2, and C2 hydrocarbons, a process that is significantly accelerated by visible light via a photothermal mechanism. Composite catalysts were synthesized and characterized, confirming intimate contact between MXene and TiO2. Photocatalytic testing revealed a pivotal finding. CO2 not only failed to increase the rate of CH4 evolution but even suppressed it compared to that under an inert (Ar) atmosphere, whereas the CO evolution rate remained unchanged. Product formation scaled with MXene loading and dispersion state, with exfoliated flakes degrading faster. The total carbon evolved per hour accounted for only about 1% of the carbon initially present in the MXene, a rate consistent with many literature reports. Our results establish that the hydrolytic self-decomposition of Ti3C2Tx provides a dominant background signal that can confound the interpretation of photocatalytic performance. This work underscores the necessity of rigorous control experiments to distinguish genuine CO2 reduction from catalyst degradation, providing an essential framework for evaluating stable MXene-based photocatalysts.",
keywords = "Composites, Inorganic carbon compounds, Oxides, Redox reactions, Two dimensional materials",
author = "Danila Vasilchenko and Vladislav Nikolaev and Roman Alekseev and Evgeny Gerasimov and Pavel Popovetskiy and Boris Kolesov and Denis Mishchenko and Angelina Zhurenok and Ekaterina Kozlova",
note = "This study was supported by the Russian Science Foundation (24-13-00416). The authors are grateful to E. Yu. Aidakov for recording the XPS spectra. The XPS and HR TEM experiments were performed using the facilities of the shared research center “National Center of Investigation of Catalysts” at Boreskov Institute of Catalysis.",
year = "2026",
month = jun,
day = "21",
doi = "10.1021/acs.inorgchem.6c02232",
language = "English",
volume = "65",
pages = "15212--15224",
journal = "Inorganic Chemistry",
issn = "0020-1669",
publisher = "ACS Publication",
number = "26",

}

RIS

TY - JOUR

T1 - Unraveling the Carbon Footprint: How Ti3C2Tx MXene Stability Affects CO2 Photoreduction on TiO2

AU - Vasilchenko, Danila

AU - Nikolaev, Vladislav

AU - Alekseev, Roman

AU - Gerasimov, Evgeny

AU - Popovetskiy, Pavel

AU - Kolesov, Boris

AU - Mishchenko, Denis

AU - Zhurenok, Angelina

AU - Kozlova, Ekaterina

N1 - This study was supported by the Russian Science Foundation (24-13-00416). The authors are grateful to E. Yu. Aidakov for recording the XPS spectra. The XPS and HR TEM experiments were performed using the facilities of the shared research center “National Center of Investigation of Catalysts” at Boreskov Institute of Catalysis.

PY - 2026/6/21

Y1 - 2026/6/21

N2 - MXenes are promising cocatalysts for CO2 photoreduction (CO2RR) on semiconductors like TiO2. However, their inherent hydrolytic instability can produce carbonaceous gases that are identical to the target products. This study systematically investigates this interplay for a model Ti3C2Tx/TiO2 system. We first demonstrate that aqueous Ti3C2Tx ink undergoes continuous hydrolysis under ambient conditions, releasing CH4, CO, CO2, and C2 hydrocarbons, a process that is significantly accelerated by visible light via a photothermal mechanism. Composite catalysts were synthesized and characterized, confirming intimate contact between MXene and TiO2. Photocatalytic testing revealed a pivotal finding. CO2 not only failed to increase the rate of CH4 evolution but even suppressed it compared to that under an inert (Ar) atmosphere, whereas the CO evolution rate remained unchanged. Product formation scaled with MXene loading and dispersion state, with exfoliated flakes degrading faster. The total carbon evolved per hour accounted for only about 1% of the carbon initially present in the MXene, a rate consistent with many literature reports. Our results establish that the hydrolytic self-decomposition of Ti3C2Tx provides a dominant background signal that can confound the interpretation of photocatalytic performance. This work underscores the necessity of rigorous control experiments to distinguish genuine CO2 reduction from catalyst degradation, providing an essential framework for evaluating stable MXene-based photocatalysts.

AB - MXenes are promising cocatalysts for CO2 photoreduction (CO2RR) on semiconductors like TiO2. However, their inherent hydrolytic instability can produce carbonaceous gases that are identical to the target products. This study systematically investigates this interplay for a model Ti3C2Tx/TiO2 system. We first demonstrate that aqueous Ti3C2Tx ink undergoes continuous hydrolysis under ambient conditions, releasing CH4, CO, CO2, and C2 hydrocarbons, a process that is significantly accelerated by visible light via a photothermal mechanism. Composite catalysts were synthesized and characterized, confirming intimate contact between MXene and TiO2. Photocatalytic testing revealed a pivotal finding. CO2 not only failed to increase the rate of CH4 evolution but even suppressed it compared to that under an inert (Ar) atmosphere, whereas the CO evolution rate remained unchanged. Product formation scaled with MXene loading and dispersion state, with exfoliated flakes degrading faster. The total carbon evolved per hour accounted for only about 1% of the carbon initially present in the MXene, a rate consistent with many literature reports. Our results establish that the hydrolytic self-decomposition of Ti3C2Tx provides a dominant background signal that can confound the interpretation of photocatalytic performance. This work underscores the necessity of rigorous control experiments to distinguish genuine CO2 reduction from catalyst degradation, providing an essential framework for evaluating stable MXene-based photocatalysts.

KW - Composites

KW - Inorganic carbon compounds

KW - Oxides

KW - Redox reactions

KW - Two dimensional materials

UR - https://www.scopus.com/pages/publications/105043930951

UR - https://www.mendeley.com/catalogue/5e2caa65-4710-36d8-a70c-3788e28bea92/

U2 - 10.1021/acs.inorgchem.6c02232

DO - 10.1021/acs.inorgchem.6c02232

M3 - Article

C2 - 42324658

VL - 65

SP - 15212

EP - 15224

JO - Inorganic Chemistry

JF - Inorganic Chemistry

SN - 0020-1669

IS - 26

ER -

ID: 80160588