男,副教授,硕士生导师,1992年生,河南郑州人,动力工程及工程热物理(学硕),能源动力(专硕)硕士生导师,2020年毕业于浙江大学材料学院获工学博士学位,2020年7月起在江苏科技大学能动学院工作。
江苏科技大学“深蓝杰出人才”,入选2023年镇江市青年科技人才托举工程,入选2021年度江苏省“双创博士”,主持国家自然科学基金青年基金一项,江苏省基础科研项目(青年基金)一项,江苏科技大学科研启动基金一项。获评江苏科技大学2021-2022学年优秀教师称号,获评2021年度能源与动力学院青年教师教学竞赛一等奖,2021年度江苏科技大学青年教师教学竞赛三等奖。
本人研究方向为轻质金属基固态制储氢材料的放氢与再吸氢性能调控,目前已在国内外知名学术期刊Chemical Engineering Journal, Journal of Materials Chemistry A, ACS Applied Energy Materials, International Journal of Hydrogen Energy,Chinese Journal of Chemical Engineering等刊物以第一(通讯)作者发表学术论文12篇,影响因子总和>100。
欢迎对固态储氢、制氢材料感兴趣的同学来本课题组学习!
学术成果:
Z. Zhang, D. Q. Gao, J. G. Zheng(corresponding author), A. Xia, Q. B. Zhang, L. Wang, L. T. Zhang,Heterostructured VF4@Ti3C2 catalyst improving reversible hydrogen storage properties of Mg(BH4)2, Chemical Engineering Journal, 2023, 460: 141690.
C. G. Yan, X. Lu, J. G. Zheng(corresponding author), Y. Zhang, Q. N. Wu, F. Y. Wu, L. T. Zhang, Dual-cation K2TaF7 catalyst improves high-capacity hydrogen storage behavior of MgH2, International Journal of Hydrogen Energy, 2023, 48(15):6023-6033.
Y. Zhang, J. G. Zheng(corresponding author), Z. Y. Lu, M. C. Song, J. H. He, F. Y. Wu, L. T. Zhang, Boosting the hydrogen storage performance of magnesium hydride with metal organic framework-derived Cobalt@Nickel oxide bimetallic catalyst, Chinese Journal of Chemical Engineering, 2022, 52: 161-171.
J. G. Zheng, M. J. Liu, F. Y. Wu, L. T. Zhang, Enabling easy and efficient hydrogen release below 80 °C from NaBH4 with multi-hydroxyl xylitol, International Journal of Hydrogen Energy, 2021, 46: 28156-28165.
J. G. Zheng, X. C. Wang, X. Z. Xiao, H. Cheng, L. T. Zhang, L. X. Chen, Improved reversible dehydrogenation properties of Mg(BH4)2 catalyzed by dual-cation transition metal fluorides K2TiF6 and K2NbF7, Chemical Engineering Journal, 2021, 412: 128738.
J. G. Zheng, Z. D. Yao, X. Z. Xiao, X. C. Wang, J. H. He, M. Chen, H. Cheng, L. T. Zhang, L. X. Chen, Enhanced hydrogen storage properties of high-loading nanoconfined LiBH4-Mg(BH4)2 composites with porous hollow carbon nanospheres, International Journal of Hydrogen Energy, 2021, 46(1):852-864.
J. G. Zheng, H. Cheng, X. C. Wang, M. Chen, X. Z. Xiao and L. X. Chen, LiAlH4 as a “Microlighter” on the Fluorographite Surface Triggering the Dehydrogenation of Mg(BH4)2: Toward More than 7 wt % Hydrogen Release below 70 °C. ACS Applied Energy Materials, 2020, 3, 3033-3041.
J. G. Zheng, H. Cheng, X. Z. Xiao, M. Chen and L. X. Chen, Enhanced low temperature hydrogen desorption properties and mechanism of Mg(BH4)2 composited with 2D MXene. International Journal of Hydrogen Energy, 2019, 44, 24292-24300.
J. G. Zheng, X. Z. Xiao, L. T. Zhang, S. Q. Li, H. W. Ge and L. X. Chen, Facile synthesis of bowl-like 3D Mg(BH4)2-NaBH4-fluorographene composite with unexpected superior dehydrogenation performances. Journal of Materials Chemistry A, 2017, 20, 9723-9732.
J. G. Zheng, X. Z. Xiao, L. T. Zhang, Y. He, S. Q. Li, H. W. Ge and L. X. Chen, Study on the dehydrogenation properties and reversibility of Mg(BH4)2-AlH3 composite under moderate conditions. International Journal of Hydrogen Energy, 2017, 42, 8050-8056.
J. G. Zheng, X. Z. Xiao, Y. He, M. Chen, M. J. Liu, S. Q. Li and L. X. Chen, Enhanced reversible hydrogen desorption properties and mechanism of Mg(BH4)2-AlH3-LiH composite. Journal of Alloys and Compounds, 2018, 762, 548-554.
H. Cheng, J. G. Zheng(co-author), X. Z. Xiao, X. C. Wang, S. Q. Li and L. X. Chen, Ultra-fast dehydrogenation behavior at low temperature of LiAlH4 modified by fluorographite. International Journal of Hydrogen Energy, 2020, in press.
L. T. Zhang, J. G. Zheng(co-author), X. Z. Xiao, X. C. Wang, X. Huang, M. J. Liu, Q. D. Wang and L. X. Chen, A new strategy to remarkably improve the low-temperature reversible hydrogen desorption performances of LiBH4 by compositing with fluorographene. International Journal of Hydrogen Energy, 2017, 42, 20046-20055.
L. T. Zhang, J. G. Zheng(co-author), X. Z. Xiao, X. L. Fan, X. Huang, X. L. Yang and L. X. Chen, Enhanced hydrogen storage properties of a dualcation (Li+, Mg2+) borohydride and its dehydrogenation mechanism. RSC Advances, 2017, 7, 36852-36859.