PUBLICATIONS
[55] Observed Photoenhancement of RAFT Polymerizations under Fume Hood Lighting. L. P. da M. Costa, T. G. McKenzie, K.N. Schwarz, Q. Fu, G. G. Qiao, ACS Macro. Lett., (2016) 5: 1287-1292.
[54] The use of reduced copper metal–organic frameworks to facilitate CuAAC click chemistry. Q. Fu, K. Xie, S. Tan, J. M. Ren, Q. Zhao, P. A. Webley, G. G. Qiao, Chem. Commun., (2016) 52: 12226-12229.
[53] Blends of Fluorinated Additives with Highly Selective Thin-Film Composite Membranes to Increase CO2 Permeability for CO2/N2 Gas Separation Applications. J. M. P. Scofield, P. A. Gurr, J. Kim, Q. Fu, S. E. Kentish, G. G. Qiao, Ind. Eng. Chem. Res., (2016) 55: 8364-8372.
[52] Investigation into the photolytic stability of RAFT agents and the implications for photopolymerization reactions. T. G. McKenzie, L. P. da M. Costa, Q. Fu, D. E. Dunstan, G. G. Qiao, Polym. Chem., (2016) 7: 4246-4253.
[51] Star Polymers. J. M. Ren, T. G. McKenzie, Q. Fu, E. H. H. Wong, J. Xu, Z. An, S. Shanmugam, T. P. Davis, C. Boyer, G. G. Qiao, Chem. Rev., (2016) 116: 6743-6836.
[50] CO2 separation using surface-functionalized SiO2 nanoparticles incorporated ultrathin film composite mixed matrix membranes for post-combustion carbon capture. J. Kim, Q. Fu, K. Xie, J. M. P. Scofield, S. E. Kentish, G. G. Qiao, J. Membr. Sci., (2016) 515: 54-62.
[49] Spatial-controlled nanoengineered films prepared via rapid catalyst induced cross-linking. E. Nam, E. H. H. Wong, S. Tan, S. N. Guntari, Q. Fu, J. Kim, B. Delalat, A. Blencowe, G.G. Qiao, Polym. Chem., (2016) 7: 3251-3258.
[48] Polypeptide-Based Macroporous Cryogels with Inherent Antimicrobial Properties: The Importance of a Macroporous Structure. S. J. Shirbin, S. J. Lam, N. Chan, M. M. Ozmen, Q. Fu, N. O’Brien-Simpson, E. C. Reynolds, G. G. Qiao, ACS Macro Lett., (2016) 5: 552-557.
[47] Beyond traditional RAFT: Alternative Activation of Thiocarbonylthio Compounds for Controlled Polymerization. T. G. McKenzie, Q. Fu, M. Uchiyama, K. Satoh, J. Xu, C. Boyer, M. Kamigaito, G. G. Qiao, Adv. Sci., (2016) 4: 1500394.
[46] Ultra-thin film composite mixed matrix membranes incorporating iron(III)–dopamine nanoparticles for CO2 separation. J. Kim, Q. Fu, J. M. P. Scofield, S. E. Kentish, G. G. Qiao. Nanoscale, (2016) 8: 8312-8323.
[45] Fractionation of graphene oxide single nano-sheets in water-glycerol solutions using gradient centrifugation. E. Bidram, A. Sulistio, A. Amini, Q. Fu, G. G. Qiao, A. Stewart, D. E. Dunstan. Carbon, (2016) 103: 363-371.
[44] Photocontrolled Cargo Release from Dual Cross-Linked Polymer Particles. S. Tan, J. Cui, Q. Fu, E. Nam, K. Ladewig, J. M. Ren, E. H. H. Wong, F. Caruso, A. Blencowe, G. G. Qiao. ACS Appl. Mater. Interfaces, (2016) 8: 6219-6228.
[43] A novel solid state photocatalyst for living radical polymerization under UV irradiation. Q. Fu, T. G. McKenzie, J. M. Ren, S. Tan, E. Nam, G. G. Qiao, Sci. Rep., (2016) 6: 20779.
