ylzzcom永利总站线路检测
教师主页

教师主页

current location: 首页 > 团队队伍 > 马川 >

马川

职称:教授

联系方式:chuanma@cqu.edu.cn

主要从事:从事含碳固废(废塑料与生物质)能源化与资源化处置,复合材料高品位回收技术以及污染物控制等方面相关研究。
  • 个人简介
  • 教育经历
  • 研究方向
  • 本科生及公司产品
  • 科研项目
  • 代表性论文

        马川,工学博士,教授,博士生导师,弘深优秀学者,国家高层次青年人才入选者。2017年获华中科技大学热能工程专业工学博士学位,先后于日本产业技术综合研究所(AIST)和日本东北大学开展博士后研究工作,期间于2019年入选日本学术振兴会JSPS Fellow。2023年入职ylzzcom永利总站线路检测。

       从事含碳固废高效清洁转化与污染物控制相关领域的研究。发表高水平论文50余篇(ESI高被引论文4篇),被引2900余次,H-index 为26。授权国家发明专利2项和日本发明专利1项。主持国家自然科学基金青年人才项目、国家自然科学基金青年科学项目、日本学术振兴会JSPS科学研究项目;参与日本新能源产业技术综合开发机构(NEDO)两项专项子课题,日本科学技术振兴机构JST紧急支撑项目和日本环境省多个科学研究项目。担任Journal of Analytical and Applied Pyrolysis编委,Frontier in Energy Research 副编辑,为Environ. Sci. Technol., J. Hazard. Mater., J. Anal. Appl. Pyrolysis和 Fuel等多个学术期刊审稿人。

  • 更多信息:

  • https://scholar.google.com/citations?user=uzwx2NwAAAAJ&hl=zh-CN&oi=ao

  • https://orcid.org/0000-0002-1731-8934

  • https://iee.cqu.edu.cn/info/1003/1286.htm

  •  



2023.02 – 至今     ylzzcom永利总站线路检测 ylzzcom永利总站线路检测 教授

2020.09 – 2022.08   日本东北大学,环境科学研究所科,JSPS学者

2017.09 – 2020.08   日本产业技术综合研究所,环境管理部门,特别研究员

2012.09 – 2017.06   华中科技大学,ylzzcom永利总站线路检测,热能工程,工学博士

2016.11 – 2017.04   日本东京工业大学,环境社会理工学院,研修生

2008.09 – 2012.06   武汉理工大学,ylzzcom永利总站线路检测,能源动力系统及自动化,工学学士

 


(1)含碳固废 (生物质 /废塑料 )热化学转化;

(2)能源利用中污染物生成机理与防治技术;

(3)高品位复合材料回收技术开发;

(4)固废衍生新型污染物(微塑料)的控制技术。

欢迎从事热化学与能源清洁转化等相关研究方向的同学报考硕士、博士研究生


1.        国家高层次人才青年项目,2025–2027,负责人

2.        国家自然科学基金青年科学基金项目,2025–2027,负责人

3.        重庆市青年人才项目,2024–2027,负责人

4.        ylzzcom永利总站线路检测科研启动费,2023–,负责人

5.        日本学术振兴会(JSPS)科学研究費,2020–2023,负责人

6.        日本学术振兴会(JSPS)科研辅助金,2022–2024,参与

7.        日本科学技术振兴机构(JST)紧急研究支持项目,2021–2028,参与

8.        日本新能源产业技术综合开发机构(NEDO)专项子课题,2017–2022,主研人

9.        日本新能源产业技术综合开发机构(NEDO)专项子课题,2014–2022,主研人

10.    日本环境省环境研究与技术发展基金,2017–2019,主研人


      代表性论文:

[1]       Zhi He, Wei He, Jingyu Ran, Chuan Ma*, Xin Huang, Yunlin Shao. Synergistic improvement of RuO2/CeO2 catalysts on Hg0 oxidation from SO2-containing flue gas: A theoretical and experimental study. Chemical Engineering Journal, 505(2025):159572.

