通讯作者(*)
[1] He Taohong, Rong Shaopeng*, Ding Danni, Zhou Yu, Zhang Nan, He Weijiang. Facet-controlled synthesis of Mn3O4 nanorods for photothermal synergistic catalytic oxidation of carcinogenic airborne formaldehyde. ACS Catalysis. 2023, In Press (学科顶刊IF=13.700)
[2] Zhou Yu#, Feng Yanfang#, Xie Huifang, Lu Jingling, Ding Danni, Rong Shaopeng*. Cryptomelane nanowires for highly selective self-heating photothermal synergistic catalytic oxidation of gaseous ammonia. Applied Catalysis B: Environmental. 2023, 331, 122668. (学科顶刊IF=24.319)
[3] Zhang Nan, Weijiang He, Zeyi Cheng, Jingling Lu, Yu Zhou, Danni Ding, Shaopeng Rong*. Construction of α-MnO2/g-C3N4 Z-scheme heterojunction for photothermal synergistic catalytic decomposition of formaldehyde. Chemical Engineering Journal. 2023, 466, 143160. (IF=16.744)
[4] Zhou Yu, Rong Shaopeng*, Xie Huifang, Feng Yanfang, Ding Danni, He Weijiang, Zhang Nan, Lu Jingling. Enhancement of acidic sites in layered MnO2 for the highly efficient selective catalytic oxidation of gaseous ammonia. Journal of Environmental Chemical Engineering. 2023, 11, 109480.
[5] Ding Danni, Zhou Yu, He Taohong, Rong Shaopeng*. Facet selectively exposed α-MnO2 for complete photocatalytic oxidation of carcinogenic HCHO at ambient temperature. Chemical Engineering Journal. 2022, 431, 133737. (IF=16.744)
[6] He Taohong, Ding Danni, Zhou Yu, Rong Shaopeng*. Sites-selective nitrogen-doping α-MnO2 for catalytic oxidation of carcinogenic HCHO in indoor air. ACS ES&T Engineering. 2022, 2, 1403-1413.
[7] Zeng Xiaoshan, Shan Chuanjia, Sun Mingdi, Ding Danni, Rong Shaopeng*. Graphene enhanced α-MnO2 for photothermal catalytic decomposition of carcinogen formaldehyde. Chinese Chemical Letters. 2022, 33, 4771-4775.
[8] Zhou Yu, Wu Zhang, Ding Danni, He Taohong, Wang Bingyu, Rong Shaopeng*. Tunnel structured manganese dioxides for the gaseous ammonia adsorption and its regeneration performance. Separation and Purification Technology. 2022, 284, 120252.
[9] He Taohong, Zhou Yu, Ding Danni, Rong Shaopeng*. Engineering manganese defects in Mn3O4 for catalytic oxidation of carcinogenic formaldehyde. ACS Applied Materials & Interfaces. 2021, 13, 29664-29675. (IF=10.383)
[10] Zeng Xiaoshan, Shan Chuanjia, Sun Mingdi, He Taohong, Rong Shaopeng*. Review on manganese dioxides for catalytic decomposition of formaldehyde in indoor air. Progress in Chemistry. 2021,12,
[11] He Taohong, Shao Dadong, Zeng Xiaoshan, Rong Shaopeng*. Harvesting the vibration energy of α-MnO2 nanostructures for complete catalytic oxidation of carcinogenic airborne formaldehyde at ambient temperature. Chemosphere. 2020, 261: 127778.
[12] Rong Shaopeng, He Taohong, Zhang Pengyi. Self-assembly of MnO2 nanostructures into high purity three-dimensional framework for high efficiency formaldehyde mineralization, Applied Catalysis B: Environmental, 2020, 267: 118375. (学科顶刊IF=24.319)
[13] He Taohong, Zeng Xiaoshan, Rong Shaopeng*. The controllable synthesis of substitutional andinterstitial nitrogen-doped manganese dioxide: theeffects of doping sites on enhancing the catalyticactivity. Journal of Materials Chemistry A. 2020, 8: 8383-8396. (IF=14.511)
[14] Rong Shaopeng*, Zhang Pengyi*, Liu Fang. Scalable synthesis of water-dispersible 2D manganese dioxide monosheets. Journal of Physics: Condensed Matter. 2020, 32: 015301
[15] Rong Shaopeng, Zhang Pengyi, et al., Engineering crystal facet of α-MnO2 nanowire for highly efficient catalytic oxidation of carcinogenic airborne formaldehyde. ACS Catalysis. 8 (2018) 3435-3446. (ESI高被引论文, 学科顶刊IF=13.700)
[16] Rong Shaopeng, Zhang Pengyi, et al., MnO2 framework for instantaneous mineralization of carcinogenic airborne formaldehyde at room temperature. ACS Catalysis, 7 (2017) 1057-1067. (学科顶刊IF=13.700)
[17] Rong Shaopeng, Zhang Pengyi, et al., Potassium associated manganese vacancy in birnessitetypemanganese dioxide for airborne formaldehyde oxidation. Catalysis Science & Technology. 8(2018) 1799-1812. (封面论文)
[18] Rong Shaopeng, Zhang Pengyi, et al., Ultrathin manganese dioxide nanosheets for formaldehyde removal and regeneration performance, Chemical Engineering Journal, 306 (2016) 1172-1179. (IF=16.744)
[19] Rong Shaopeng, Sun Yabing, et al., Degradation of TAIC by water falling film dielectric barrierdischarge-Influence of radical scavengers, Journal of Hazardous Materials, 287 (2015) 317-324. (IF=14.224)
[20] Rong Shaopeng, Zhang Pengyi, et al., Room temperature synthesis of manganese oxide quantumdots and their application as a fluorescent probe for the detection of metal ions in aqueoussolution, RSC Advances, 6 (2016) 114632-114638.
[21] Rong Shaopeng, Sun Yabing, et al., Wetted-wall corona discharge induced degradation ofsulfadiazine antibiotics in aqueous solution, Journal of Chemical Technology and Biotechnology,89 (2014) 1351-1359.
[22] Rong Shaopeng, Sun Yabing, et al., Degradation of sulfadiazine antibiotics by water falling filmdielectric barrier discharge, Chinese Chemical Letters, 25 (2014) 187-192.
[23] Rong Shaopeng, Sun Yabing, et al., Dielectric barrier discharge induced degradation of diclofenacin aqueous solution. Water Science & Technology. 69 (2014) 76-83.
[24] Liu Fang, Rong Shaopeng, Zhang Pengyi, et al. One-step synthesis of nanocarbon-decorated MnO2 with superior activity for indoor formaldehyde removal at room temperature. Applied Catalysis B: Environmental, 235 (2018) 158-167. (IF=19.503)
[26] Zhu Lin, Wang Jinlong, Rong Shaopeng, et al., Cerium modified birnessite-type MnO2 for gaseous formaldehyde oxidation at low temperature, Applied Catalysis B: Environmental, 211 (2017) 212-221. (高被引论文, 学科顶刊IF=13.700)