[1] |
D'Alessandro D M, Smit B, Long J R. Carbon dioxide capture: prospects for new materials[J]. Angewandte Chemie International Edition, 2010, 49(35): 6058-6082
|
[2] |
Dawson R, Cooper A I, Adams D J. Chemical functionalization strategies for carbon dioxide capture in microporous organic polymers[J]. Polymer International, 2013, 62(3): 345-352
|
[3] |
Sumida K, Rogow D L, Mason J A, McDonald T M, Bloch E D, Herm Z R, Bae T H, Long J R. Carbon dioxide capture in metal-organic frameworks[J]. Chemical Reviews, 2011, 112(2): 724-781
|
[4] |
Wang Q, Luo J, Zhong Z, Borgna A. CO2 capture by solid adsorbents and their applications: current status and new trends[J]. Energy & Environmental Science, 2011, 4(1): 42-55
|
[5] |
Yang J, Li J, Wang W, Li L, Li J. Adsorption of CO2, CH4, and N2 on 8-, 10-, and 12-membered ring hydrophobic microporous high-silica zeolites: DDR, silicalite-1, and beta[J]. Industrial & Engineering Chemistry Research, 2013, 52(50): 17856-17864
|
[6] |
Zhu X, Hillesheim P C, Mahurin S M, Wang C, Tian C, Brown S, Luo H, Veith G M, Han K S, Hagaman E W, Liu H, Dai S. Efficient CO2 capture by porous, nitrogen-doped carbonaceous adsorbents derived from task-specific ionic liquids[J]. ChemSusChem, 2012, 5(10): 1912-1917
|
[7] |
Hicks J C, Drese J H, Fauth D J, Gray M L, Qi G, Jones C W. Designing adsorbents for CO2 capture from flue gas-hyperbranched aminosilicas capable of capturing CO2 reversibly[J]. Journal of the American Chemical Society, 2008, 130(10): 2902-2903
|
[8] |
Yang Q, Liu D, Zhong C, Li J R. Development of computational methodologies for metal-organic frameworks and their application in gas separations[J]. Chemical Reviews, 2013, 113(10): 8261-8323
|
[9] |
Xiang Z, Cao D. Porous covalent-organic materials: synthesis, clean energy application and design[J]. Journal of Materials Chemistry A, 2013, 1(8): 2691-2718
|
[10] |
Dawson R, Cooper A I, Adams D J. Nanoporous organic polymer networks[J]. Progress in Polymer Science, 2012, 37(4): 530-563
|
[11] |
Côté A P, Benin A I, Ockwig N W, O'Keeffe M, Matzger A J, Yaghi O M. Porous, crystalline, covalent organic frameworks[J]. Science, 2005, 310(5751): 1166-1170
|
[12] |
Cooper A I. Conjugated microporous polymers[J]. Advanced Materials, 2009, 21(12): 1291-1295
|
[13] |
Luo Y, Li B, Wang W, Wu K, Tan B. Hypercrosslinked aromatic heterocyclic microporous polymers: a new class of highly selective CO2 capturing materials[J]. Advanced Materials, 2012, 24(42): 5703-5707
|
[14] |
Du N, Park H B, Dal-Cin M M, Guiver M D. Advances in high permeability polymeric membrane materials for CO2 separations[J]. Energy & Environmental Science, 2012, 5(6): 7306-7322
|
[15] |
Ben T, Ren H, Ma S, Cao D, Lan J, Jing X, Wang W, Xu J, Deng F, Simmons J M, Qiu S, Zhu G. Targeted synthesis of a porous aromatic framework with high stability and exceptionally high surface area[J]. Angewandte Chemie International Edition, 2009, 48(50): 9457-9460
|
[16] |
Yuan D, Lu W, Zhao D, Zhou H C. Highly stable porous polymer networks with exceptionally high gas-uptake capacities[J]. Advanced Materials, 2011, 23(32): 3723-3725
|
[17] |
Lu W, Yuan D, Sculley J, Zhao D, Krishna R, Zhou H C. Sulfonate-grafted porous polymer networks for preferential CO2 adsorption at low pressure[J]. Journal of the American Chemical Society, 2011, 133(45): 18126-18129
|
[18] |
Lu W, Verdegaal W M, Yu J, Balbuena P B, Jeong H K, Zhou H C. Building multiple adsorption sites in porous polymer networks for carbon capture applications[J]. Energy & Environmental Science, 2013, 6(12): 3559-3564
|
[19] |
Lu W, Sculley J P, Yuan D, Krishna R, Wei Z, Zhou H C. Polyamine-tethered porous polymer networks for carbon dioxide capture from flue gas[J]. Angewandte Chemie International Edition, 2012, 51(30): 7480-7484
|
[20] |
Dawson R, Adams D J, Cooper A I. Chemical tuning of CO2 sorption in robust nanoporous organic polymers[J]. Chemical Science, 2011, 2(6): 1173-1177