[42] Stereoregular High-Density Bottlebrush Polymer and Its Organic Nanocrystal Stereocomplex through Triple-Helix Formation. J. M. Ren, K. Ishitake, K. Satoh, A. Blencowe, Q. Fu, E. H. H. Wong, M. Kamigaito and G. G. Qiao, Macromolecules, (2016) 49: 788–795.
[41] A novel cross-linked nano-coating for carbon dioxide capture. Q. Fu, J. Kim, P. A. Gurr, J. M. P. Scofield, S. E. Kentish, G. G. Qiao, Energy Environ. Sci., (2016) 9: 434-440. Cover Article.
[40] Development of novel fluorinated additives for high performance CO2 separation thin-film composite membranes. J. M. P. Scofield, P. A. Gurr, J. Kim, Q. Fu, S. E. Kentish, G. G. Qiao, J. Membr. Sci., (2016) 499: 191-200.
[39] A rapid and facile preparation of novel macroporous silicone-based cryogels via photo-induced thiol-ene click chemistry. M. M. Ozmen, Q. Fu, J. Kim and G. G. Qiao, Chem. Commun., (2015) 51:17479-17482.
[38] Synthesis of well dispersed polymer grafted metal–organic framework nanoparticles. K. Xie, Q. Fu, Y. He, J. Kim, S. Jin Goh, E. Nam, G. G. Qiao, P. A. Webley, Chem. Commun., (2015) 51: 15566-15569.
[37] Controlled Formation of Star Polymer Nanoparticles via Visible Light Photopolymerization. T. G. McKenzie, E. H. H. Wong, Q. Fu, A. Sulistio, D. E. Dunstan, G. G. Qiao, ACS Macro. Lett., (2015) 4: 1012-1016.
[36] Cisplatin-Induced Formation of Biocompatible and Biodegradable Polypeptide-Based Vesicles for Targeted Anticancer Drug Delivery. S. J. Shirbin, K. Ladewig, Q. Fu, M. Klimak, X. Zhang, W.Duan and G. G. Qiao, Biomacromolecules, (2015) 16: 2463–2474.
[35] Tertiary amine catalyzed photo-induced controlled radical polymerization of methacrylates. Q. Fu, T. G. McKenzie, S. Tan, E. Nam, G. G. Qiao. Polym. Chem., (2015) 6: 5362-5368.
[34] Cyclodextrin-based supramolecular polymeric nanoparticles for next generation gas separation membranes. S. Tan,† Q. Fu,† J. Scofield, J. Kim, P. Andrew Gurr, K. Ladewig, A. Blencowe, G.G Qiao. J. Mater. Chem. A, (2015) 3: 14876-14886.
[33] Visible light mediated controlled radical polymerization in the absence of exogenous radical sources or catalysts. T. G. McKenzie, Q. Fu, E. H. H. Wong, D. E. Dunstan, G. G. Qiao. Macromolecules, (2015) 48: 3864-3872.
[32] Synthesis of perfectly alternating copolymers for polymers of intrinsic microporosity. J. Zhang, J. Jin, R. Cooney, Q. Fu, G. G Qiao, S. Thomas, T. Merkel. Polym. Chem., (2015) 6: 5003-5008.
[31] High-performance thin film composite membranes with well-defined poly(dimethylsiloxane)-b-poly(ethylene glycol) copolymer additives for CO2 separation. J. M. P. Scofield, P. A. Gurr, J. Kim, Q. Fu, A. Halim, S. E. Kentish, G. G. Qiao. J. Polym. Sci., Part A: Polym. Chem., (2015) 53: 1500-1511.
[30] Fabrication of ultra-thin polyrotaxane-based films via solid-state continuous assembly of polymers. S. Tan, E. Nam, J. Cui, C. Xu, Q. Fu, J. M. Ren, E. H. H. Wong, K. Ladewig, F. Caruso, A. Blencowe, G. G. Qiao. Chem. Commun., (2015) 51: 2025-2028.
[29] Degradable cross-linked polymer vesicles for the efficient delivery of platinum drugs. Q. Fu, J. Xu, K. Ladewig, T. M. A. Henderson, G. G. Qiao, Polym. Chem. (2015) 6: 35-43. Cover Article.