[2]       Chuan Ma*, Shogo Kumagai, Yuko Saito, Toshiaki Yoshioka, Xin Huang, Yunlin Shao, Jingyu Ran, Lushi Sun. Recent Advancements in Pyrolysis of Halogen-Containing Plastics for Resource Recovery and Halogen Upcycling: A State-of-the-Art Review. Environmental Science & Technology, 58(2024): 1423-1440. (Highly Cited paper)

[3]       Chuan Ma, Shogo Kumagai, Atsushi Watanabe, Chuichi Watanabe, Norio Teramae, Toshiaki Yoshioka, Young-Min Kim. Thermal and catalytic fast hydropyrolysis of lignin: Optimization for selective production of aromatics using high-pressure tandem μ-reactor–gas chromatography/mass spectrometry. Chemical Engineering Journal, 479(2024):147524

[4]       Tao Chen, Chuan Ma*, Ben Wang, Linlin Xu, Wu Yang, Lushi Sun. Kinetics and debromination studies on the pyrolysis of waste printed circuit boards with the addition of copper and copper oxides. Journal of Cleaner Production, 443(2024): 141141.

[5]       Chuan Ma*, Shogo Kumagai, Masumi Sato, Yumi Nakai, Yuko Saito, Atsushi Watanabe, Chuichi Watanabe, Norio Teramae, Toshiaki Yoshioka. Investigating the degradation and products of thermo-oxidation of polyimide-based engineering plastics. Journal of Analytical and Applied Pyrolysis, 181(2024): 106575.

[6]       Chuan Ma*, Shogo Kumagai, Yuko Saito, Tomohito Kameda, Atsushi Watanabe, Chuichi Watanabe, Norio Teramae, Toshiaki Yoshioka. Production of BTX via catalytic fast pyrolysis of printed circuit boards and waste tires using hierarchical ZSM-5 zeolites and biochar. ACS Sustainable Chemistry & Engineering, 10(2022):14775–14782. (Supplementary Cover)

[7]       Shogo Kumagai, Masumi Sato, Chuan Ma*, Yumi Nakai, Tomohito Kameda, Yuko Saito, Atsushi Watanabe, Chuichi Watanabe, Norio Teramae, Toshiaki Yoshioka. A comprehensive study into the thermo-oxidative degradation of sulfur-based engineering plastics. Journal of Analytical and Applied Pyrolysis, 168(2022):105754.

[8]       Chuan Ma*, Shengyu Xie, Shogo Kumagai, Yusuke Takahashi, Yuko Saito, Tomohito Kameda, Toshiaki Yoshioka. Synergistic effects during co-pyrolysis of milled wood lignin and polyolefins at the gas phase and liquid/solid phase contacting modes. Chemical Engineering Journal, 431(2022):134030.

[9]       Chuan Ma*, Shogo Kumagai, Yuko Saito, Tomohito Kameda, Toshiaki Yoshioka. An integrated utilization strategy of printed circuit boards and waste tire by fast co-pyrolysis: Value-added products recovery and heteroatoms transformation. Journal of Hazardous Materials, 430(2022):128420.

[10]   Ben Wang, Wei Li, Chuan Ma*, Wu Yang, Deepak Pudasainee, Rajender Gupta, Lushi Sun. Synergistic effect on the co-gasification of petroleum coke and carbon-based feedstocks: A state-of-the-art review. Journal of the Energy Institute, 102(2022):1-13. (Highly Cited paper)

[11]   Chuan Ma*, Shogo Kumagai, Yuko Saito, Tomohito Kameda, Toshiaki Yoshioka. Enhanced production of phenol and debromination by co-pyrolysis of the non-metallic fraction of printed circuit boards and waste tire. Green Chemistry, 23(2021):6392-6404. (Back-cover)

[12]   Chuan Ma*, Daniel S. Rodríguez, Tohru Kamo. A comprehensive study on the oxidative pyrolysis of epoxy resin from fiber/epoxy composites: Product characteristics and kinetics, Journal of Hazardous Materials, 412(2021):125329.

