Chengwen Song
Dalian University of Technology
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Publication
Featured researches published by Chengwen Song.
Journal of Inorganic Materials | 2012
Chengwen Song; Dawei Jiang; Lin Li; Mei-Yue Sun; Tonghua Wang
针对现有气体分离炭膜存在的渗透速率低等问题, 提出并设计在PMDA-ODA型聚酰亚胺前驱体中掺杂碳纳米管, 经高温热解后制备炭/碳纳米管杂化膜. 分别采用透射电镜(TEM)、X射线衍射分析(XRD)和气体渗透实验对炭/碳纳米管杂化膜的微观结构和分离性能进行表征. 实验结果表明, 在PMDA-ODA型聚酰亚胺前驱体中掺杂碳纳米管后, 碳纳米管与炭基体之间形成明显的“界面间隙”, 打破了原有炭膜中由乱层炭构成的无序微孔结构, 重新构建了杂化炭膜的孔隙结构. 与纯炭膜相比, 杂化炭膜的气体渗透速率大幅增加, 其中O 2 的渗透速率增大接近4倍(达到1576 Barrer), 而O 2 /N 2 的分离选择性仅降低17%.针对现有气体分离炭膜存在的渗透速率低等问题, 提出并设计在PMDA-ODA型聚酰亚胺前驱体中掺杂碳纳米管, 经高温热解后制备炭/碳纳米管杂化膜. 分别采用透射电镜(TEM)、X射线衍射分析(XRD)和气体渗透实验对炭/碳纳米管杂化膜的微观结构和分离性能进行表征. 实验结果表明, 在PMDA-ODA型聚酰亚胺前驱体中掺杂碳纳米管后, 碳纳米管与炭基体之间形成明显的“界面间隙”, 打破了原有炭膜中由乱层炭构成的无序微孔结构, 重新构建了杂化炭膜的孔隙结构. 与纯炭膜相比, 杂化炭膜的气体渗透速率大幅增加, 其中O 2 的渗透速率增大接近4倍(达到1576 Barrer), 而O 2 /N 2 的分离选择性仅降低17%.
Separation and Purification Technology | 2006
Chengwen Song; Tonghua Wang; Yanqiu Pan; Jieshan Qiu
Separation and Purification Technology | 2008
Chengwen Song; Tonghua Wang; Xiuyue Wang; Jieshan Qiu; Yiming Cao
Journal of Membrane Science | 2010
Chengwen Song; Tonghua Wang; Huawei Jiang; Xiuyue Wang; Yiming Cao; Jieshan Qiu
Journal of Porous Materials | 2008
Chengwen Song; Tonghua Wang; Jieshan Qiu; Yiming Cao; Tianxi Cai
Journal of Membrane Science | 2014
Lin Li; Chengwen Song; Huawei Jiang; Jieshan Qiu; Tonghua Wang
Journal of Porous Materials | 2009
Chengwen Song; Tonghua Wang; Yinghua Qiu; Jieshan Qiu; Hui-Ming Cheng
Desalination | 2009
Chengwen Song; Tonghua Wang; Jieshan Qiu
Archive | 2012
Tonghua Wang; Chengwen Song; Rongchun Wang; Lin Li; Jianxin Li; Jieshan Qiu
Separation and Purification Technology | 2017
Lin Li; Chengwen Song; Dawei Jiang; Tonghua Wang
