1. 木质纤维素催化转化到小分子多元醇

主要研究不同结构木质纤维素高选择性催化转化的一般规律，揭示不同组成结构、生物质类型、杂质等因素对纤维素催化转化和催化剂的影响，建立生物质全组分利用的环境友好途径。

2. 乙醇催化转化到高附加值化学品

以生物乙醇为平台分子，在探索新型催化剂体系的基础上，实现乙醇到丁醇、乙醛等产物的选择性调变，建立乙醇催化转化中-OH和-H选择性活化的一般规律和C-C偶联的主要手段。

3.选择性加氢催化剂的研制与应用

    针对重要生物质催化转化反应，开发新型加氢催化剂体系。重点利用碳化钨、碳化钼等碳化物的类贵金属催化特性，采用第二金属调变过渡金属碳化物电子性质，实现生物质平台化合物催化转化中产物的选择性调控。

   

081705-工业催化

工业催化

2017-11--2018-05   华盛顿州立大学   访问学者
2008-09--2011-11   大连化学物理研究所   博士
2005-07--2008-07   大连理工大学   硕士
2001-09--2005-07   东北石油大学   学士

   

2016-06~现在, 大连化学物理研究所, 副研究员
2012-01~2016-06,大连化学物理研究所, 助理研究员

代表性专利如下：

1.          庞纪峰，张涛，郑明远，姜宇，王爱琴，近或超临界水条件下碳水化合物制小分子多元醇的方法，授权号：CN 103420787 B，授权日期：2015.01.28。

2.          庞纪峰，张涛，郑明远，姜宇，王爱琴，一种吸附剂在碳水化合物制小分子醇反应中的应用，授权号：CN 103420799 B，授权日期：2015.04.01。

3.          庞纪峰，郑明远，张涛，姜宇，孙睿岩，王爱琴，王晓东，一种锡基催化剂的制备方法及锡基催化剂和应用，授权号：CN106861747B，授权日期：2020.4.7。

4.          庞纪峰，郑明远，张涛，王爱琴，王晓东，一种复杂反应底物中回收钨基催化剂的方法，授权号：CN106868305B，授权日期：2019.5.28。

5.          Tao Zhang, Jifeng Pang, Mingyuan Zheng, Yu Jiang, Aiqin Wang, Process for highly efficient catalytic conversion of cellulose raw material to diol, Patent NO.: US 9085505 B2, Date of Patent: 2015.7.21.

6.       张涛，庞纪峰，郑明远，姜宇，王爱琴，一种高效催化转化纤维素类原料到二元醇的方法，授权号：CN 103420798 B，授权日期：2015.12.09。                           

7.          张涛，庞纪峰，郑明远，王爱琴，一种炭载镍基催化剂的制备和应用，授权号：CN 102671672 B；授权日期：2014.7.23。

8.          张涛，庞纪峰，郑明远，姜宇，王爱琴，一种催化转化芒草制备二元醇的方法，授权号：CN 104098440 B；授权日期：2016.02.10

9.          张涛，郑明远，庞纪峰，姜宇，李宁，王爱琴，王晓东，一种抑制环醚醇生成的纤维素催化转化制乙二醇的方法，授权号：CN 102731253 B，授权日期：2014.10.22。

10.      郑明远，张涛，庞纪峰，姜宇，王爱琴，王晓东，一种以玉米秸秆和/或高粱秸秆为原料制备乙二醇的方法，授权号：CN 102731254 B，授权日期：2015.02.04。

11.      郑明远，张涛，庞纪峰，姜宇，王爱琴，王晓东，一种以玉米芯为原料制备乙二醇的方法，授权号：CN 102731255 B，授权日期：2014.10.22。

12.    郑明远，张涛，庞纪峰，姜宇，王爱琴，一种碳水化合物内循环催化转化制备低碳多元醇的方法，授权号：CN 102731258 B，授权日期：2014.07.23。

13.      郑明远，张涛，庞纪峰，姜宇，王爱琴，一种木质纤维素生物质综合利用制备能源化学品的方法，授权号：CN104694671B，授权日期：2018.2.13。

14.      姜宇，张涛，郑明远，庞纪峰，王爱琴，一种低沸点有机相中由碳水化合物生产二元醇的方法，授权号：CN103420795B，授权日期：2015.11.4。

