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[3]Yuan, Yongning; Yuan, Nini; Guo, Tuo; Bai, Hongcun; Xia, Hongqiang; Ren, Yanjiao; Guo, Qingjie*. Density functional theory study on the reaction mechanism of Ni+‑catalysed cyclohexane dehydrogenation. STRUCTURAL CHEMISTRY ,2022,33, 721–731.

[4]Haichuan Li,Ziheng Han,Chenye Hu,Jingjing Ma *, Qingjie Guo *. Transformation and Migrant Mechanism of Sulfur and Nitrogen during Chemical Looping Combustion with CuFe2O4. ATMOSPHERE , 2022, 13,(5):786.

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[7]Dongyan Xu, Yan Zhang, Qingjie Guo, Research progress on catalysts for hydrogen generation through sodium borohydride alcoholysis. International Journal of Hydrogen Energy,2022,47(9): 5929-5946.

[8]Zhiwen Xia, Feng Wang, Zhao Ma, Ping Li, Changzong Du, Haoyong Kan, Qingjie Guo, Depositional characteristics of Ningdong coal under a reducing atmosphere, Can. J. Chem. Eng. 2022, 1. https://doi.org/10.1002/cjce.24334.

[9] Zhao Yanling, Jia Guangchao, Shang Yili, Zhao Peitao, Cui Xin, Guo Qingjie*. Chlorine migration during hydrothermal carbonization of recycled paper wastes and fuel performance of hydrochar. Process Safety and Environmental Protection. 2022; 158:495.

[10]Zhao, P. T.; Lin, C. J.; Li, Y. L.; Zhang, J.; Huang, N.; Cui, X.; Liu, F.; Guo, Q. J*., Combustion and slagging characteristics of hydrochar derived from the co-hydrothermal carbonization of PVC and alkali coal. Energy 2022, 244.

[11]Wan, Z. X.; Duan, L. Y.; Hu, X. D.; Li, X. L.; Fang, L.; Guo, Q. J*.; Sun, D. S., Removal of mercury from flue gas using coal gasification slag. Fuel Process. Technol. 2022, 231.

[12]Yuan, N.; Han, Z.; Guo, Q. J*.; Jian, H.; Ma, J.; Bai, H., Chemical looping combustion characteristics and kinetic behaviour of Sr-doped perovskite-type CaFeO3 oxygen carriers: theoretical and experimental investigations. The Canadian Journal of Chemical Engineering 2022,

[13] Tian, W. G.; Wang, Y. X.; Hao, J.; Guo, T.; Wang, X.; Xiang, X. J.; Guo, Q. J.*, Amine-Modified Biochar for the Efficient Adsorption of Carbon Dioxide in Flue Gas. Atmosphere 2022, 13 (4).

[14] Li, H. C.; Han, Z. H.; Hu, C. Y.; Ma, J. J.; Guo, Q. J*., Transformation and Migrant Mechanism of Sulfur and Nitrogen during Chemical Looping Combustion with CuFe2O4. Atmosphere 2022, 13 (5).

[15] Hou, Y. H.; Wang, X. Y.; Chen, M.; Gao, X. Y.; Liu, Y. Z.; Guo, Q. J*., Sr1-xKxFeO3 Perovskite Catalysts with Enhanced RWGS Reactivity for CO2 Hydrogenation to Light Olefins. Atmosphere 2022, 13 (5).

[16]An, M.; Yuan, N.; Guo, Q. J*; Wei, X., Role of CuFe2O4 in elemental mercury adsorption and oxidation on modified bentonite for coal gasification. Fuel 2022, 328, 125231.

[17]Cui, Z.; Sun, S.; Zhang, H.; Liu, B.; Tian, W.; Guo, Q. J*, Comprehensive optimization of coal chemical looping gasification process for low CO2 emission based on multi-scale simulation coupled experiment. Fuel 2022, 324, 124464.

[18]Yang, J.; Zhu, P.; Meng, F.; Guo, Q. J*; He, T.; Yang, Z.; Qu, W.; Li, H., Charge distribution modulation and morphology controlling of copper selenide for an enhanced elemental mercury adsorption activity in flue gas. Chemical Engineering Journal. 2022, 442, 136145.

