Recent advances in graphene-based membranes for CO2 separation

doi:10.16085/j.issn.1000-6613.2022-0164

Abstract

Abstract:

The development of CO₂ separation technologies with high efficiency and energy effectiveness has practical and long-term significance. Membrane based CO₂ separation has become a promising approach owing to its low energy consumption, easy operation, small footprint and cost effectiveness. Currently, the focus of membrane research is searching for novel membrane materials with excellent transport characteristics. Graphene and its derivatives have gained great attention in the field of gas separation because of the atomic thickness, sub-nano pore size and excellent mechanical, thermal and chemical stability. The limiting factors for the practical applications include the difficulties in processing, technological cost, large-area fabrication and membrane working stability. Graphene-based CO₂ separation membranes can be categorized as: nanoporous graphene, lamellar graphene oxide membranes and mixed matrix membranes with graphene and its derivatives as the nanofillers. The review summarized outstanding breakthroughs regarding graphene-based CO₂ separation membranes, emphasizing the gas transport mechanisms and structure-property relationships. Optimization strategies based on rational design and the underlying mechanisms discussed. Challenges analyzed and the potential research directions proposed. Systematic theoretical research should be conducted combined with advanced characterization methods to establish structure-property relationship of membranes. In addition, the cost-effectiveness and working stability vital for the practical applications.

Key words: two-dimensional materials, carbon dioxide separation, interface regulation, mixed matrix membrane

摘要：

节能高效的CO₂分离技术的开发具有重要的现实及长远意义，膜法CO₂分离在该领域备受关注，具有优异传质特性的新型分离膜材料对膜分离过程有决定性的影响。近年来，石墨烯及其衍生材料因独特的单原子层厚度、亚纳米级别的孔道结构以及优异的机械、化学和热稳定性，成为气体分离膜领域的研究热点，膜的加工难度、技术成本、大面积制备、工作稳定性等问题是限制其实际应用的关键因素。石墨烯基CO₂分离膜主要有三种形式：纳米孔石墨烯膜、层状结构氧化石墨烯膜、基于石墨烯及其衍生材料的混合基质膜。本文综述了石墨烯基CO₂分离膜领域的突破性研究进展，重点介绍了气体的跨膜传质机理和膜的构性关系，总结了膜性能的优化思路和原理，梳理了石墨烯基CO₂分离膜发展面临的挑战，提出了潜在的研究方向。分析表明，进行系统的理论研究，采用先进的表征手段，以建立膜构性关系的理论模型，指导膜结构设计是未来研究的重点。此外，进一步降低膜加工成本，充分研究膜在实际工作环境中的稳定性也至关重要。

关键词: 二维材料, 二氧化碳分离, 界面调控, 混合基质膜

CLC Number:

ZHAO Guoke, PAN Guoyuan, ZHANG Yang, YU Hao, ZHAO Muhua, TANG Gongqing, LIU Yiqun. Recent advances in graphene-based membranes for CO₂ separation[J]. Chemical Industry and Engineering Progress, 2022, 41(11): 5896-5911.

赵国珂, 潘国元, 张杨, 于浩, 赵慕华, 唐功庆, 刘轶群. 石墨烯基材料在CO₂分离膜领域的研究进展[J]. 化工进展, 2022, 41(11): 5896-5911.

