AgBF4/[emim] [BF4] supported ionic liquid membrane for carbon monoxide/nitrogen separation

doi:10.1016/j.jechem.2018.02.004

能源化学(英文) ›› 2019, Vol. 28 ›› Issue (2): 31-39.DOI: 10.1016/j.jechem.2018.02.004

AgBF₄/[emim] [BF₄] supported ionic liquid membrane for carbon monoxide/nitrogen separation

Shichao Feng, Yuanyuan Wu, Jianquan Luo, Yinhua Wan

State Key Laboratory of Biochemical Engineering, Institute of Process Engineering, Chinese Academy of Sciences, Beijing 100190, China

收稿日期:2017-11-20 修回日期:2018-01-24 出版日期:2019-02-15 发布日期:2019-02-15
通讯作者: Shichao Feng, Yinhua Wan
基金资助:
Financial support from the National Natural Science Foundation of China (21406235) is gratefully acknowledged.

AgBF₄/[emim] [BF₄] supported ionic liquid membrane for carbon monoxide/nitrogen separation

Shichao Feng, Yuanyuan Wu, Jianquan Luo, Yinhua Wan

State Key Laboratory of Biochemical Engineering, Institute of Process Engineering, Chinese Academy of Sciences, Beijing 100190, China

Received:2017-11-20 Revised:2018-01-24 Online:2019-02-15 Published:2019-02-15
Contact: Shichao Feng, Yinhua Wan
Supported by:
Financial support from the National Natural Science Foundation of China (21406235) is gratefully acknowledged.

摘要/Abstract

摘要： In this paper, AgBF₄/[emim] [BF₄] supported ionic liquid membranes (SILMs) were prepared successfully for CO/N₂ separation using nitrogen pressure immobilization procedures. The incorporation of AgBF₄ could decrease membrane weight loss, improve the pressure-resistant ability, and keep the critical pressure (0.45 MPa) of the SILMs. The high viscosity and undissolved AgBF₄ solids in membrane liquid would disturb gas molecular transport through membrane and give rise to the gas transport resistance. Therefore, the gas permeability decreased remarkably with increasing AgBF₄ carrier content in the membrane. When the molar ratio of AgBF₄ to[emim] [BF₄] increased from 0:1 to 0.3:1, the CO/N₂ selectivity of the SILMs showed a great increase from ～1 to ～9 at 20℃ and 0.4 MPa, suggesting that AgBF₄ was an effective carrier for CO facilitated transport. The permeabilities of N₂ and CO increased at higher transmembrane pressure, indicating that molecular transport would dominate the transport process at high pressure. The temperature-dependent gas permeability followed the Arrhenius equation. Moreover, the differences between the activation energies of CO and N₂ became larger after introducing AgBF₄, resulting in more obvious decrease in the CO/N₂ selectivity at higher operating temperature.

关键词: Supported ionic liquid membranes, [emim][BF₄], AgBF₄, Carbon monoxide separation

Abstract: In this paper, AgBF₄/[emim] [BF₄] supported ionic liquid membranes (SILMs) were prepared successfully for CO/N₂ separation using nitrogen pressure immobilization procedures. The incorporation of AgBF₄ could decrease membrane weight loss, improve the pressure-resistant ability, and keep the critical pressure (0.45 MPa) of the SILMs. The high viscosity and undissolved AgBF₄ solids in membrane liquid would disturb gas molecular transport through membrane and give rise to the gas transport resistance. Therefore, the gas permeability decreased remarkably with increasing AgBF₄ carrier content in the membrane. When the molar ratio of AgBF₄ to[emim] [BF₄] increased from 0:1 to 0.3:1, the CO/N₂ selectivity of the SILMs showed a great increase from ～1 to ～9 at 20℃ and 0.4 MPa, suggesting that AgBF₄ was an effective carrier for CO facilitated transport. The permeabilities of N₂ and CO increased at higher transmembrane pressure, indicating that molecular transport would dominate the transport process at high pressure. The temperature-dependent gas permeability followed the Arrhenius equation. Moreover, the differences between the activation energies of CO and N₂ became larger after introducing AgBF₄, resulting in more obvious decrease in the CO/N₂ selectivity at higher operating temperature.

Key words: Supported ionic liquid membranes, [emim][BF₄], AgBF₄, Carbon monoxide separation

Shichao Feng, Yuanyuan Wu, Jianquan Luo, Yinhua Wan. AgBF₄/[emim] [BF₄] supported ionic liquid membrane for carbon monoxide/nitrogen separation[J]. 能源化学(英文), 2019, 28(2): 31-39.

Shichao Feng, Yuanyuan Wu, Jianquan Luo, Yinhua Wan. AgBF₄/[emim] [BF₄] supported ionic liquid membrane for carbon monoxide/nitrogen separation[J]. Journal of Energy Chemistry, 2019, 28(2): 31-39.