[19]Tian, B.; Zhao, W.; Guo, Q. J*; Tian, Y., A comprehensive understanding of synergetic effect and volatile interaction mechanisms during co-pyrolysis of rice husk and different rank coals. Energy 2022, 254, 124388.

[20] Li, H. L.; Yang, J. P.; Zhu, P. L.; Meng, F. Y.; Guo, Q. J*.; He, T.; Yang, Z. Q.; Qu, W. Q., Charge distribution modulation and morphology controlling of copper selenide for an enhanced elemental mercury adsorption activity in flue gas. Chemical Engineering Journal. 2022, 442.

[21] Li, D. Y.; Xu, R. D.; Wong, R. J.; Zhu, X.; Tian, D.; Jiang, L.; Guo, Q. J.*; Bai, H. C.; Huang, L. A.; Liu, W.; Wang, H.; Li, K. Z., Suppressing byproduct formation for high selective CO2 reduction over optimized Ni/TiO2 based catalysts. Journal of Energy Chemistry 2022, 72, 465-478.

[22] Chen, Q.; Guo, Q. J*; Zhang, W.; Wong, P. K. J.; Huang, Z. C.; Kou, Z. X.; Du, J.; Zeng, Z. M.; Zhai, Y., Programmable Gilbert Damping in Py/Cu/Fe-Co-Tb Structures with Dynamic Interlayer Coupling. Physical Review Applied 2022, 17 (3).

[23]Huang, Z. C.; Liu, W. Q.; Liang, J.; Guo, Q. J*; Zhai, Y.; Xu, Y. B., Spin transport in epitaxial Fe3O4/GaAs lateral structured devices. Chinese Physics B 2022, 31 (6).

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[25]Xu, D. Y.; Zhang, Y.; Guo, Q. J*, Research progress on catalysts for hydrogen generation through sodium borohydride alcoholysis. International Journal of Hydrogen Energy 2022, 47 (9), 5929-5946.

[26] Qian, Y.; Su, W. Y.; Li, L.; Zhao, R. M.; Fu, H. Y.; Li, J. Y.; Zhang, P. D.; Guo, Q. J*; Ma, J. J., Cooperative Effect of ZIF-67-Derived Hollow NiCo-LDH and MoS2 on Enhancing the Flame Retardancy of Thermoplastic Polyurethane. Polymers 2022, 14 (11).

[27] Li, S. Q.; Zhu, X. D.; Li, L.; Qian, Y.; Guo, Q. J*; Ma, J. J., Synthesis of LDHs Based on Fly-Ash and Its Influence on the Flame Retardant Properties of EVA/LDHs Composites. Polymers 2022, 14 (13).

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[29]Zhao, Y.; Wang, L. D.; Xue, J. S.; Zhang, Q.; Tian, Y. F.; Yan, S. S.; Bai, L. H.; Harder, M.; Guo, Q. J*; Zhai, Y., Measuring the magnon phase in a hybrid magnon-photon system. Physical Review B 2022, 105 (17).

[30]Wong, K. C.; Goh, P. S.; Ismail, A. F.; Kang, H. S.; Guo, Q. J*; Jiang, X. X.; Ma, J. J., The State-of-the-Art Functionalized Nanomaterials for Carbon Dioxide Separation Membrane. Membranes 2022, 12 (2).

[31]Zhou, H. T.; Ye, Y. X.; Tan, Y. F.; Zhu, K. L.; Liu, X. M.; Tian, H. J.; Guo, Q. J*; Wang, L. Y.; Zhao, S. J.; Liu, Y., Supported Liquid Membranes Based on Bifunctional Ionic Liquids for Selective Recovery of Gallium. Membranes 2022, 12 (4).

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[33]Niu, Y. J.; Liu, X. M.; Wang, L. Y.; Guo, Q. J*; Wu, J. J., Study on the mechanism of anaerobic fluidized bed microbial fuel cell for coal chemical wastewater treatment. Bioprocess and Biosystems Engineering 2022, 45 (3), 481-492.

[34]Zhang, J. P.; Wang, Y. M.; Feng, W.; Zhang, H.; Wang, Q.; Li, H. N.; Bai, H. C.; Guo, Q. J*, Insights into the Molecular Structure of Yangchangwan Subbituminous Coal Based on the Combination of Experimental and Multi-Scale Computational Descriptions. Solid Fuel Chemistry 2022, 56 (1), 67-77.