Figures/Tables 11

References 82

1	CHEN Guining, WANG Tianlei, ZHANG Guangru, et al. Membrane materials targeting carbon capture and utilization[J]. Advanced Membranes, 2022, 2: 100025.
2	HAN Yang, WINSTON Ho W S. Polymeric membranes for CO₂ separation and capture[J]. Journal of Membrane Science, 2021, 628: 119244.
3	MOGHADAM Farhad, PARK Ho Bum. Two-dimensional materials: an emerging platform for gas separation membranes[J]. Current Opinion in Chemical Engineering, 2018, 20: 28-38.
4	YOO Byung Min, SHIN Jae Eun, LEE Hee Dae, et al. Graphene and graphene oxide membranes for gas separation applications[J]. Current Opinion in Chemical Engineering, 2017, 16: 39-47.
5	NIDAMANURI Nagapradeep, LI Yaqi, LI Qiang, et al. Graphene and graphene oxide-based membranes for gas separation[J]. Engineered Science, 2020, 9: 3-16.
6	Scott BUNCH J, VERBRIDGE Scott S, ALDEN Jonathan S, et al. Impermeable atomic membranes from graphene sheets[J]. Nano Letters, 2008, 8(8): 2458-2462.
7	XU Pengtao, YANG Jixiang, WANG Kesai, et al. Porous graphene: properties, preparation, and potential applications[J]. Chinese Science Bulletin, 2012, 57(23): 2948-2955.
8	JIANG Deen, COOPER Valentino R, DAI Sheng. Porous graphene as the ultimate membrane for gas separation[J]. Nano Letters, 2009, 9(12): 4019-4024.
9	BELL D C, LEMME M C, STERN L A, et al. Precision cutting and patterning of graphene with helium ions[J]. Nanotechnology, 2009, 20(45): 455301.
10	YANG Rong, ZHANG Lianchang, WANG Yi, et al. An anisotropic etching effect in the graphene basal plane[J]. Advanced Materials, 2010, 22(36): 4014-4019.
11	BAI Jingwei, ZHONG Xing, JIANG Shan, et al. Graphene nanomesh[J]. Nature Nanotechnology, 2010, 5(3): 190-194.
12	HSU Kuang Jung, VILLALOBOS Luis Francisco, HUANG Shiqi, et al. Multipulsed millisecond ozone gasification for predictable tuning of nucleation and nucleation-decoupled nanopore expansion in graphene for carbon capture[J]. ACS Nano, 2021, 15(8): 13230-13239.
13	XIE Guibai, YANG Rong, CHEN Peng, et al. A general route towards defect and pore engineering in graphene[J]. Small, 2014, 10(11): 2280-2284.
14	FISCHBEIN Michael D, Marija DRNDIĆ. Electron beam nanosculpting of suspended graphene sheets[J]. Applied Physics Letters, 2008, 93(11): 113107.
15	RUSSO Christopher J, GOLOVCHENKO J A. Atom-by-atom nucleation and growth of graphene nanopores[J]. Proceedings of the National Academy of Sciences of the United States of America, 2012, 109(16): 5953-5957.
16	ZHAO Guoke, LI Xinming, HUANG Meirong, et al. The physics and chemistry of graphene-on-surfaces[J]. Chemical Society Reviews, 2017, 46(15): 4417-4449.
17	HUANG Shiqi, DAKHCHOUNE Mostapha, LUO Wen, et al. Single-layer graphene membranes by crack-free transfer for gas mixture separation[J]. Nature Communications, 2018, 9(1): 2632.
18	SAFRON Nathaniel S, KIM Myungwoong, GOPALAN Padma, et al. Barrier-guided growth of micro-and nano-structured graphene[J]. Advanced Materials, 2012, 24(8): 1041-1045.
19	VILLALOBOS Luis Francisco, VAN GOETHEM Cédric, HSU Kuang-Jung, et al. Bottom-up synthesis of graphene films hosting atom-thick molecular-sieving apertures[J]. Proceedings of the National Academy of Sciences of the United States of America, 2021, 118(37): e2022201118.
20	PAWLAK Rémy, LIU Xunshan, NINOVA Silviya, et al. Bottom-up synthesis of nitrogen-doped porous graphene nanoribbons[J]. Journal of the American Chemical Society, 2020, 142(29): 12568-12573.
21	NEUMANN Christof, KAISER David, MOHN Michael J, et al. Bottom-up synthesis of graphene monolayers with tunable crystallinity and porosity[J]. ACS Nano, 2019, 13(6): 7310-7322.
22	JACOBSE Peter H, MCCURDY Ryan D, JIANG Jingwei, et al. Bottom-up assembly of nanoporous graphene with emergent electronic states[J]. Journal of the American Chemical Society, 2020, 142(31): 13507-13514.
23	DRAHUSHUK Lee W, STRANO Michael S. Mechanisms of gas permeation through single layer graphene membranes[J]. Langmuir, 2012, 28(48): 16671-16678.
24	SHAN Meixia, XUE Qingzhong, JING Nuannuan, et al. Influence of chemical functionalization on the CO₂/N₂ separation performance of porous graphene membranes[J]. Nanoscale, 2012, 4(17): 5477-5482.
25	GHIASI Mina, ZEINALI Parisa, GHOLAMI Samira, et al. Separation of CH₄, H₂S, N₂ and CO₂ gases using four types of nanoporous graphene cluster model: a quantum chemical investigation[J]. Journal of Molecular Modeling, 2021, 27(7): 1-13.
26	WU Tiantian, XUE Qingzhong, LING Cuicui, et al. Fluorine-modified porous graphene as membrane for CO₂/N₂ separation: molecular dynamic and first-principles simulations[J]. The Journal of Physical Chemistry C, 2014, 118(14): 7369-7376.
27	SUN Chengzhen, ZHU Shaohua, LIU Maochang, et al. Selective molecular sieving through a large graphene nanopore with surface charges[J]. The Journal of Physical Chemistry Letters, 2019, 10(22): 7188-7194.
28	TIAN Ziqi, MAHURIN Shannon M, DAI Sheng, et al. Ion-gated gas separation through porous graphene[J]. Nano Letters, 2017, 17(3): 1802-1807.
29	KOENIG Steven P, WANG Luda, PELLEGRINO John, et al. Selective molecular sieving through porous graphene[J]. Nature Nanotechnology, 2012, 7(11): 728-732.
30	CELEBI Kemal, BUCHHEIM Jakob, WYSS Roman M, et al. Ultimate permeation across atomically thin porous graphene[J]. Science, 2014, 344(6181): 289-292.
