4(%3)3 - Ecole nationale supÃ©rieure de chimie de Montpellier

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In conclusion, a self-healing membrane with tunable porosity based on dynamic set ofnanometric block copolymer micelles has been described. The membrane shows the capacity to selfregulateits performance in response to applied water pressure. The proof of the pore size tuning andmost important its functional applicability is demonstrated by the filtration experiments of PEO polymersaccording to their size through membranes previously subjected to various water pressures. Despite thelow permeabilities 27,29 (i.e. 13.4 L.h -1 .m -2 bar -1 for the adaptive spherical-type membranes and 40 L.h -1 .m -2bar -1 for the very stable worm-like membranes), the reversible sharp change in the membraneperformance controlled via operating conditions is quite remarkable. Moreover the membrane exhibitscapacity to mend itself at the macroscopic level. The production of such self-healable films to be used inmembrane science can prolong their usable life in a given application without any other externalintervention. The use of block copolymer micelles with adaptive behaviors under compression showssome formal similarity with the functional complexity of natural systems for which the communicationbetween different length scales is the central point of the natural selections of functions 2,40 .72
REFERENCES1 Lehn, J.-M. From supramolecular chemistry towards constitutional dynamic chemistry and adaptivechemistry. Chemical Society Reviews 36, doi:10.1039/b616752g (2007).2 Rybtchinski, B. Adaptive Supramolecular Nanomaterials Based on Strong Noncovalent Interactions. AcsNano 5, 6791-6818, doi:10.1021/nn2025397 (2011).3 Tauk, L., Schroeder, A. P., Decher, G. & Giuseppone, N. Hierarchical functional gradients of pH-responsiveself-assembled monolayers using dynamic covalent chemistry on surfaces. Nature Chemistry 1,doi:10.1038/nchem.400 (2009).4 Mann, S. Self-assembly and transformation of hybrid nano-objects and nanostructures under equilibriumand non-equilibrium conditions. Nature Materials 8, doi:10.1038/nmat2496 (2009).5 Kim, B. S. et al. Design of artificial extracellular matrices for tissue engineering. Progress in Polymer Science36, 238-268, doi:10.1016/j.progpolymsci.2010.10.001 (2011).6 Oda, T. et al. Effectiveness of near-infrared spectroscopy during surgical repair of tracheo-innominateartery fistula. Journal of Artificial Organs 14, doi:10.1007/s10047-011-0565-9 (2011).7 Kaur, P., Hupp, J. T. & Nguyen, S. T. Porous Organic Polymers in Catalysis: Opportunities and Challenges.Acs Catalysis 1, doi:10.1021/cs200131g (2011).8 Jackson, E. A. & Hillmyer, M. A. Nanoporous Membranes Derived from Block Copolymers: From DrugDelivery to Water Filtration. Acs Nano 4, doi:10.1021/nn1014006 (2010).9 Krieg, E., Weissman, H., Shirman, E., Shimoni, E. & Rybtchinski, B. A recyclable supramolecular membranefor size-selective separation of nanoparticles. Nature Nanotechnology 6, doi:10.1038/nnano.2010.274(2011).10 Stein, A. Advances in microporous and mesoporous solids - Highlights of recent progress. AdvancedMaterials 15, doi:10.1002/adma.200300007 (2003).11 Guimard, N. K. et al. Current Trends in the Field of Self-Healing Materials. Macromolecular Chemistry andPhysics 213, 131-143, doi:10.1002/macp.201100442 (2012).12 Wu, D. Y., Meure, S. & Solomon, D. Self-healing polymeric materials: A review of recent developments.Progress in Polymer Science 33, 479-522, doi:10.1016/j.progpolymsci.2008.02.001 (2008).13 Ma, M. & Hill, R. M. Superhydrophobic surfaces. Current Opinion in Colloid & Interface Science 11,doi:10.1016/j.cocis.2006.06.002 (2006).14 Ogawa, T., Ding, B., Sone, Y. & Shiratori, S. Super-hydrophobic surfaces of layer-by-layer structured filmcoatedelectrospun nanofibrous membranes. Nanotechnology 18, doi:10.1088/0957-4484/18/16/165607(2007).15 