[28] Soft nanoparticles assembled from linear poly (ethylene glycol) and linear brush polydimethylsiloxane diblock copolymers. A. Halim, T. D. Reid, J. Ren, Q. Fu, P. A. Gurr, A. Blencowe, S. E. Kentish, G. G. Qiao. J. Polym. Sci., Part A: Polym. Chem., (2014) 52: 1251-1262.
[27] Azobenzene-Functionalised Core Cross-Linked Star Polymers and their Host–Guest Interactions. S. Tan, E. H. H. Wong, Q. Fu, J. M. Ren, A. Sulistio, K. Ladewig, A. Blencowe, G. G. Qiao, Aust. J. Chem., (2014) 67: 173-178.
[26] Highly efficient and versatile formation of biocompatible star polymers in pure water and their stimuli-responsive self-assembly. T. G. McKenzie, E. H. H. Wong, Q. Fu, S. J. Lam, D. E. Dunstan, G. G. Qiao. Macromolecules, (2014) 47: 7869-7877.
[25] Polyimide polydimethylsiloxane triblock copolymers for thin film composite gas separation membranes. P. A. Gurr, J. M. P. Scofield, J. Kim, Q. Fu, S. E. Kentish, G. G. Qiao. J. Polym. Sci., Part A: Polym. Chem., (2014) 52: 3372-3382.
[24] The effect of soft nanoparticle morphologies on thin film composite membrane performance. Q. Fu, E. H. H. Wong, J. Kim, J. M. P. Scofield, P. A. Gurr, S. E. Kentish, G. G. Qiao. J. Mater. Chem. A, (2014) 2: 17751-17756.
[23] Dynamic Performance of Duolayers at the Air/Water Interface. 1. Experimental Analysis. A. H. M. Leung, E. L. Prime, D. N. H. Tran, Q. Fu, A. J. Christofferson, G. Yiapanis, I. Yarovsky, G. G. Qiao, D. H. Solomon, J. Phys. Chem. B, (2014) 37: 10919-10926.
[22] Continuous assembly of polymers via solid phase reactions. E. Nam, J. Kim, S. N. Guntari, H. Seyler, Q. Fu, E. H. H. Wong, A. Blencowe, D. J. Jones, F. Caruso, G. G. Qiao. Chem. Sci., (2014) 5: 3374-3380.
[21] Cyclodextrin-Based Supramolecular Assemblies and Hydrogels: Recent Advances and Future Perspectives. S. Tan, K. Ladewig, Q. Fu, A. Blencowe, G. G. Qiao, Macromol. Rapid Commun., (2014) 35: 1166-1184. Cover Article.
[20] Soft polymeric nanoparticles additives for next generation gas separation membranes. A. Halim, Q. Fu, Q. Yong, P. A. Gurr, S. E. Kentish, G. G. Qiao. J. Mater. Chem. A, (2014) 2: 4999-5009.
[19] Novel drug carriers: from grafted polymers to cross-linked vesicles. J. Xu, Q. Fu, J. M. Ren, G. Bryant, G. G. Qiao, Chem. Commun., (2013) 49: 33-35.
[18] Highly permeable membrane materials for CO2 capture. Q. Fu, A. Halim, J. Kim, J. M. P. Scofield, P. A. Gurr, S. E. Kentish, G. G. Qiao. J. Mater. Chem. A, (2013) 1: 13769-13778.
[17] Synthesis of novel core cross-linked star (CCS)-based polyrotaxane end-capped via ‘CuAAC’ click chemistry. Q. Fu, J. Ren, S. Tan, J. Xu, G. G. Qiao. Macromol. Rapid Commum., (2012) 33: 2109-2114.
[16] Organic catalyst-mediated ring-opening polymerization for the highly efficient synthesis of polyester-based star polymers. J. M. Ren, Q. Fu, A. Blencowe, G. G. Qiao. ACS Macro. Lett., (2012) 1: 681-686.
[15] Synthesis of novel cylindrical bottlebrush polypseudorotaxane via inclusion complexation of high density poly(ε-caprolactone) bottlebrush polymer and α-cyclodextrins. Q. Fu, J. M. Ren, G. G. Qiao. Polym. Chem., (2012) 3: 343-351.