15.      邰志军，张涛，郑明远，庞纪峰，姜宇，张军营，王爱琴，一种含糖化合物选择性制丙二醇的方法，授权号：CN102731257B，授权日期：2015.12.16。

16.      张军营，张涛，郑明远，庞纪峰，姜宇，邰志军，王爱琴，一种高金属负载量催化剂用于碳水化合物制乙二醇的方法，授权号：CN 103420796 B，授权日期：2015.05.20。

（1） 辽宁省自然科学学术成果奖, 二等奖, 省级, 2018

[1] 庞纪峰, 郑明远, 王婵, 李新生, 姜宇, 赵宇, 张涛. 一种乙醇高能化利用的方法. CN: CN111217673B, 2022-03-22.
[2] 庞纪峰, 郑明远, 姜宇, 赵宇, 张涛. 一种乙醇脱氢制备乙醛催化剂的制备方法与应用. CN: CN114054079A, 2022-02-18.
[3] 庞纪峰, 郑明远, 李新生, 李显泉, 张涛. 一种合金单原子催化剂的制备方法和应用. CN: CN114054023A, 2022-02-18.
[4] 郑明远, 李显泉, 庞纪峰, 张涛. 一种MFI分子筛纳米片负载的锆基催化剂及其在制备丁二烯反应中的应用. CN: CN112958146A, 2021-06-15.
[5] 庞纪峰, 王祉诺, 郑明远, 张涛. 一种乙醇转化制备C4-C8高碳醇的催化剂及其制备方法与应用. CN: CN110711578B, 2021-04-02.
[6] 庞纪峰, 郑明远, 姜宇, 赵宇, 张涛. 一种水滑石基催化剂在高浓度糖转化到1,2-丙二醇中的应用. CN: CN110711588B, 2021-02-12.
[7] 庞纪峰, 郑明远, 张涛, 李新生, 赵宇, 姜宇, 王爱琴. 一种木质纤维素高效分离并实现全组分利用的方法. CN: CN109896922A, 2019-06-18.
[8] 庞纪峰, 郑明远, 张涛, 李新生, 王婵, 姜宇, 王爱琴. 一种双组分催化剂上乙醇转化制备高碳伯醇的方法. CN: CN109896923A, 2019-06-18.
[9] 王爱琴, 徐刚, 张涛, 郑明远, 张涛, 王华. 一种碳水化合物制备乙醇酸酯的方法. CN: CN108129320A, 2018-06-08.
[10] 王爱琴, 徐刚, 张涛, 郑明远, 庞纪峰, 王华. 一种生物质制备1,1,2-三甲氧基乙烷的方法. CN: CN108101752A, 2018-06-01.
[11] 余葆如, 钱俊, 郑明远, 周伟, 姜宇, 陈可明, 庞纪峰, 赵宇, 吴越峰, 刘应春. 一种生物质乙二醇的分离方法. CN: CN106946654A, 2017-07-14.
[12] 庞纪峰, 郑明远, 张涛, 王爱琴, 王晓东. 一种复杂反应底物中回收钨基催化剂的方法. CN: CN106868305A, 2017-06-20.
[13] 郑明远, 庞纪峰, 张涛, 王爱琴, 王晓东. 钌锡催化剂在糖类化合物催化转化制备丙二醇中的应用. CN: CN106866362A, 2017-06-20.
[14] 庞纪峰, 郑明远, 张涛, 王爱琴, 王晓东. 钨基催化剂在糖类化合物催化制低碳醇中的循环使用方法. CN: CN106866372A, 2017-06-20.
[15] 郑明远, 萧斌, 庞纪峰, 孙睿岩, 李新生, 王爱琴, 王晓东, 张涛. 一种5-羟甲基糠醛催化转化制备1,6-己二醇的方法. CN: CN106866360A, 2017-06-20.
[16] 庞纪峰, 郑明远, 张涛, 姜宇, 孙睿岩, 王爱琴, 王晓东. 一种锡基催化剂的制备方法及锡基催化剂和应用. CN: CN106861747A, 2017-06-20.
[17] 艾硕, 郑明远, 张涛, 庞纪峰, 王爱琴, 王晓东. 一种多元醇混合物的分离方法. CN: CN106866369A, 2017-06-20.
[18] 孙睿岩, 郑明远, 张涛, 庞纪峰, 姜宇, 王爱琴, 王晓东. 合金催化剂用于碳水化合物催化制备低碳二元醇的方法. CN: CN106694009A, 2017-05-24.
[19] 阿兹兰·沙阿·侯赛因, 罗傅益, 郑明远, 庞纪峰, 陶章. 含糖类的原料选择性转化为乙二醇的方法. MY: CN106573860A, 2017-04-19.
[20] 王爱琴, 徐刚, 张涛, 郑明远, 庞纪峰, 王华. 一种纤维素两步法制备乙二醇和1,2-丙二醇的方法. CN: CN106278822A, 2017-01-04.
[21] 王爱琴, 徐刚, 张涛, 郑明远, 庞纪峰, 王华. 一种纤维素两步法制备乙醇和正丙醇的方法. CN: CN106278816A, 2017-01-04.
[22] 庞纪峰, 郑明远, 姜宇, 王爱琴, 王晓东, 张涛. 一种乙醇催化转化制备高碳伯醇的方法. CN: CN105712840A, 2016-06-29.
[23] 郑明远, 赵宇, 张涛, 庞纪峰, 张涛. 一种碳水化合物制备乙醇酸酯的方法. CN: CN105622419A, 2016-06-01.