31	HE Guangwei, HUANG Shiqi, VILLALOBOS Luis Francisco, et al. High-permeance polymer-functionalized single-layer graphene membranes that surpass the postcombustion carbon capture target[J]. Energy & Environmental Science, 2019, 12(11): 3305-3312.
32	HUANG Kang, LIU Gongping, JIN Wanqin. Vapor transport in graphene oxide laminates and their application in pervaporation[J]. Current Opinion in Chemical Engineering, 2017, 16: 56-64.
33	GUAN Kecheng, SHEN Jie, LIU Gongping, et al. Spray-evaporation assembled graphene oxide membranes for selective hydrogen transport[J]. Separation and Purification Technology, 2017, 174: 126-135.
34	IBRAHIM Amr F M, LIN Y S. Synthesis of graphene oxide membranes on polyester substrate by spray coating for gas separation[J]. Chemical Engineering Science, 2018, 190: 312-319.
35	SINGH Swati, VARGHESE Anish Mathai, REINALDA Donald, et al. Graphene-based membranes for carbon dioxide separation[J]. Journal of CO₂ Utilization, 2021, 49: 101544.
36	TSOU Chi Hui, AN Quanfu, Shen Chuan LO, et al. Effect of microstructure of graphene oxide fabricated through different self-assembly techniques on 1-butanol dehydration[J]. Journal of Membrane Science, 2015, 477: 93-100.
37	SHEN Jie, LIU Gongping, HUANG Kang, et al. Subnanometer two-dimensional graphene oxide channels for ultrafast gas sieving[J]. ACS Nano, 2016, 10(3): 3398-3409.
38	KIM Hyo Won, YOON Hee Wook, YOON Seon Mi, et al. Selective gas transport through few-layered graphene and graphene oxide membranes[J]. Science, 2013, 342(6154): 91-95.
39	LI Hang, SONG Zhuonan, ZHANG Xiaojie, et al. Ultrathin, molecular-sieving graphene oxide membranes for selective hydrogen separation[J]. Science, 2013, 342(6154): 95-98.
40	SU Y, KRAVETS V G, WONG S L, et al. Impermeable barrier films and protective coatings based on reduced graphene oxide[J]. Nature Communications, 2014, 5: 4843.
41	IBRAHIM Amr, LIN Y S. Gas permeation and separation properties of large-sheet stacked graphene oxide membranes[J]. Journal of Membrane Science, 2018, 550: 238-245.
42	LI Wen, ZHENG Xin, DONG Zihan, et al. Molecular dynamics simulations of CO₂/N₂ separation through two-dimensional graphene oxide membranes[J]. The Journal of Physical Chemistry C, 2016, 120(45): 26061-26066.
43	WANG Pan, LI Wen, DU Congcong, et al. CO₂/N₂ separation via multilayer nanoslit graphene oxide membranes: molecular dynamics simulation study[J]. Computational Materials Science, 2017, 140: 284-289.
44	CHI Chenglong, WANG Xuerui, PENG Yongwu, et al. Facile preparation of graphene oxide membranes for gas separation[J]. Chemistry of Materials, 2016, 28(9): 2921-2927.
45	KIM Hyo Won, YOON Hee Wook, YOO Byung Min, et al. High-performance CO₂-philic graphene oxide membranes under wet-conditions[J]. Chemical Communications, 2014, 50(88): 13563-13566.
46	ZHOU Fanglei, TIEN Huynh Ngoc, XU Weiwei L, et al. Ultrathin graphene oxide-based hollow fiber membranes with brush-like CO₂-philic agent for highly efficient CO₂ capture[J]. Nature Communications, 2017, 8(1): 2107.
47	ZHOU Fanglei, TIEN Huynh Ngoc, DONG Qiaobei, et al. Ultrathin, ethylenediamine-functionalized graphene oxide membranes on hollow fibers for CO₂ capture[J]. Journal of Membrane Science, 2019, 573: 184-191.
48	WANG Shaofei, WU Yingzhen, ZHANG Ning, et al. A highly permeable graphene oxide membrane with fast and selective transport nanochannels for efficient carbon capture[J]. Energy & Environmental Science, 2016, 9(10): 3107-3112.
49	REN Yanxiong, PENG Dongdong, WU Hong, et al. Enhanced carbon dioxide flux by catechol-Zn²⁺ synergistic manipulation of graphene oxide membranes[J]. Chemical Engineering Science, 2019, 195: 230-238.
50	LIU Zhuang, ZHAI Yeming, ZHOU Kaige, et al. Advanced membranes with responsive two-dimensional nanochannels[J]. Advanced Membranes, 2021, 1: 100012.
51	LIU Meiling, GUO Jialin, JAPIP Susilo, et al. One-step enhancement of solvent transport, stability and photocatalytic properties of graphene oxide/polyimide membranes with multifunctional cross-linkers[J]. Journal of Materials Chemistry A, 2019, 7(7): 3170-3178.
52	LEE Yunyang, GURKAN Burcu. Graphene oxide reinforced facilitated transport membrane with poly(ionic liquid) and ionic liquid carriers for CO₂/N₂ separation[J]. Journal of Membrane Science, 2021, 638: 119652.
53	YING Wen, CAI Jingsong, ZHOU Ke, et al. Ionic liquid selectively facilitates CO₂ transport through graphene oxide membrane[J]. ACS Nano, 2018, 12(6): 5385-5393.
54	YING Wen, ZHOU Ke, HOU Quangang, et al. Selectively tuning gas transport through ionic liquid filled graphene oxide nanoslits using an electric field[J]. Journal of Materials Chemistry A, 2019, 7(25): 15062-15067.
55	WU Mian, SONG Xiangju, ZHANG Xiaoqian, et al. A reduced pressure-assisted vapor penetration of ionic liquid into the laminated graphene oxide membranes for efficient CO₂ separation[J]. Separation and Purification Technology, 2022, 287: 120514.
56	XIN Qingping, LI Zhao, LI Congdi, et al. Enhancing the CO₂ separation performance of composite membranes by the incorporation of amino acid-functionalized graphene oxide[J]. Journal of Materials Chemistry A, 2015, 3(12): 6629-6641.
57	LI Xueqin, CHENG Youdong, ZHANG Haiyang, et al. Efficient CO₂ capture by functionalized graphene oxide nanosheets as fillers to fabricate multi-permselective mixed matrix membranes[J]. ACS Applied Materials & Interfaces, 2015, 7(9): 5528-5537.
