学习及工作经历（从博士开始）：

中国科学院山西煤炭化学研究所 工学博士（1994.09-1997.08）

韩国化学研究所 KISTEP Scientist（2001.01-2002.07）

南京工业大学 教授（2003.06-2006.08）

北九州市立大学（日本）访问教授（2005.07-2005.10）

陕西师范大学 教授（2006年至今）

Educations and Work Experiences：

Ph. D., Institute of Coal Chemistry, Chinese Academy of Sciences (1997)

KISTEP Scientist, KRICT, Korea (2001.01-2002.07)

Professor, Nanjing University of Technology (2003.06-2006.08)

Visiting Professor., The University of Kitakyushu, Japan (2005.07-2005.10)

Professor, Shaanxi Normal University (2006-)

研究领域：

合成气定向催化转化

二氧化碳氧化资源化利用

重整制氢

Research Interests:

Directional Catalytic Conversion of Syngas

Recycling Using of Carbon Dioxide Oxidation

Hydrogen Production by Reforming

代表性成果（Representative Publications，包括论文、专利、著作等）

(1) Cobalt nanoparticles confined in carbon matrix for probing the size dependence in Fischer-Tropsch synthesis.

Qun-Xing Luo, Li-Peng Guo, Si-Yu Yao, Jun Bao, Zhao-Tie Liu, Zhong-Wen Liu.* Journal of Catalysis. 2019, 369, 143-156.

(2) Direct synthesis of the reduced Co-C/SiO₂ as an efficient catalyst for Fischer-Tropsch synthesis.

Yong-Hua Zhao, Chang Liu, Yong-Hong Song, Qi-Jian Zhang, Min-Li Zhu, Zhao-Tie Liu, Zhong-Wen Liu.* Industrial Engineering Chemistry Research. 2018, 57, 1137-1145.

(3) The active nature of crystal MoS₂ for conversion of sulfur-containing syngas.

Chang Liu, Xue-Ying Cui, Yong-Hong Song, Min-Li Zhu, Zhao-Tie Liu, Zhong-Wen Liu*. ChemCatChem. 2019, 11, 1112-1122.

(4) Metal-support interactions regulated via carbon coating - A case study of Co/SiO₂ for Fischer-Tropsch synthesis.

Zhong-Shan Jiang, Yong-Hua Zhao, Chuan-Feng Huang*, Yong-Hong Song, Da-Peng Li, Zhao-Tie Liu, Zhong-Wen Liu.* Fuel. 2018, 226, 213-220.

(5) V₂O₅/Ce_0.6Zr_0.4O₂-Al₂O₃ as an efficient catalyst for the oxidative dehydrogenation of ethylbenzene with CO₂.

Zhong-Wen Liu*, Chan Wang, Wei-Bin Fan, Zhao-Tie Liu, Qing-Qing Hao, Xu Long, Jian Lu, Jian-Guo Wang, Zhang-Feng Qin, Dang Sheng Su. ChemSusChem. 2011, 4, 341-345.

(6) Catalytic behavior of manganese oxides for oxidative dehydrogenation of ethylbenzene with carbon dioxide.

Kai Ren, Jian Song, Yong-Hong Song, Huan Wang, Zonghuai Liu, Zhao-Tie Liu, Jinqiang Jiang, Zhong-Wen Liu.* Journal of CO₂ Utilization. 2017, 22, 63-70.

(7) Defect-rich Ce_1-xZrxO₂ solid solutions for oxidative dehydrogenation of ethylbenzene with CO₂.

Huan Wang, Guo-Qing Yang, Yong-Hong Song, Zhao-Tie Liu, Zhong-Wen Liu.* Catalysis Today. 2019, 324, 39-48.

(8) Hydrogen production for fuel cells via steam reforming of dimethyl ether over commercial Cu/ZnO/Al2O₃ and zeolite.

Jing Li, Qi-Jian Zhang*, Xu Long, Ping Qi, Zhao-Tie Liu, Zhong-Wen Liu.* Chemical Engineering Journal. 2012, 198, 299-305.

(9) Insights into CeO₂-modified Ni–Mg–Al oxides for pressurized carbon dioxide reforming of methane.

Hua-Ping Ren, Yong-Hong Song, Wei Wang, Jian-Gang Chen, Jie Cheng, Jinqiang Jiang, Zhao-Tie Liu, Zhong-Wen Liu*, Zhengping Hao, Jian Lu.* Chemical Engineering Journal. 2015, 259, 581-593.

(10) Key factors on the pressurized tri-reforming of methane over Ni-SiO₂.

Hua-Ping Ren, Yong-Hong Song, Zhao-Tie Liu, Zhong-Wen Liu.*

in Advances in CO₂ Capture, Sequestration, and Conversion, ACS Book series 1194, Eds. by Fangming Jin, Liang-Nian He and Yun Hang Hu, American Chemical Society: Washington, DC. 2015, pp 63-70