[24] 郑明远, 张涛, 宋蕾, 王华, 姜宇, 庞纪峰, 王爱琴. 一种由果糖基碳水化合物催化转化制备含氮化合物的方法. CN: CN104693128A, 2015-06-10.
[25] 张涛, 姜宇, 郑明远, 庞纪峰, 王爱琴. 一种生物质乙二醇的吸附精制方法. CN: CN104693007A, 2015-06-10.
[26] 郑明远, 张涛, 庞纪峰, 姜宇, 王爱琴. 一种木质纤维素生物质综合利用制备能源化学品的方法. CN: CN104694671A, 2015-06-10.
[27] 张涛, 萧斌, 郑明远, 庞纪峰, 姜宇, 王爱琴. 一种生物质乙二醇合成聚对苯二甲酸乙二醇酯的方法. CN: CN104418997A, 2015-03-18.
[28] 张涛, 孙睿岩, 郑明远, 庞纪峰, 姜宇, 王爱琴. 一种碳水化合物催化转化制备乙二醇的方法. CN: CN104119207A, 2014-10-29.
[29] 张涛, 庞纪峰, 郑明远, 姜宇, 王爱琴. 一种生物质乙二醇的精制方法. CN: CN104098439A, 2014-10-15.
[30] 张涛, 庞纪峰, 郑明远, 姜宇, 王爱琴. 一种催化转化芒草制备二元醇的方法. CN: CN104098440A, 2014-10-15.
[31] 张涛, 周立坤, 王爱琴, 庞纪峰, 郑明远, 李昌志. 一种以菊芋为原料直接催化转化制备1,2-丙二醇的方法. CN: CN103833513A, 2014-06-04.
[32] 张涛, 郑明远, 王爱琴, 庞纪峰, 李昌志, T·N·卡尔奈斯, J·Q·陈, J·A·科贾尔. 一种连续催化转化纤维素生产多元醇的方法. US: CN103687837A, 2014-03-26.
[33] T·N·卡尔奈斯, J·Q·陈, J·A·科贾尔, 张涛, 郑明远, 王爱琴, 庞纪峰, 李昌志. 一种伴以循环的连续催化转化纤维素类原料到多元醇的方法. US: CN103608321A, 2014-02-26.
[34] 张军营, 张涛, 郑明远, 庞纪峰, 姜宇, 邰志军, 王爱琴. 一种高金属负载量催化剂用于碳水化合物制乙二醇的方法. CN: CN103420796A, 2013-12-04.
[35] 张军营, 张涛, 郑明远, 庞纪峰, 姜宇, 邰志军, 王爱琴. 低金属负载量催化剂用于碳水化合物制备乙二醇的方法. CN: CN103420797A, 2013-12-04.
[36] 姜宇, 张涛, 郑明远, 庞纪峰, 王爱琴. 一种在两相溶剂中由碳水化合物生产小分子醇的方法. CN: CN103420788A, 2013-12-04.
[37] 庞纪峰, 张涛, 郑明远, 姜宇, 王爱琴. 一种吸附剂在碳水化合物制小分子醇反应中的应用. CN: CN103420799A, 2013-12-04.
[38] 庞纪峰, 张涛, 郑明远, 姜宇, 王爱琴. 近或超临界水条件下碳水化合物制小分子多元醇的方法. CN: CN103420787A, 2013-12-04.
[39] 姜宇, 张涛, 郑明远, 庞纪峰, 王爱琴. 一种低沸点有机相中由碳水化合物生产二元醇的方法. CN: CN103420795A, 2013-12-04.
[40] 张涛, 庞纪峰, 郑明远, 姜宇, 王爱琴. 一种高效催化转化纤维素类原料到二元醇的方法. CN: CN103420798A, 2013-12-04.
[41] 张涛, 周立坤, 王爱琴, 庞纪峰, 李昌志, 郑明远. 一种以菊芋为原料催化转化制备六元醇的方法. CN: CN102746117A, 2012-10-24.
[42] 郑明远, 张涛, 庞纪峰, 姜宇, 王爱琴. 一种碳水化合物内循环催化转化制备低碳多元醇的方法. CN: CN102731258A, 2012-10-17.
[43] 邰志军, 张涛, 郑明远, 庞纪峰, 姜宇, 张军营, 王爱琴. 一种含糖化合物选择性制丙二醇的方法. CN: CN102731257A, 2012-10-17.
[44] 郑明远, 张涛, 庞纪峰, 姜宇, 王爱琴, 王晓东. 一种以玉米秸秆和/或高粱秸秆为原料制备乙二醇的方法. CN: CN102731254A, 2012-10-17.
[45] 张涛, 郑明远, 庞纪峰, 姜宇, 李宁, 王爱琴, 王晓东. 一种抑制环醚醇生成的纤维素催化转化制乙二醇的方法. CN: CN102731253A, 2012-10-17.
[46] 郑明远, 张涛, 庞纪峰, 姜宇, 王爱琴, 王晓东. 一种以玉米芯为原料制备乙二醇的方法. CN: CN102731255A, 2012-10-17.
[47] 张涛, 郑明远, 庞纪峰, 姜宇, 李宁, 王爱琴, 王晓东. 一种抑制环醚醇生成的纤维素转化制乙二醇的方法. CN: CN102731256A, 2012-10-17.
[48] 张涛, 庞纪峰, 郑明远, 王爱琴. 一种炭载镍基催化剂的制备和应用. CN: CN102671672A, 2012-09-19.
[49] 张涛, 郑明远, 王爱琴, 纪娜, 庞纪峰, 邰志军, 周立坤, 陈经广, 王晓东. 一种多羟基化合物制乙二醇的方法. CN: CN101735014A, 2010-06-16.

