陆小军，博士，教授，博士生导师

地址：湖北省武汉东湖新技术开发区光谷一路206号武汉工程大学化工与制药学院

邮编：430073

电话：027-87194980

电子邮箱: xiaojunlu@wit.edu.cn

教育背景

2007.01-2011.11，南非金山大学（University of the Witwatersrand）化学工程 博士

2003.09-2006.03，华东理工大学，化学工艺，硕士

1998.09-2003.06，常州大学，化学工程与工艺，学士

工作履历

2020.06至今，武汉工程大学化工与制药学院，教授

2017.10-2020.05，生物质热化学技术国家重点实验室，副主任（兼）

2017.05-2020.05，武汉凯迪工程技术研究总院，副首席科学家

2013.03-2018.01，南非大学科学工程与技术学院，高级研究员、副教授

2012.01-2013.02，南非金山大学材料与过程合成中心，博士后

研究领域

反应工程，非均相催化，能源化工，合成气转化，CO2转化利用，生物质能源。

兼具石油化工和煤化工教育、科研背景，从事CO、CO2加氢催化转化制取油品与化学品过程中催化剂和反应体系的研究，致力于生物质等分散含碳资源高效转化利用和传统能源与可再生能源融合发展技术的开发。

团队

团队共有4名老师，其中教授1名，青年教师3名；另有国外合作导师2名，其中美国罗格斯大学1名，南非大学1名。诚邀优秀博士、博士后加入课题组。

基金

2022-2024，科技部政府间国际科技创新合作重点专项，太阳能光热还原二氧化碳生产清洁燃料；2016-2018，南非国家科研基金（NRF），Environmentally and User Friendly Fuels from Underutilized Resources and Waste；2023-2025，湖北省“科技人才服务企业”项目。

主持或重点参与了以下项目

湖北海力氯乙烯合成催化剂研发；上海浦景化工丙烯酸酯类衍生物催化剂研发；湖北浠水蓝天联合气体有限公司三氯氢硅合成技术开发；湖北安耐吉环保科技有限公司技术咨询（科技副总）；武汉凯迪生物质为原料油、醇联产技术开发；南非大学城市垃圾制油小型示范项目；美国休斯顿（Liberty GTL）3000桶/天天然气制油项目；陕西宝鸡煤制油中试项目。

学术荣誉

入选湖北省“百人计划”创新人才项目；获南非青年学者评级。

论文(部分)

1. Liu Y.; He, C.; Jiang X.; Zhang R.; Liu X.; Hildebrandt D. Lu X. Fischer-Tropsch Synthesis to a-Olefins with Low CO₂ Selectivity on a Co₂C Catalyst, Chemical Engineering Journal, 2024, 479, 147927.

2. He, C.; Lu, X.; Liu, Y.; Yan, Z.; Zhang, R.; Liu, X. Stability enhancement for silver catalyst in ethylene epoxidation by support treatment, Catalysis Communications, 2023, 178, 106669.

3. Tang, Y.; Liu, Y.; Chen, J.; He, C.; Lu, X.; Zhang, R.; Liu, X. Review of CO2 selectivity and its control in the Fischer Tropsch Synthesis to value-added chemicals, React. Chem. Eng., 2023, 8, 122.

4. Chang J.; Zhang, Y.; Lu, X.; Yao, Y.; Liu, X.; Hildebrandt, D. Insight into the Role of Co2C Supported on Reduced Graphene Oxide in Fischer-Tropsch Synthesis and Ethene Hydroformylation, Applied Catalysis A: General, 2021, 614, 118050.

5. Zhang, Y.; Yao, Y.; Chang, J.; Lu, X.; Liu, X.; Hildebrandt, D. Fischer–Tropsch synthesis with ethene co-feeding: Experimental evidence of the CO-insertion mechanism at low temperature, AIChE Journal, 2020, 66, 17029.

6. Adeleke, A.A.; Liu, X.; Lu, X.; Moyo, M.; Hildebrandt, D. Cobalt Hybrid Catalysts in Fischer-Tropsch Synthesis. Reviews in Chemical Engineering, 2020, 36, 437-457.

