1.Han, D.-X.; Xin, Y.*; Jia, J.-X.; Wang, J.; Zhang, Z.-L.*. Mild thermal treatment-driven transformation of CuOx assisted with the rearrangement of Al sites in Cu-SSZ-13. Applied Catalysis O: Open. 2025, 205, 207054.
2.Han, D.-X.; Xin, Y.*; Jia, J.-X.; Wang, J.; Zhang, Z.-L.*. Acetate-assisted preparation of high-Cu-content Cu-SSZ-13 with low Si/Al ratio: distinguishing Cu species and origins. Catalysts. 2025.
3.Han, D.-X.; Han, Z.-B.*; Liu, L.-Y.*; Xin, S.-G.; Yu, Z. Improved Kaempferol Solubility via Heptakis-O-(2-hydroxypropyl)-β-cyclodextrin Complexation: A Combined Spectroscopic and Theoretical Study. International Journal of Molecular Sciences. 2024, 25, 12492.
4.Han, D.-X.; Han, Z.-B; Liu, L.-Y.; Wang, Y.; Xin, S.-G.; Zhang, H.-B.; Yu, Z.*. Solubility Enhancement of Myricetin by Inclusion Complexation with Heptakis-O-(2-Hydroxypropyl)-β-Cyclodextrin: A Joint Experimental and Theoretical Study. International Journal of Molecular Sciences. 2020, 21, 766.
5.Han, D.-X.; Li, T.-L.; Miao, R.-D.; Wang, Y., Liu, L.-Y.; Yu, Z. Study of Solubility Enhancement of Luteolin by Heptakis-(2, 6-dimethyl)-β-cyclodextrin. Chin J Mod Appl Pharm, 2020, 37(22): 2747-2751.
6.Yu, Z.; Han, D.-X; Li, H.-Y.; Xin, S.-G.; Zhang, H.-B. Mechanistic study of solubility enhancement of camptothecin by heptakis-(2,6-dimethyl)-β-cyclodextrin. Journal of Shenyang Normal University (Natural Science Edition). 2020, 38(02), 97.
7.Zhang, N.-N.; Xin, Y.*, Li, R.-R; Han, D.-X.; Jia, J.-X.; Li, Q.; Wang, J.; Zhang, Z.-L.; Pd/SAPO-34 passive NOx adsorbers: Stable Pd ion adsorption sites in six-member rings. Materials Research Express, 2021, 8: 035505.
8.Xin, Y.; Cheng, L.; Lv, Y.-N.; Jia, J.-X.; Han, D.-X.; Zhang, N.-N.; Wang, J.; Zhang, Z.-L.*; Cao, X.-M.*. Experimental and theoretical insight into the facet-dependent mechanisms of the NO oxidation catalyzed by structurally diverse Mn2O3 nanocrystals, ACS Catalysis, 2022, 12, 397−410.
9.Zhu, X.-L.; Xin, Y.*; Yu, L.; Liu, S.; Han, D.-X.; Jia, J.-X.; Wang, J.; Zhang, Z.-L.*. Zeolite-based materials eliminating nitrogen oxides (NOx) and volatile organic compounds (VOCs): Advances and future perspectives, Catalysis Science & Technology, 2024, 14, 4756–4774.
10.Li, P.; Xin, Y.*; Zhang, H.-X.; Yang, F.-Z.; Tang, A.-H.; Han, D.-X.; Jia, J.-X.; Wang, J.; Li, Z.-G.; Zhang, Z.-L. Recent progress in performance optimization of Cu-SSZ-13 catalyst for selective catalytic reduction of NOx. Frontiers in Chemistry, 2022, 10, 1033255.
11.Xin, Y.; Zhang, H.-X.; Li, P.; Qu, N.-N.; Tang, A.-H.; Yang, F.-Z.; Han, D.-X.; Jia, J.-X.; Wang, J.; Zheng, L.-R.; Zhang, Z.-L.*. Low-content and highly effective zoned Rh and Pd three-way catalysts for gasoline particulate filter potentially meeting Euro 7. Journal of Rare Earths. 2023, 41(6), 905-916.
12.Yang, F.-Z.; Xin, Y.*; Zhu, X.-L.; Tang, A.-H.; Yu, L.; Han, D.-X.; Jia, J.-X.; Lu, Y.-N.; Zhang, Z.-L.*. Hard Template-Assisted Trans-Crystallization Synthesis of Hierarchically Porous Cu-SSZ-13 with Enhanced NH3-SCR Performance. Catalysts. 2023, 13(8), 1217.