第一作者和通讯文章

 第一作者

1. J. Pang, J. Li, Low thermal expansion porous SiC-WC composite ceramics, Ceram. Int., 35 (2009) 3517-3520.

2. J. Pang, A. Wang, M. Zheng, T. Zhang, Hydrolysis of cellulose into glucose over carbons sulfonated at elevated temperatures, Chem. Commun., 46 (2010) 6935-6937.

3. J. Pang, M. Zheng, A. Wang, T. Zhang, Catalytic Hydrogenation of Corn Stalk to Ethylene Glycol and 1,2-Propylene Glycol, Ind. Eng. Chem. Res., 50 (2011) 6601-6608.

4. J. Pang, Y. Jiang, A. Wang, T. Zhang, Progress in ethylene glycol production and purification, Chem. Ind. Eng. Prog., 32 (2013) 2006.(中文 F1000)

5. J. Pang, M. Zheng, A. Wang, R. Sun, H. Wang, Y. Jiang, T. Zhang, Catalytic conversion of concentrated miscanthus in water for ethylene glycol production, AIChE J., 60 (2014) 2254-2262.

6. J. Pang, M. Zheng, R. Sun, L. Song, A. Wang, X. Wang, T. Zhang, Catalytic conversion of cellulosic biomass to ethylene glycol: Effects of inorganic impurities in biomass, Bioresour. Technol., 175 (2015) 424-429.

7. J. Pang, M. Zheng, L. He, L. Li, X. Pan, A. Wang, X. Wang, T. Zhang, Upgrading ethanol to n-butanol over highly dispersed Ni-MgAlO catalysts, J. Catal., 344 (2016) 184-193.

8. J. Pang, M. Zheng, R. Sun, A. Wang, X. Wang, T. Zhang, Synthesis of ethylene glycol and terephthalic acid from biomass for producing PET, Green Chem., 18 (2016) 342-359.