7. Seadira, T.; Sadanandam, G.; Ntho, T.A.; Lu, X.; Masuku, C.M.; Scurrell, M. Hydrogen Production from Glycerol Reforming: Conventional and Green Production. Reviews in Chemical Engineering, 2018, 34, 695-726.

8. Muvhiiwa, R. F.; Lu, X.; Hildebrandt, D.; Glasser, D.; Matambo, T. Applying Thermodynamics to Digestion/Gasification Processes: The Attainable Region Approach. Journal of Thermal Analysis and Calorimetry, 2018, 131, 25-36.

9. Gorimbo, J.; Muleja, A.; Lu, X.; Yao, Y.; Liu, X.; Hildebrandt, D.; Glasser, D. Lu Plot and Yao Plot: Models To Analyze Product Distribution of Long-Term Gas-Phase Fischer–Tropsch Synthesis Experimental Data on an Iron Catalyst. Energy Fuels, 2017, 31, 5682–5690.

10. Lu, X.; Zhu, X.; Masuku, C.M.; Hildebrandt, D.; Glasser, D. A Study of the Fischer–Tropsch Synthesis in a Batch Reactor: Rate, Phase of Water, and Catalyst Oxidation. Energy Fuels, 2017, 31, 7405–7412.

11. Gorimbo J. Lu, X.; Liu, X.; Yao, Y.; Hildebrandt, D.; Glasser, D. Low Pressure Fischer-Tropsch Synthesis: in-situ Oxidative Regeneration of Iron Catalysts. Industrial & Engineering Chemistry Research 2017, 56, 4267-4274.

12. Gorimbo J. Lu, X. Hildebrandt, D.; Glasser, D. A long term study of the gas phase Low pressure Fischer-Tropsch products when reducing an iron catalyst with three different reducing gases. Applied Catalysis A 2017, 534, 1-11.

13. Lu, X.; Hildebrandt, D.; Glasser, D. Distribution between C₂ and C₃ in low temperature Fischer–Tropsch synthesis over a TiO₂-supported cobalt catalyst. Applied Catalysis A 2015, 506, 67-76.

14. Masuku, C. M.; Lu, X.; Hildebrandt, D.; Glasser, D. Reactive distillation in conventional Fischer-Tropsch reactors. Fuel Processing Technology 2015, 130, 54–61.

15. Zhu, X.; Lu, X.; Liu, X.; Hildebrandt, D.; Glasser, D. Heat Transfer Study with and without Fischer-Tropsch Reaction in a Fixed bed Reactor with TiO₂, SiO₂, and SiC Supported Cobalt Catalysts. Chemical Engineering Journal 2014, 247, 75-84.

16. Lu, X.; Hildebrandt, D.; Liu, X.; Glasser, D. A Thermodynamic Approach to Olefin Product Distribution in Fischer−Tropsch Synthesis. Industrial & Engineering Chemistry Research 2012, 51, 16544–16551.

17. Glasser, D.; Hildebrandt, D.; Liu, X.; Lu, X.; Masuku, C.M. Recent advances in understanding the Fischer–Tropsch synthesis (FTS) reaction. Current Opinion in Chemical Engineering 2012, 1, 296–362.

18. Lu, X.; Zhu, X.; Hildebrandt, D.; Liu, X.; Glasser, D. A new way to look at FTS using flushing experiments. Industrial & Engineering Chemistry Research 2011, 50, 4359–4365.

19. Lu, X.; Hildebrandt, D.; Liu, X.; Glasser, D. Making Sense of the Fischer-Tropsch Synthesis Reaction: Start-up. Industrial & Engineering Chemistry Research 2010, 49, 9753–9758.

20. Zhu, X.; Lu, X.; Liu, X.; Hildebrandt, D.; Glasser, D. Study of Radial Heat Transfer in a Tubular Fischer-Tropsch Synthesis Reactor. Industrial & Engineering Chemistry Research 2010, 49, 10682–10688.

专著

1. Chemicals and fuels from Biomass via Fischer-Tropsch Synthesis: A Route to Sustainability, 2022, ISBN: 978-1-83916-393-7, Publisher: RSC.