1. Liao, Lei, et al. Constructing MOFs-derived Co3O4 microsphere with atomic pn homojunction as an efficient photothermal catalyst for boosting ethyl acetate oxidation under light irradiation. Separation and Purification Technology 309 (2023): 122939.

2. **ong, Wuwan, et al. Economical and sustainable synthesis of small-pore chabazite catalysts for NO x abatement by recycling organic structure-directing agents. Environmental Science & Technology 57.1 (2022): 655-665.

3. Wang, Bangfen, et al. Dielectric barrier discharge plasma modified Pt/CeO2 catalysts for toluene oxidation: effect of discharge time. Applied Surface Science 614 (2023): 156162.

4. Liu, Peng, et al. Different Reactivity of Birnessite and Cryptomelane toward Isoprene: Effect of Structure, Morphology, and Exposed Faces. The Journal of Physical Chemistry C 126.51 (2022): 21558-21567.

5. Wang, Bangfen, et al. Unravelling the correlation of dielectric barrier discharge power and performance of Pt/CeO 2 catalysts for toluene oxidation. Catalysis Science & Technology 13.2 (2023): 389-399.

6. Chen, Gui, et al. Enhanced plasma-catalytic oxidation of methanol over MOF-derived CeO2 catalysts with exposed active sites. Journal of Environmental Chemical Engineering 10.6 (2022): 108981.

7. Chen, Dongdong, et al. Mechanistic insights into the promotion of low-temperature NH3-SCR catalysis by copper auto-reduction in Cu-zeolites. Applied Catalysis B: Environmental 322 (2023): 122118.

8. Su, Chun**g, et al. Unraveling specific role of carbon matrix over Pd/quasi-Ce-MOF facilitating toluene enhanced degradation. Journal of Rare Earths 40.11 (2022): 1751-1762.

9. Peng, Lin, et al. Ammonia abatement via selective oxidation over electron-deficient copper catalysts. Environmental Science & Technology 56.19 (2022): 14008-14018.

10. Liu, Peng, et al. Effect of iron substitution in cryptomelane on the heterogeneous reaction with isoprene. Journal of Hazardous Materials 437 (2022): 129293.

11. Wang, **aohong, et al. Experimental and computational investigation on the organic acid modification of porous carbon for toluene adsorption under humid conditions. Chemical Engineering Journal 450 (2022): 138070.

12. Liang, **aoming, et al. Carbonyls from commercial, canteen and residential cooking activities as crucial components of VOC emissions in China. Science of The Total Environment 846 (2022): 157317.

13. Yao, **ze, et al. Rapid Adsorption of Indoor Low-Concentration Formaldehyde by β-Cyclodextrin-Based Porous Organic Polymers. Industrial & Engineering Chemistry Research 61.30 (2022): 11148-11155.

14. Shi, Xuefeng, et al. Effect of oxygen vacancy on the oxidation of toluene by ozone over Ag-Ce catalysts at low temperature. Applied Surface Science 601 (2022): 154237.

15. Zhang, **, et al. Static and dynamic quantification tracking of asymmetric oxygen vacancies in copper-ceria catalysts with superior catalytic activity. Applied Catalysis B: Environmental 316 (2022): 121620.

16. Ou, Runhua, et al. Emission characteristics and ozone formation potentials of VOCs from ultra-low-emission waterborne automotive painting. Chemosphere 305 (2022): 135469.

17. Li, Yinsong, et al. Characteristics and sources of volatile organic compounds (VOCs) in **nxiang, China, during the 2021 summer ozone pollution control. Science of the Total Environment 842 (2022): 156746.

18. **ao, Gaofei, et al. Cu-VWT Catalysts for Synergistic Elimination of NO x and Volatile Organic Compounds from Coal-Fired Flue Gas. Environmental Science & Technology 56.14 (2022): 10095-10104.

19. Sun, Yuhai, et al. Plasma-catalytic CO2 hydrogenation over a Pd/ZnO catalyst: in situ probing of gas-phase and surface reactions. JACS Au 2.8 (2022): 1800-1810.

20. Du, Yueying, et al. A high-performance and stable Cu/Beta for adsorption-catalytic oxidation in-situ destruction of low concentration toluene. Science of the Total Environment 833 (2022): 155288.

21. Li, Anqi, et al. A dual plasmonic core—shell Pt/[TiN@ TiO2] catalyst for enhanced photothermal synergistic catalytic activity of VOCs abatement. Nano Research 15.8 (2022): 7071-7080.

22. Li, Yifei, et al. Engineering cobalt oxide with coexisting cobalt defects and oxygen vacancies for enhanced catalytic oxidation of toluene. ACS Catalysis 12.9 (2022): 4906-4917.

23. Gan, Qi, et al. Synergistic catalytic ozonation of toluene with manganese and cerium varies at low temperature. Chinese Chemical Letters 33.5 (2022): 2726-2730.

24. Wu, Peng, et al. Quenching-induced surface modulation of perovskite oxides to boost catalytic oxidation activity. Journal of Hazardous Materials 433 (2022): 128765.

25. Ye, Guangzheng, et al. Preparing hierarchical porous carbon with well-developed microporosity using alkali metal-catalyzed hydrothermal carbonization for VOCs adsorption. Chemosphere 298 (2022): 134248.

26. **ao, Gaofei, et al. Insights into the effect of flue gas on synergistic elimination of toluene and NOx over V2O5-MoO3 (WO3)/TiO2 catalysts. Chemical Engineering Journal 435 (2022): 134914.

27. Wu, Peng, et al. Acid-activated layered δ-MnO2 promotes VOCs combustion. Applied Surface Science 574 (2022): 151707.

28. Peng, Ruosi, et al. The lanthanide do** effect on toluene catalytic oxidation over Pt/CeO2 catalyst. Journal of colloid and interface science 614 (2022): 33-46.

29. Chen, Longwen, et al. Porous stainless-steel fibers supported CuCeFeOx/Zeolite catalysts for the enhanced CO oxidation: Experimental and kinetic studies. Chemosphere 291 (2022): 132778.

Wu, Kang, et al. Tuning the local electronic structure of SrTiO3 catalysts to boost plasma-catalytic interfacial synergy. Journal of Hazardous Materials 428 (2022): 128172.