9. J. Pang, M. Zheng, X. Li, L. Song, R. Sun, J. Sebastian, A. Wang, J. Wang, X. Wang, T. Zhang, Catalytic Conversion of Carbohydrates to Methyl Lactate Using Isolated Tin Sites in SBA-15, Chemistryselect, 2 (2017) 309-314.

10. J. Pang, M. Zheng, X. Li, Y. Jiang, Y. Zhao, A. Wang, J. Wang, X. Wang, T. Zhang, Selective conversion of concentrated glucose to 1,2-propylene glycol and ethylene glycol by using RuSn/AC catalysts, Appl. Catal. B Environ., 239 (2018) 300-308.

11. J. Pang, J. Sun, M. Zheng, H. Li, Y. Wang, T. Zhang, Transition metal carbide catalysts for biomass conversion: A review, Appl. Catal. B Environ., 254 (2019) 510-522.

12. J. Pang, M. Zheng, X. Li, J. Sebastian, Y. Jiang, Y. Zhao, A. Wang, T. Zhang, Unlock the Compact Structure of Lignocellulosic Biomass by Mild Ball Milling for Ethylene Glycol Production, ACS Sust. Chem. Eng., 7 (2019) 679-687.

13. J. Pang, M. Zheng, T. Zhang, Synthesis of ethanol and its catalytic conversion, in: C. Song (Ed.) Advances in Catalysis, Vol 642019, pp. 89-191.

14. J. Pang, M. Zheng, C. Wang, X. Yang, H. Liu, X. Liu, J. Sun, Y. Wang, T. Zhang, Hierarchical Echinus-like Cu-MFI Catalysts for Ethanol Dehydrogenation, ACS Catal., 10 (2020) 13624-13629.

15. J. Pang, M. Zheng, Z. Wang, S. Liu, X. Li, X. Li, J. Wang, T. Zhang, Catalytic upgrading of ethanol to butanol over a binary catalytic system of FeNiOx and LiOH, Chin. J. Catal., 41 (2020) 672-678.

16. J. Pang, B. Zhang, Y. Jiang, Y. Zhao, C. Li, M. Zheng, T. Zhang, Complete conversion of lignocellulosic biomass to mixed organic acids and ethylene glycol via cascade steps, Green Chem., 23 (2021) 2427-2436.

共同第一作者

1.      H. Li, J. Pang, N.R. Jaegers, L. Kovarik, M. Engelhard, A.W. Savoy, J. Hu, J. Sun, Y. Wang, Conversion of ethanol to 1,3-butadiene over Ag-ZrO₂/SiO₂ catalysts: The role of surface interfaces, J. Energy. Chem., 54 (2021) 7-15.

通讯作者

1.      Z. Wang, J. Pang, L. Song, X. Li, Q. Yuan, X. Li, S. Liu, M. Zheng, Conversion of Ethanol to n-Butanol over NiCeO₂ Based Catalysts: Effects of Metal Dispersion and NiCe Interactions, Ind. Eng. Chem. Res., 59 (2020) 22057-22067

