Institute of Coal Chemistry,Chinese Academy of Sciences
Taoyuan South Road 27, Taiyuan 030001, China
Tel:0351-4040476
Email:junjieshiding@gmail.com
史俊杰,男,助理研究员。2009年于青岛农业大学获得学士学位,2009至2011年于中国海洋大学攻读硕士学位,2011年获国家留学基金委公派资助前往德国不来梅大学攻读博士学位,2017年获得博士学位(最优等 magna cum laude)。2020至2022年,美国佛罗里达大学从事博士后研究工作。
2023年加入中国科学院山西煤炭化学研究所工作。主要从事多相催化(水煤气变换,烷烃活化), 表面化学(超高真空UHV为基础的模型催化),发表论文20余篇,主要在催化,物理化学和凝聚态物理领域期刊:ACS Catal., Appl. Catal. B, Catal. Sci. Technol., PCCP, JPCC, J. Chem. Phys. J. Phys. Condens. Matter 等。
主持国家自然科学基金(青年)1项,山东省青年基金1项。获得欧盟“地平线-2020”研究与创新框架“玛丽•居里学者计划”(Marie Skłodowska Curie Individual Fellowship)人才基金资助。
一. 学习及工作经历:
2023.3 - 至今 中国科学院山西煤炭化学研究所工作。
2020.1 - 2022.12 佛罗里达大学,博士后研究员(合作导师Jason F.Weaver)。
2017.8 - 2019.12 烟台大学,讲师。
2011.10 - 2017.6 不来梅大学(德国),生物与化学学院,获得博士学位(导师Marcus Bäumer)。
2009.9 - 2011.9 中国海洋大学,攻读硕士学位。
2005.9 - 2011.7 青岛农业大学,获得学士学位
二. 研究方向
(1) 多相催化: 稀土氧化物催化,金催化,水煤气变换,烷烃活化
(2) 表面化学:单原子合金(single atom alloy)模型催化(超高真空UHV), 烷烃活化, 醇类选择性脱氢
三. 主持科研项目
(1) 山东省自然科学基金青年基金
(2) 国家自然科学基金青年基金
(3) 欧盟“地平线-2020”项目-“玛丽•居里学者计划”(21万欧元)
四.会议经历
1. 2021 年 6 月,美国 IMASC (Integrated Mesoscale Architectures for Sustainable Catalysis) 会议, Prof. Cynthia Friend(哈佛大学) 主持,美国能源部资助,口头报告:探测 Ti-Cu (111)稀合金表面 Ti金属的微观结构。
2. 2019年10月,中国 第十九届全国催化会议,重庆,口头报告:镨铈复合氧化 物负载的纳米金催化剂在水煤气变换反应中的应用。
3. 2018年7月,法国GOLD2018,巴黎,口头报告:Atomic Observation of Praseodymia-Titania Mixed Oxides Functionalized Nanoporous Gold as Stable Catalysts for Water-Gas Shift Reaction (原子层面对氧化镨-氧化钛复合金属氧 化物修饰的 多孔纳米金作为稳定催化剂用于催化水煤气变换反应中的解析)
4. 2016年9月,不来梅大学 UFT 组建 20 周年年庆,不来梅,口头报告: Nanoporous gold supported metal oxides as high performance hydrogen production catalysts (多孔纳米金负载的金属氧化物作为高效产氢催化剂)
5. 2015年8月,美国化学会第 250 届学术年会 (秋季), 波士顿, 口头报告 :Nanoporous Gold Supported Titania-Ceria Mixed Oxides as High-performance Hydrogen Production Catalyst (多孔纳米金负载的氧化钛和氧化铈混合氧化物 作为高效产氢催化剂)
6. 2014年9月,留德华人化学化工学会第 27 届学术年会,柏林,墙报:CeOx
Functionalized Nanoporous Gold inverse Catalysts for Water Gas shift(氧化铈 修饰的多 孔纳米金反相催化剂用于水煤气转化反应。
7. 2013年5月,德国本生物理化学年会,卡尔斯鲁厄,墙报:CeOx and TiOx
Functionalized Nanoporous Gold inverse Catalysts for Water Gas shift Reaction(氧化铈和氧化钛修饰的多孔纳米金反相催化剂用于水煤气转化反应)
五.发表论文
[21] Shi, J.; Ngan, H.; Sautet, P.*; Weaver, J.*, High Selectivity and Activity of Ti-Cu(111) Dilute Alloys for the Deoxygenation of Ethanol to Ethylene. ACS Catal. 2023, 13, 17, 11244–11255.
[20] Shi, J.*; Li, H.; Genest, A.; Zhao, W.; Qi, P.; Wang, T.; Rupprechter, G.*, Highperformance water gas shift induced by asymmetric oxygen vacancies: Gold clusters supported by ceria-praseodymia mixed oxides. Applied Catalysis B: Environmental. 2022, 301, 120789.
[19] Zhao, W.; Shi, J.*; Lin, M.; Sun, L.; Su, H.; Sun, X.; Murayama, T.; Qi, C.*, Praseodymia–titania mixed oxide supported gold as efficient water gas shift catalyst: modulated by the mixing ratio of oxides. RSC advances. 2022, 12, 5374.
[18] Shi, J.; Owen, C.; Ngan, H.; Qin, S.; Mehar, V.; Sautet, P.*; Weaver, J.*, Formation of a Ti–Cu(111) single atom alloy: Structure and CO binding. The Journal of Chemical Physic. 2021, 154, 234703.
[17] Shi, J.*; Li, H.; Zhao, W.; Qi, P.; Wang, H., Praseodymium hydroxide/gold-supported precursor: a new strategy for preparing stable and active catalyst for the water-gas shift reaction. Catalysis Science & Technology. 2020, 10, 7291.