[1]	Jungwon Kang, Jin Min Kim, do Youb Kim, Jungdon Suk, Jaekook Kim, dong Wook Kim, Yongku Kang. In-situ electrochemical functionalization of carbon materials for high-performance Li-O₂ batteries[J]. 能源化学(英文版), 2020, 48(9): 7-13.
[2]	Mingtan Wang, Huaiqing Wang, Huamin Zhang, Xianfeng Li. Aqueous K-ion battery incorporating environment-friendly organic compound and Berlin green[J]. 能源化学(英文版), 2020, 48(9): 14-20.
[3]	Tingting Qin, Xuefeng Chu, Ting Deng, boran Wang, Xiaoyu Zhang, Taowen Dong, Zhengming Li, Xiaofeng Fan, Xin Ge, Zizhun Wang, Peng Wang, Wei Zhang, Weitao Zheng. Reinventing the mechanism of high-performance Bi anode in aqueous K⁺ rechargeable batteries[J]. 能源化学(英文版), 2020, 48(9): 21-28.
[4]	Fen Qiao, Yi Xie. Strategies for enhancing conductivity of colloidal nanocrystals and their photoelectronic applications[J]. 能源化学(英文版), 2020, 48(9): 29-42.
[5]	Han Wu, Min Wu, boyang Wang, Xue Yong, Yushan Liu, baojun Li, baozhong Liu, Siyu Lu. Interface electron collaborative migration of Co-Co₃O₄/carbon dots: Boosting the hydrolytic dehydrogenation of ammonia borane[J]. 能源化学(英文版), 2020, 48(9): 43-53.
[6]	Karam Jabbour. Tuning combined steam and dry reforming of methane for "metgas" production: A thermodynamic approach and state-of-the-art catalysts[J]. 能源化学(英文版), 2020, 48(9): 54-91.
[7]	Sasan Ghashghaie, Samson Ho-Sum Cheng, Jie Fang, Hafiz Khurram Shahzad, Robin Lok-Wang Ma, chi-Yuen Chung. Electrophoretically deposited binder-free 3-D carbon/sulfur nanocomposite cathode for high-performance Li-S batteries[J]. 能源化学(英文版), 2020, 48(9): 92-101.
[8]	Huanhuan Jia, Linfeng Peng, Zhuoran Zhang, Tao An, Jia Xie. Na_3.8[Sn_0.67Si_0.33]_0.8Sb_0.2S₄:A quinary sodium fast ionic conductor for all-solid-state sodium battery[J]. 能源化学(英文版), 2020, 48(9): 102-106.
[9]	Xue Liu, Qiu He, Hong Yuan, chong Yan, Yan Zhao, Xu Xu, Jia-Qi Huang, Yu-Lun Chueh, Qiang Zhang, Liqiang Mai. Interface enhanced well-dispersed Co₉S₈ nanocrystals as an efficient polysulfide host in lithium-sulfur batteries[J]. 能源化学(英文版), 2020, 48(9): 109-115.
[10]	Bo Xu, Xiaodong Yang, Qiang Fang, Linbing Du, Yan Fu, Yiqiang Sun, Qisheng Liu, Qingquan Lin, cuncheng Li. Anion-cation dual doping: An effective electronic modulation strategy of Ni₂P for high-performance oxygen evolution[J]. 能源化学(英文版), 2020, 48(9): 116-121.
[11]	Feng Xiao, Xianghong Chen, Jiakui Zhang, chunmao Huang, Tong Hu, bo Hong, Jiantie Xu. Large-scale production of holey graphite as high-rate anode for lithium ion batteries[J]. 能源化学(英文版), 2020, 48(9): 122-127.
[12]	Bo Yuan, di Hua, Xingxing Gu, Yu Shen, Li-Chun Xu, Xiuyan Li, bing Zheng, Jiansheng Wu, Weina Zhang, Sheng Li, fengwei Huo. Polar, catalytic, and conductive CoSe₂/C frameworks for performance enhanced S cathode in Li-S batteries[J]. 能源化学(英文版), 2020, 48(9): 128-135.
[13]	C.Cannilla, G.Bonura, S.Maisano, L.Frusteri, M.Migliori, G.Giordano, S.Todaro, f.Frusteri. Zeolite-assisted etherification of glycerol with butanol for biodiesel oxygenated additives production[J]. 能源化学(英文版), 2020, 48(9): 136-144.
[14]	Renheng Wang, Weisheng Cui, fulu Chu, feixiang Wu. Lithium metal anodes: Present and future[J]. 能源化学(英文版), 2020, 48(9): 145-159.
[15]	Wen-Feng Ren, Jun-Tao Li, Shao-Jian Zhang, Ai-Ling Lin, You-Hu Chen, Zhen-Guang Gao, Yao Zhou, Li Deng, Ling Huang, Shi-Gang Sun. Fabrication of multi-shell coated silicon nanoparticles via in-situ electroless deposition as high performance anodes for lithium ion batteries[J]. 能源化学(英文版), 2020, 48(9): 160-168.

AgBF₄/[emim] [BF₄] supported ionic liquid membrane for carbon monoxide/nitrogen separation

AgBF₄/[emim] [BF₄] supported ionic liquid membrane for carbon monoxide/nitrogen separation

可视化

摘要/Abstract

引用本文

使用本文

参考文献

相关文章 15

编辑推荐

Metrics