58	HUANG Tse Chiang, LIU Yucheng, LIN Gengsheng, et al. Fabrication of pebax-1657-based mixed-matrix membranes incorporating N-doped few-layer graphene for carbon dioxide capture enhancement[J]. Journal of Membrane Science, 2020, 602: 117946.
59	YANG Euntae, Kunli GOH, CHUAH Chong Yang, et al. Asymmetric mixed-matrix membranes incorporated with nitrogen-doped graphene nanosheets for highly selective gas separation[J]. Journal of Membrane Science, 2020, 615: 118293.
60	DONG Guanying, ZHANG Yatao, HOU Jingwei, et al. Graphene oxide nanosheets based novel facilitated transport membranes for efficient CO₂ capture[J]. Industrial & Engineering Chemistry Research, 2016, 55(18): 5403-5414.
61	时飞, 李奕帆. 混合基质膜在碳捕集领域的研究进展[J]. 化工进展, 2020, 39(6): 2453-2462.
	SHI Fei, LI Yifan. Advances of mixed matrix membrane for CO₂ capture[J]. Chemical Industry and Engineering Progress, 2020, 39(6): 2453-2462.
62	FAN Yanfang, WANG Xueli, LI Nanwen. Interfacial manipulation of MOFs/polymer mixed matrix membranes for gas separations: a review[J]. Chinese Science Bulletin, 2021, 66(23): 2930-2942.
63	YANG Liuxin, LUO Wenhua, WANG Changan, et al. Novel inorganic two-dimensional materials for gas separation membranes[J]. Journal of Inorganic Materials, 2020, 35(9): 959.
64	ZHAO Li, CHENG Cheng, CHEN Yufei, et al. Enhancement on the permeation performance of polyimide mixed matrix membranes by incorporation of graphene oxide with different oxidation degrees[J]. Polymers for Advanced Technologies, 2015, 26(4): 330-337.
65	WANG Ting, ZHAO Li, SHEN Jiangnan, et al. Enhanced performance of polyurethane hybrid membranes for CO₂ separation by incorporating graphene oxide: the relationship between membrane performance and morphology of graphene oxide[J]. Environmental Science & Technology, 2015, 49(13): 8004-8011.
66	SHEN Jie, ZHANG Mengchen, LIU Gongping, et al. Facile tailoring of the two-dimensional graphene oxide channels for gas separation[J]. RSC Advances, 2016, 6(59): 54281-54285.
67	DONG Guanying, HOU Jingwei, WANG Jing, et al. Enhanced CO₂/N₂ separation by porous reduced graphene oxide/Pebax mixed matrix membranes[J]. Journal of Membrane Science, 2016, 520: 860-868.
68	SHEN Jie, ZHANG Mengchen, LIU Gongping, et al. Size effects of graphene oxide on mixed matrix membranes for CO₂ separation[J]. AIChE Journal, 2016, 62(8): 2843-2852.
69	SHEN Jie, LIU Gongping, HUANG Kang, et al. Membranes with fast and selective gas-transport channels of laminar graphene oxide for efficient CO₂ capture[J]. Angewandte Chemie International Edition, 2015, 54(2): 578-582.
70	ZHANG Yatao, SHEN Qin, HOU Jingwei, et al. Shear-aligned graphene oxide laminate/Pebax ultrathin composite hollow fiber membranes using a facile dip-coating approach[J]. Journal of Materials Chemistry A, 2017, 5(17): 7732-7737.
71	MOHAMMED Shawqi Ali, NASIR A M, AZIZ F, et al. CO₂/N₂ selectivity enhancement of PEBAX MH 1657/Aminated partially reduced graphene oxide mixed matrix composite membrane[J]. Separation and Purification Technology, 2019, 223: 142-153.
72	CHEN Zan, ZHANG Peng, WU Hong, et al. Incorporating amino acids functionalized graphene oxide nanosheets into Pebax membranes for CO₂ separation[J]. Separation and Purification Technology, 2022, 288: 120682.
73	ZHANG Jinhui, XIN Qingping, LI Xu, et al. Mixed matrix membranes comprising aminosilane-functionalized graphene oxide for enhanced CO₂ separation[J]. Journal of Membrane Science, 2019, 570/571: 343-354.
74	DAI Yan, RUAN Xuehua, YAN Zhijun, et al. Imidazole functionalized graphene oxide/Pebax mixed matrix membranes for efficient CO₂ capture[J]. Separation and Purification Technology, 2016, 166: 171-180.
75	PENG Dongdong, WANG Shaofei, TIAN Zhizhang, et al. Facilitated transport membranes by incorporating graphene nanosheets with high zinc ion loading for enhanced CO₂ separation[J]. Journal of Membrane Science, 2017, 522: 351-362.
76	HUANG Guoji, ISFAHANI Ali Pournaghshband, MUCHTAR Ansori, et al. Pebax/ionic liquid modified graphene oxide mixed matrix membranes for enhanced CO₂ capture[J]. Journal of Membrane Science, 2018, 565: 370-379.
77	Winny FAM, MANSOURI Jaleh, LI Hongyu, et al. Gelled graphene oxide-ionic liquid composite membranes with enriched ionic liquid surfaces for improved CO₂ separation[J]. ACS Applied Materials & Interfaces, 2018, 10(8): 7389-7400.
78	SHIN Jae Eun, LEE Seul Ki, CHO Young Hoon, et al. Effect of PEG-MEA and graphene oxide additives on the performance of Pebax^® 1657 mixed matrix membranes for CO₂ separation[J]. Journal of Membrane Science, 2019, 572: 300-308.
79	YANG Kai, DAI Yan, RUAN Xuehua, et al. Stretched ZIF-8@GO flake-like fillers via pre-Zn(Ⅱ)-doping strategy to enhance CO₂ permeation in mixed matrix membranes[J]. Journal of Membrane Science, 2020, 601: 117934.
80	YANG Kai, DAI Yan, ZHENG Wenji, et al. ZIFs-modified GO plates for enhanced CO₂ separation performance of ethyl cellulose based mixed matrix membranes[J]. Separation and Purification Technology, 2019, 214: 87-94.
81	LI Wen, CHUAH Chong Yang, NIE Lina, et al. Enhanced CO₂/CH₄ selectivity and mechanical strength of mixed-matrix membrane incorporated with NiDOBDC/GO composite[J]. Journal of Industrial and Engineering Chemistry, 2019, 74: 118-125.
82	HE Rongrong, CONG Shenzhen, WANG Jing, et al. Porous graphene oxide/porous organic polymer hybrid nanosheets functionalized mixed matrix membrane for efficient CO₂ capture[J]. ACS Applied Materials & Interfaces, 2019, 11(4): 4338-4344.