[16] Shi, J.; Wittstock, A.; Mahr, C.; Murshed, M. M.; Gesing, T. M.; Rosenauer, A.; Bäumer, M.*, Nanoporous gold functionalized with praseodymia–titania mixed oxides as a stable catalyst for the water–gas shift reaction. Physical Chemistry Chemical Physics. 2019, 21 (6), 3278-3286.
[15] Shi, J.; Mahr, C.; Murshed, M. M.; Rosenauer, A.; Gesing, T. M.; Bäumer, M., Wittstock, A.*, Steam Reforming of Methanol over Nanoporous Gold/Oxide Catalysts: A Combined In-situ FTIR and Flow Reactor Study. Physical Chemistry Chemical Physics. 2017, 19, 8880-8888.
[14] Shi, J.; Mahr, C.; Murshed, M. M.; Zielasek, V.; Rosenauer, A.; Gesing, T. M.; Bäumer, M.; Wittstock, A.*, A versatile sol–gel coating for mixed oxides on nanoporous gold and their application in the water gas shift reaction. Catalysis Science & Technology. 2016, 6, 5311-5319.
[13] Shi, J.; Schaefer, A.; Wichmann, A.; Murshed, M. M.; Gesing, T. M.; Wittstock, A.*; Bäumer, M., Nanoporous Gold-Supported Ceria for the Water–Gas Shift Reaction: UHV Inspired Design for Applied Catalysis. The Journal of Physical Chemistry C. 2014, 118 (50), 29270-29277.
[12] Yu, X.; Shi, J.*; Feng, L.; Li, C.; Wang, L.*, A Three-Dimensional BiOBr/RGO Heterostructural Aerogel with Enhanced and Selective Photocatalytic Properties under Visible Light. Applied Surface Science. 2016, 396, 1775–1782.
[11] Yu, X.; Wu, P.; Qi, C.; Shi, J.*; Feng, L.; Li, C.; Wang, L.*, Ternary-component reduced graphene oxide aerogel constructed by g-C3N4/BiOBr heterojunction and graphene oxide with enhanced photocatalytic performance. Journal of Alloys and Compounds. 2017, 729, 162-170.
[10] Li, Z.; Zhang, H.; Wang, L.*; Meng, X.; Shi, J.*; Qi, C.; Zhang, Z.; Feng, L.; Li, C., 2D/2D BiOBr/Ti3C2 heterojunction with dual applications in both water detoxification and water splitting. Journal of Photochemistry and Photobiology A: Chemistry. 2020, 386, 112099.
[9] Lee, C.; Vashishtha, S.; Shariff, M.; Zou, F.; Shi, J.; Meyer, R.; Weaver, J.*, Kinetics and selectivity of methane oxidation on an IrO2(110) film. Journal of Physics: Condensed Matter. 2022, 34, 284002.
[8] Qi, S.; Lin, M.; Qi, P.*; Shi, J.; Song, G.; Fan, W.; Sui, K.*; Gao, C., Interfacial and build-in electric fields rooting in gradient polyelectrolyte hydrogel boosted heavy metal removal. Chemical Engineering Journal. 2022, 444, 136541.
[7] Qi, P.*; Zeng, J.; Tong, X.; Shi, J.; Wang, Y.; Sui, K.*, Bioinspired synthesis of fibershaped silk fibroin-ferric oxide nanohybrid for superior elimination of antimonite. Journal of Hazardous Materials. 2022, 403, 123909.
[6] Zeng, J.; Qi, P.*; Shi, J.; Pichler, T.; Wang, F.; Wang, Y.; Sui, K.*,Chitosan functionalized iron nanosheet for enhanced removal of As(III) and Sb(III): Synergistic effect and mechanism. Chemical Engineering Journal. 2020, 382, 122999.
[5] Rumancev, C.; Von Gundlach, A. R.; Baier, S.; Wittstock, A.; Shi, J.; Benzi, F.; Senkbeil, T.; Stuhr, S.; Garamusx, V. M.; Grunwaldt, J.-D.*; Rosenhahn, A.*, Morphological analysis of cerium oxide stabilized nanoporous gold catalysts by soft Xray ASAXS. RSC advances. 2017, 7, 45344-45350.
[4] Baier, S.; Wittstock, A.; Damsgaard, C.-D.; Diaz, A.; Reinhardt, J.; Benzi, F.; Shi, J.; Scherer, T.; Wang, D.; Kübel, C.; Schroer, C. G.; Grunwaldt, J.-D. *, Influence of gas atmosphere and ceria on the stability of nanoporous gold studied by environmental electron microscopy and in situ ptychography. RSC advances. 2016, 6, 83031-83043.
[3] Baier, S.; Damsgaard, C. D.; Scholz, M.; Benzi, F.; Rochet, A.; Hoppe, R.; Scherer, T.; Shi, J.; Wittstock, A.; Weinhausen, B.; Wagner, J. B.; Schroer, C. G.; Grunwaldt, J.-D.*, In situ ptychography of heterogeneous catalysts using hard X-rays: high resolution imaging at ambient pressure and elevated temperature. Microscopy and Microanalysis. 2016, 22(1):178-188.
[2] Yu, X.; Shi, J.; Wang, L.;* Wang, W.; Bian, J.; Feng, L.; Li, C., A novel Au NPsloaded MoS2/RGO composite for efficient hydrogen evolution under visible light. Materials letters. 2016, 182, 125–128.
[1] Sun, X.; Li, F.; Shi, J.; Zheng. Y.; Su, H.; Sun, L.; Peng, S.; Qi, C., * Gold nanoparticles supported on MgOx-Al2O3 composite oxide: An efficient catalyst for selective hydrogenation of acetylene. Applied Surface Science, 2019, 487, 625-633.