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.