膜材料	制备方法	分离物系	测试条件	CO₂渗透通量/GPU	选择因子	参考文献
纳米孔石墨烯膜	聚焦离子束轰击	H₂/CO₂	室温，2bar	6.4×10⁶	4.69	［30］
PEI修饰的纳米孔石墨烯	氧等离子体刻蚀	CO₂/N₂	30℃，2bar	6180	22.5	［31］
GO膜	喷涂法	H₂/CO₂	25℃，1bar	3.88	20.9	［33］
GO膜	真空抽滤法	H₂/CO₂	20℃，1bar	0.09	3400	［39］
GO膜	真空抽滤法	H₂/CO₂	室温，Ar吹扫	11.4	35.3	［41］
GO膜	真空抽滤法	H₂/CO₂	室温，Ar吹扫	4.25	240	［44］
哌嗪修饰的GO膜	真空抽滤法	CO₂/N₂	室温，He吹扫	1020	680	［46］
乙二胺修饰的GO膜	真空抽滤法	CO₂/N₂	75℃，He吹扫	660	500	［47］
硼酸盐修饰的GO膜	真空抽滤法	CO₂/CH₄	30℃，1bar	650	75	［48］
Zn²⁺修饰的GO膜	真空抽滤法	CO₂/CH₄	30℃，1.5bar	175	19.1	［49］
离子液体修饰的GO膜	真空抽滤法	CO₂/N₂	室温，1bar	68.5	382	［53］