|
[21] |
Rabbani M G, El-Kaderi H M. Synthesis and characterization of porous benzimidazole-linked polymers and their performance in small gas storage and selective uptake[J]. Chemistry of Materials, 2012, 24(8): 1511-1517
|
[22] |
Patel H A, Hyun Je S, Park J, Chen D P, Jung Y, Yavuz C T, Coskun A. Unprecedented high-temperature CO2 selectivity in N2-phobic nanoporous covalent organic polymers[J]. Nature Communication, 2013, 4: 1357
|
[23] |
Zhu X, Do-Thanh C L, Murdock C R, Nelson K M, Tian C, Brown S, Mahurin S M, Jenkins D M, Hu J, Zhao B, Liu H, Dai S. Efficient CO2 capture by a 3D porous polymer derived from Tröger's base[J]. ACS Macro Letters, 2013, 2(8): 660-663
|
[24] |
Li B, Gong R, Wang W, Huang X, Zhang W, Li H, Hu C, Tan B. A new strategy to microporous polymers: knitting rigid aromatic building blocks by external cross-linker[J]. Macromolecules, 2011, 44(8): 2410-2414
|
[25] |
Dawson R, Stevens L A, Drage T C, Snape C E, Smith M W, Adams D J, Cooper A I. Impact of water coadsorption for carbon dioxide capture in microporous polymer sorbents[J]. Journal of the American Chemical Society, 2012, 134(26): 10741-10744
|
[26] |
Dawson R, Ratvijitvech T, Corker M, Laybourn A, Khimyak Y Z, Cooper A I, Adams D J. Microporous copolymers for increased gas selectivity[J]. Polymer Chemistry, 2012, 3(8): 2034-2038
|
[27] |
Zhao Y, Yao K X, Teng B, Zhang T, Han Y. A perfluorinated covalent triazine-based framework for highly selective and water-tolerant CO2 capture[J]. Energy & Environmental Science, 2013, 6(12): 3684-3692
|
[28] |
Mohanty P, Kull L D, Landskron K. Porous covalent electron-rich organonitridic frameworks as highly selective sorbents for methane and carbon dioxide[J]. Nature Communication, 2011, 2: 401
|
[29] |
Chen Q, Luo M, Hammershøj P, Zhou D, Han Y, Laursen B W, Yan C G, Han B H. Microporous polycarbazole with high specific surface area for gas storage and separation[J]. Journal of the American Chemical Society, 2012, 134(14): 6084-6087
|
[30] |
Arab P, Rabbani M G, Sekizkardes A K, ?slamo?lu T, El-Kaderi H M. Copper(I)-catalyzed synthesis of nanoporous azo-linked polymers: impact of textural properties on gas storage and selective carbon dioxide capture[J]. Chemistry of Materials, 2014, 26(3): 1385-1392
|
[31] |
Lu W, Sculley J P, Yuan D, Krishna R, Wei Z, Zhou H C. Polyamine-tethered porous polymer networks for carbon dioxide capture from flue gas[J]. Angewandte Chemie International Edition, 2012, 51(30): 7480-7484
|
[32] |
McKeown N B, Budd P M, Msayib K J, Ghanem B S, Kingston H J, Tattershall C E, Makhseed S, Reynolds K J, Fritsch D. Polymers of intrinsic microporosity(PIMs): bridging the void between microporous and polymeric materials[J]. Chemistry - A European Journal, 2005, 11(9): 2610-2620
|
[33] |
Du N, Park H B, Robertson G P, Dal-Cin M M, Visser T, Scoles L, Guiver M D. Polymer nanosieve membranes for CO2-capture applications[J]. Nature Material, 2011, 10(5): 372-375
|
[34] |
Carta M, Malpass-Evans R, Croad M, Rogan Y, Jansen J C, Bernardo P, Bazzarelli F, McKeown N B. An efficient polymer molecular sieve for membrane gas separations[J]. Science, 2013, 339(6117): 303-307
|
[35] |
Zhu X, Tian C, Mahurin S M, Chai S H, Wang C, Brown S, Veith G M, Luo H, Liu H, Dai S. A superacid-catalyzed synthesis of porous membranes based on triazine frameworks for CO2 separation[J]. Journal of the American Chemical Society, 2012, 134(25): 10478- 10484
|
[36] |
Kuhn P, Antonietti M, Thomas A. Porous, covalent triazine-based frameworks prepared by ionothermal synthesis[J]. Angewandte Chemie International Edition, 2008, 47(18): 3450-3453
|
[37] |
Zhu X, Tian C, Chai S, Nelson K, Han K S, Hagaman E W, Veith G M, Mahurin S M, Liu H, Dai S. New tricks for old molecules: development and application of porous N-doped, carbonaceous membranes for CO2 separation[J]. Advanced Materials, 2013, 25(30): 4152-4158
|