[13]   Chuan Ma*, Daniel S. Rodríguez, Tohru Kamo. Influence of thermal treatment on the properties of carbon fiber reinforced plastics under various conditions, Polymer Degradation and Stability, 178(2020):109199.

[14]   Daniel S. Rodríguez, Chuan Ma*, Tohru Kamo. Inhibition effect of amine compounds derived from hardening agents on the extraction of hydrogen bromide by water from the pyrolysis oil of brominated printed circuit boards, Journal of Cleaner Production, 265(2020):121811.

[15]   Chuan Ma* and Tohru Kamo. Effect of steam-iron reaction on product characteristics and debromination during pyrolysis of epoxy-printed circuit boards, Journal of Hazardous Materials, 379(2019):120803.

[16]   Chuan Ma, Qianqian Yan, Jie Yu, Tao Chen, Dingshun Wang, Sheng Liu, Kagiso Bikane, Lushi Sun. The behavior of heteroatom compounds during the pyrolysis of waste computer casing plastic under various heating conditions, Journal of Cleaner Production, 219(2019):461-470.

[17]   Chuan Ma* and Tohru Kamo. Enhanced debromination by Fe particles during the catalytic pyrolysis of non-metallic fractions of printed circuit boards over ZSM-5 and Ni/SiO2-Al2O3 catalyst, Journal of Analytical and Applied Pyrolysis, 138(2019):170-177.

[18]   Chuan Ma* and Tohru Kamo. Two-stage catalytic pyrolysis and debromination of printed circuit boards: Effect of zero-valent Fe and Ni metals. Journal of Analytical and Applied Pyrolysis, 134(2018): 614-620.

[19]   Chuan Ma, Jie Yu, Tao Chen, Qianqian Yan, Zijian Song, Ben Wang, Lushi Sun. Influence of Fe based ZSM-5 catalysts on the vapor intermediates from the pyrolysis of brominated acrylonitrile-butadiene-styrene copolymer (Br-ABS). Fuel, 15 (2018):390-396.

[20]   Chuan Ma, Jie Yu, Qianqian Yan, Zijian Song, Ke Wang, Ben Wang, Lushi Sun. Pyrolysis-catalytic upgrading of brominated high impact polystyrene over Fe and Ni modified catalysts: Influence of HZSM-5 and MCM-41 catalysts. Polymer Degradation and Stability, 146(2017):1-12.

[21]   Chuan Ma, Jie Yu, Ben Wang, Zijian Song, Jun Xiang, Song Hu, Sheng Su, Lushi Sun. Catalytic pyrolysis of flame retarded high impact polystyrene over various solid acid catalyst. Fuel Processing Technology, 155(2017):32-41.

[22]   Chuan Ma, Jie Yu, Ben Wang, Zijian Song, Jun Xiang, Song Hu, Sheng Su, Lushi Sun. Chemical recycling of brominated flame retarded plastics from e-waste for clean fuels production: A Review. Renewable & Sustainable Energy Reviews, 61(2016):433-450. (Highly Cited paper)

[23]   Chuan Ma, Jie Yu, Ben Wang, Zijian Song, Fei Zhou, Jun Xiang, Song Hu, Sheng Su, Lushi Sun. Influence of zeolites and mesoporous catalysts on catalytic pyrolysis of brominated acrylonitrile–butadiene–styrene (Br-ABS). Energy & Fuels, 30(2016):4635-4643.

[24]   Chuan Ma, Lushi Sun, Jun Xiang, Song Hu, Sheng Su. Effect of polypropylene on the pyrolysis of flame retarded high impact polystyrene. Fuel Processing Technology, 135(2015):150–156.