膜材料	制备方法	分离物系	测试条件	CO₂渗透通量/GPU	选择因子	参考文献
纳米孔石墨烯膜	聚焦离子束轰击	H₂/CO₂	室温，2bar	6.4×10⁶	4.69	［30］
PEI修饰的纳米孔石墨烯	氧等离子体刻蚀	CO₂/N₂	30℃，2bar	6180	22.5	［31］
GO膜	喷涂法	H₂/CO₂	25℃，1bar	3.88	20.9	［33］
GO膜	真空抽滤法	H₂/CO₂	20℃，1bar	0.09	3400	［39］
GO膜	真空抽滤法	H₂/CO₂	室温，Ar吹扫	11.4	35.3	［41］
GO膜	真空抽滤法	H₂/CO₂	室温，Ar吹扫	4.25	240	［44］
哌嗪修饰的GO膜	真空抽滤法	CO₂/N₂	室温，He吹扫	1020	680	［46］
乙二胺修饰的GO膜	真空抽滤法	CO₂/N₂	75℃，He吹扫	660	500	［47］
硼酸盐修饰的GO膜	真空抽滤法	CO₂/CH₄	30℃，1bar	650	75	［48］
Zn²⁺修饰的GO膜	真空抽滤法	CO₂/CH₄	30℃，1.5bar	175	19.1	［49］
离子液体修饰的GO膜	真空抽滤法	CO₂/N₂	室温，1bar	68.5	382	［53］

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Recent advances in graphene-based membranes for CO₂ separation

石墨烯基材料在CO₂分离膜领域的研究进展

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