[1] Pang, Jifeng, Yin, Ming, Wu, Pengfei, Song, Lei, Li, Xianquan, Zhang, Tao, Zheng, Mingyuan. Redispersion and Stabilization of Cu/MFI Catalysts by the Encapsulation Method for Ethanol Dehydrogenation. ACS SUSTAINABLE CHEMISTRY & ENGINEERING. 2023, http://dx.doi.org/10.1021/acssuschemeng.2c06058.
[2] Wu, Pengfei, Yang, Miao, Pang, Jifeng, Fan, Dong, Song, Lei, Sun, Tantan, Zheng, Mingyuan, Tian, Peng, Zhang, Tao. Facile synthesis of SAPO-34 nanocrystallites with excellent performance for the dehydration of carbohydrates to 5-hydroxymethylfurfural. GREEN CHEMISTRY[J]. 2023, 25(4): 1395-1405, http://dx.doi.org/10.1039/d2gc04301g.
[3] Wang, Zhinuo, Yin, Ming, Pang, Jifeng, Li, Xianquan, Xing, Yanan, Su, Yang, Liu, Shimin, Liu, Xiaoyan, Wu, Pengfei, Zheng, Mingyuan, Zhang, Tao. Active and stable Cu doped NiMgAlO catalysts for upgrading ethanol to n-butanol. JOURNAL OF ENERGY CHEMISTRY[J]. 2022, 72(9): 306-317, http://dx.doi.org/10.1016/j.jechem.2022.04.049.
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[5] Li, Houqian, Pang, Jifeng, Jaegers, Nicholas R, Kovarik, Libor, Engelhard, Mark, Savoy, Anthony W, Hu, Jianzhi, Sun, Junming, Wang, Yong. Conversion of ethanol to 1,3-butadiene over Ag-ZrO2/SiO2 catalysts: The role of surface interfaces. JOURNAL OF ENERGY CHEMISTRY[J]. 2021, 54(3): 7-15, http://lib.cqvip.com/Qikan/Article/Detail?id=7104209000.
[6] Li, Xinsheng, Pang, Jifeng, Zhang, Jingcai, Li, Xianquan, Jiang, Yu, Su, Yang, Li, Weizhen, Zheng, Mingyuan. Tuning the Reaction Selectivity over MgAl Spinel-Supported Pt Catalyst in Furfuryl Alcohol Conversion to Pentanediols. CATALYSTS[J]. 2021, 11(4): https://doaj.org/article/aa3e71e93c00487ba59c01b972000a41.
[7] Li, Xinsheng, Pang, Jifeng, Luo, Wenhao, Zhao, Yu, Pan, Xiaoli, Zheng, Mingyuan. Catalytic Conversion of Tetrahydrofurfuryl Alcohol over Stable Pt/MoS2 Catalysts. CATALYSIS LETTERS[J]. 2021, 151(9): 2734-2747, http://dx.doi.org/10.1007/s10562-020-03500-9.
[8] Pang Jifeng, Zheng Mingyuan, Wang Zhinuo, Liu Shimin, Li Xinsheng, Li Xianquan, Wang Junhu, Zhang Tao. Catalytic upgrading of ethanol to butanol over a binary catalytic system of FeNiOx and LiOH. CHINESE JOURNAL OF CATALYSIS[J]. 2020, 41(4): 672-678, http://dx.doi.org/10.1016/S1872-2067(20)63541-0.
[9] Yuan, Qiang, Pang, Jifeng, Yu, Wenguang, Zheng, Mingyuan. Vapor-Phase Furfural Decarbonylation over a High-Performance Catalyst of 1%Pt/SBA-15. CATALYSTS[J]. 2020, 10(11): https://doaj.org/article/23822a6b2e254df8885bff84210417f9.
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[11] Wang, Zhinuo, Pang, Jifeng, Song, Lei, Li, Xianquan, Yuan, Qiang, Li, Xinsheng, Liu, Shimin, Zheng, Mingyuan. Conversion of Ethanol to n-Butanol over NiCeO2 Based Catalysts: Effects of Metal Dispersion and NiCe Interactions. INDUSTRIAL & ENGINEERING CHEMISTRY RESEARCH[J]. 2020, 59(51): 22057-22067, https://www.webofscience.com/wos/woscc/full-record/WOS:000603392000004.
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[29] 艾硕, 郑明远, 庞纪峰, 王爱琴, 张涛. 新型乙二醇合成工艺的产品精制与节能技术. 化工进展[J]. 2017, 36(7): 2344-2352, http://lib.cqvip.com/Qikan/Article/Detail?id=7000245499.
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[31] Xu, Gang, Wang, Aiqin, Pang, Jifeng, Zhao, Xiaochen, Xu, Jinming, Lei, Nian, Wang, Jia, Zheng, Mingyuan, Yin, Jianzhong, Zhang, Tao. Chemocatalytic Conversion of Cellulosic Biomass to Methyl Glycolate, Ethylene Glycol, and Ethanol. CHEMSUSCHEM[J]. 2017, 10(7): 1390-1394, http://dx.doi.org/10.1002/cssc.201601714.