[14] The effect of acrylamide-co-vinylpyrrolidinone copolymer on the depression of talc in mixed nickel mineral flotation. A. Leung, J. Wiltshire, A. Blencowe, Q. Fu, D. H Solomon, G. G. Qiao, Miner. Eng., (2011) 24: 449-454.
[13] A Simple Way for Synthesis of Alkyne‐Telechelic Poly (methyl methacrylate) via Single Electron Transfer Radical Coupling Reaction. Z. Zhang, Q. Fu, J. Huang, Chinese J. Chem., (2010) 28: 1327-1330.
[12] Investigation of nitroxide radical coupling reaction in wide temperature range and different catalyst system. W. C. Lin, B. Huang, Q. Fu, J. L. Huang. J. Polym. Sci.; Part A: Polym. Chem., (2010) 48: 2991-2999.
[11] Single electron transfer nitroxide radical coupling reaction at ambient temperature: application in the synthesis of block copolymers. Q. Fu, Z. N. Zhang, W. C. Lin, J. L. Huang. Macromolecules, (2009) 42: 4381-4383.
[10] One-pot preparation of 3-miktoarm star terpolymers via ‘click chemistry’ and atom transfer nitroxide radical coupling reaction. Q. Fu, G. Wang, W. C. Lin, J. L. Huang. J. Polym. Sci.; Part A: Polym. Chem., (2009) 47: 986-990.
[9] One-pot synthesis of heterograft copolymers via ‘graft onto’ by atom transfer nitroxide radical coupling chemistry. Q. Fu, C. Liu, W. C. Lin, J. L. Huang. J. Polym. Sci.; Part A: Polym. Chem., (2008) 46: 6770-6779.
[8] One-pot synthesis of ABC type triblock copolymers via a combination of ‘click chemistry’ and atom transfer nitroxide radical coupling chemistry. W. C. Lin, Q. Fu, Y. Zhang, J. L. Huang. Macromolecules, (2008) 41: 4127-4135.
[7] A New Strategy for Preparation of Graft Copolymers via “Graft onto” by Atom Transfer Nitroxide Radical Coupling Chemistry: Preparation of Poly(4-glycidyloxy-2,2,6,6-tetramethylpiperidine-1-oxyl-co-ethylene oxide)-graft-polystyrene and Poly(tert-butyl acrylate). Q. Fu, W. C. Lin, J. L. Huang. Macromolecules, (2008) 41: 2381-2387.
[6] Synthesis of a thioether modified hyperbranched polyglycerol and its template effect on fabrication of CdS and CdSe nanoparticles. D. Wan, Q. Fu, J. Huang, J. Appl. Polym. Sci., (2006) 102: 3679-3684.
[5] Synthesis and self-assembly morphologies of amphiphilic multiblock copolymers [poly (ethylene oxide)-b-polystyrene](n) via trithiocarbonate-embedded PEO macro-RAFT agent. Z. F. Jia, X. W. Xu, Q. Fu, J. L. Huang. J. Polym. Sci.; Part A: Polym. Chem., (2006) 44: 6071-6082.
[4] Synthesis of amphiphilic macrocyclic graft copolymer consisting of a poly(ethylene oxide) ring and multi-polystyrene lateral chains. Z. F. Jia, Q. Fu, J. L. Huang. Macromolecules, (2006) 39: 5190-5193.
[3] Synthesis of amphiphilic hyperbranched polyglycerol polymers and their application as template for size control of gold nanoparticles. D. Wan, Q. Fu, J. Huang, J. Appl. Polym. Sci., (2006) 101: 509-514.
[2] Synthesis of poly(ethylene oxide) with pending 2,2,6,6-tetramethylpiperidine-1-oxyl groups and its further initiation of the grafting polymerization of styrene. Z. F. Jia, Q. Fu, J. L. Huang. J. Polym. Sci.; Part A: Polym. Chem., (2006) 44: 3836-3842.
[1] Synthesis of a thermoresponsive shell cross-linked 3-layer onion-like polymer particle with a hyperbranched polyglycerol core. D. C. Wan, Q. Fu, J. L. Huang, J. Polym. Sci.; Part A: Polym. Chem., (2005) 43: 5652-5660.