13.Tang, A.-H.; Yang, F.-Z.; Xin, Y.*; Zhu, X.-L.; Yu, L.; Liu, S.; Han, D.-X.; Jia, J.-X.; Lu, Y.-N.; Li, Z.-G.; Zhang, Z.-L.*. Enhanced Low-Temperature Activity and Hydrothermal Stability of Ce-Mn Oxide-Modified Cu-SSZ-39 Catalysts for NH3-SCR of NOx. Catalysts. 2024, 14(1), 10.
Patents (with a total of 10 patent applications)
1.Zhang, Z.-L.; Han, D.-X.; Xin, Y.; Jia, J.-X.; Yang, F.-Z.; Wang, J. A Gradient Loading Method for Preparing Cu-Based Small-Pore Zeolite Catalysts, the Obtained Products and Applications; Authorized, Patent No.: ZL 2022 1 1692388.7
2.Zhang, Z.-L.; Han, D.-X.; Xin, Y.; Jia, J.-X.; Yang, F.-Z.; Wang, J. A High-Performance Cu-Based Small-Pore Zeolite Catalyst Preparation Method, the Obtained Product and Applications; Authorized, Patent No.: ZL 2023 1 0459042.0
3.Zhang, Z.-L.; Han, D.-X.; Xin, Y.; Jia, J.-X.; Yang, F.-Z.; Wang, J. An Ion Trapping Method for Preparing Metal-Based Small-Pore Zeolites, the Obtained Products and Applications; Authorized, Patent No.: ZL 2023 1 0379072.0
4.Xue, J.-Q.; Xin, Y.; Han, D.-X.; Jia, J.-X. A High-Salinity Water Treatment Oxidation Reactor; Authorized, Patent No.: ZL 202320247864.8
5.Xue, J.-Q.; Xin, Y.; Han, D.-X.; Jia, J.-X. An Automatic Dosing Mechanism for High-Salinity Water Treatment Equipment; Authorized, Patent No.: ZL 202320247863.3
6.Xue, J.-Q.; Xin, Y.; Han, D.-X.; Jia, J.-X. A High-Salinity Water Treatment Device Based on Distillation Technology; Authorized, Patent No.: ZL 202320247808.4
7.Zhang, Z.-L.; Jia, J.-X.; Xin, Y.; Han, D.-X.; Li, P.; Zhang, H.-X.; Yang, F.-Z; Tang, A. H.;, Wang, J. A Method for Improving the Hydrothermal Stability of Metal-Based Small-Pore Zeolites, the Obtained Products and Applications; Authorized, Patent No.: ZL 202210696992.0
8.Zhang, Z.-L.; Jia, J.-X.; Xin, Y.; Han, D.-X.; Wang, J.; Lu, Y.-N.; Liu, G.-H; A Preparation Method for High-Performance Al-Rich Cu-SSZ-39 Zeolite and Its Application in NH3-SCR; Authorized, Patent No.: ZL 202410324092.2
9.Xin, Y.; Zhang, H.-X.; Zhang, Z.-L.; Li, P.; Zhang, Z.-H.; Han, D.-X.; Jia, J.-X.; Tang, A.-H.; Yang, F.-Z.; Wang, J.; Zhu, X.-X.; Zhang, R.; Tang, M.; Zhang, Y.-F. An Electrified SCR Catalyst for Low-Temperature High-Efficiency Nitrogen Oxide Removal, Its Preparation Method and Application; Authorized, Patent No.: ZL 202210124132.X
10.Xin, Y.; Li, P.; Zhang, Z.-L.; Zhang, H.-X.; Jia, J.-X.; Han, D.-X.; Yang, F.-Z.; Tang, A.-H.; Wang, J. A Preparation Method for SSZ-13 Zeolite with Hierarchical Pore Structure, the Obtained Product and Applications; Authorized, Patent No.: ZL 202210512677.8
Conference paper
1.Han, D.-X.; Jia, J.-X.; Xin, Y.; Wang, J.; Zhang, Z.-L*. Preparation of Cu-SSZ-13 Catalyst by Ion Trapping Method and Its NH3-SCR Performance. Excellent Poster. The 13th National Conference on Environmental Catalysis and Environmental Materials, Dalian.
2.Han, D.-X.; Jia, J.-X.; Xin, Y.; Wang, J.; Zhang, Z.-L*. Preparation Method of High-Performance Cu-SSZ-13 Small-Pore Zeolite Catalyst. The 12th National Conference on Environmental Chemistry, Wuhan.