[32] Xiao, Bin, Zheng, Mingyuan, Li, Xinsheng, Pang, Jifeng, Sun, Ruiyan, Wang, Hua, Pang, Xiaoli, Wang, Aiqin, Wang, Xiaodong, Zhang, Tao. Synthesis of 1,6-hexanediol from HMF over double-layered catalysts of Pd/SiO2 + Ir-ReOx/SiO2 in a fixed-bed reactor. GREEN CHEMISTRY[J]. 2016, 18(7): 2175-2184, http://cas-ir.dicp.ac.cn/handle/321008/148403.
[33] Pang, Jifeng, Zheng, Mingyuan, Sun, Ruiyan, Wang, Aiqin, Wang, Xiaodong, Zhang, Tao. Synthesis of ethylene glycol and terephthalic acid from biomass for producing PET. GREEN CHEMISTRY[J]. 2016, 18(2): 342-359, http://cas-ir.dicp.ac.cn/handle/321008/171170.
[34] Sun, Ruiyan, Zheng, Mingyuan, Pang, Jifeng, Liu, Xin, Wang, Junhu, Pan, Xiaoli, Wang, Aiqin, Wang, Xiaodong, Zhang, Tao. Selectivity-Switchable Conversion of Cellulose to Glycols over Ni-Sn Catalysts. ACS CATALYSIS[J]. 2016, 6(1): 191-201, http://cas-ir.dicp.ac.cn/handle/321008/148281.
[35] Pang, Jifeng, Zheng, Mingyuan, He, Lei, Li, Lin, Pan, Xiaoli, Wang, Aiqin, Wang, Xiaodong, Zhang, Tao. Upgrading ethanol to n-butanol over highly dispersed Ni-MgAlO catalysts. JOURNAL OF CATALYSIS[J]. 2016, 344: 184-193, http://dx.doi.org/10.1016/j.jcat.2016.08.024.
[36] Xiao, Bin, Zheng, Mingyuan, Pang, Jifeng, Jiang, Yu, Wang, Hua, Sun, Ruiyan, Wang, Aiqin, Wang, Xiaodong, Zhang, Tao. Synthesis and Characterization of Poly(ethylene terephthalate) from Biomass-Based Ethylene Glycol: Effects of Miscellaneous Diols. INDUSTRIAL & ENGINEERING CHEMISTRY RESEARCH[J]. 2015, 54(22): 5862-5869, http://cas-ir.dicp.ac.cn/handle/321008/146334.
[37] Pang, Jifeng, Zheng, Mingyuan, Sun, Ruiyan, Song, Lei, Wang, Aiqin, Wang, Xiaodong, Zhang, Tao. Catalytic conversion of cellulosic biomass to ethylene glycol: Effects of inorganic impurities in biomass. BIORESOURCE TECHNOLOGY[J]. 2015, 175: 424-429, http://dx.doi.org/10.1016/j.biortech.2014.10.076.
[38] Xu, Gang, Wang, Aiqin, Pang, Jifeng, Zheng, Mingyuan, Yin, Jianzhong, Zhang, Tao. Remarkable effect of extremely dilute H2SO4 on the cellulose conversion to ethylene glycol. APPLIED CATALYSIS A-GENERAL[J]. 2015, 502: 65-70, http://dx.doi.org/10.1016/j.apcata.2015.05.038.
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[40] Sun, Ruiyan, Wang, Tingting, Zheng, Mingyuan, Deng, Weiqiao, Pang, Jifeng, Wang, Aiqin, Wang, Xiaodong, Zhang, Tao. Versatile Nickel-Lanthanum(III) Catalyst for Direct Conversion of Cellulose to Glycols. ACS CATALYSIS[J]. 2015, 5(2): 874-883, http://cas-ir.dicp.ac.cn/handle/321008/145987.
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（ 1 ） 纤维素/半纤维素定向催化转化制备二元醇, 参与, 国家级, 2017-01--2021-12
（ 2 ） 菊芋转化制备乳酸酯的新型催化剂设计和应答机制研究, 主持, 国家级, 2014-01--2016-12
（ 3 ） 生物乙醇催化转化为丁醇的立体位阻催化剂设计, 主持, 国家级, 2018-01--2021-12

（1）Upgrading ethanol to butanol: the catalyst development   2019-08-07
（2）Selective conversion of concentrated sugars to 1,2-propylene glycol and ethylene glycol by using RuSn/AC catalysts   TOCAT-8   2018-08-05
（3）Upgrading ethanol to n-butanol over highly dispersed Ni–MgAlO catalysts   第七届亚太催化大会   Jifeng Pang, Mingyuan Zheng, Aiqin Wang, Tao Zhang   2017-01-16

同大连交通大学刘世民教授联合培养学生，王祉诺 已经毕业

同大连交通大学刘世民教授联合培养学生，郭晋，在读

现指导学生

殷铭  硕士研究生  085600-材料与化工