He, D., Susanto, H. & Ulbricht, M. Photo-irradiation for preparation, modification and stimulation ofpolymeric membranes. Progress in Polymer Science 34, doi:10.1016/j.progpolymsci.2008.08.004 (2009).16 Persson, K. M., Gekas, V. & Tragardh, G. STUDY OF MEMBRANE COMPACTION AND ITS INFLUENCE ONULTRAFILTRATION WATER PERMEABILITY. Journal of Membrane Science 100, doi:10.1016/0376-7388(94)00263-x (1995).17 Ebert, K., Fritsch, D., Koll, J. & Tjahjawiguna, C. Influence of inorganic fillers on the compaction behaviourof porous polymer based membranes. Journal of Membrane Science 233,doi:10.1016/j.memsci.2003.12.012 (2004).18 Yang, Q., Adrus, N., Tomicki, F. & Ulbricht, M. Composites of functional polymeric hydrogels and porousmembranes. Journal of Materials Chemistry 21, doi:10.1039/c0jm02234a (2011).19 Tokarev, I. & Minko, S. Multiresponsive, Hierarchically Structured Membranes: New, Challenging,Biomimetic Materials for Biosensors, Controlled Release, Biochemical Gates, and Nanoreactors. AdvancedMaterials 21, doi:10.1002/adma.200801408 (2009).20 Quemener, D. et al. Free-Standing Nanomaterials from Block Copolymer Self-Assembly. Macromolecules43, doi:10.1021/ma100809v (2010).21 Jain, S. & Bates, F. S. Consequences of nonergodicity in aqueous binary PEO-PB micellar dispersions.Macromolecules 37, doi:10.1021/ma035467j (2004).22 He, Y. Y., Li, Z. B., Simone, P. & Lodge, T. P. Self-assembly of block copolymer micelles in an ionic liquid.Journal of the American Chemical Society 128, doi:10.1021/ja058091t (2006).73
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THESISPRESENTED ATNATIONAL GRADUATE
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As the human civilization progress
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CHAPTER - 1 SELF-HEALING POLYMERIC
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8.1.5 Atomic Force Microscopy …
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Synthetic engineering materials in
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esponse to a specific external stim
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The first work based on this approa
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een prepared from urea-formaldehyde
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monomer systems. The addition of EN
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Figure - 1.10: Self-healing process
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was required to reach healing effic
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In addition to above works, some ot
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that have been identified to be tak
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part of the chapter, these material
Page 31 and 32: Figure - 1.17: Self-healing of the
Page 33 and 34: commercialized under tradenames; Nu
Page 35 and 36: joined together at temperature high
Page 37 and 38: Inspired by these findings, the fir
Page 39 and 40: temperature greater than 80 o C in
Page 41 and 42: Figure - 1.27: Sulfur chemistry bas
Page 43 and 44: A different kind of sulfur chemistr
Page 45 and 46: Figure - 1.29: Dynamic covalent che
Page 47 and 48: cracks. The recovered droplets afte
Page 49 and 50: 23 White, S. R. et al. Autonomic he
Page 51 and 52: 65 Taber, D. F. & Frankowski, K. J.
Page 53 and 54: 107 Kushner, A. M., Vossler, J. D.,
Page 55: 148 Park, J. S., Kim, H. S. & Hahn,
Page 58 and 59: The value of subscripts “n”,
Page 60 and 61: The formation of spherical micelles
Page 62 and 63: the micelle assembly showed the pre
Page 64 and 65: gain onto the electrodes by buildin
Page 66 and 67: The resistance R can be further exp
Page 68 and 69: empty-tower velocity U only depends
Page 70 and 71: This apparent morphological switchi
Page 72 and 73: In a further qualitative analysis,
Page 74 and 75: noteworthy and though its feasibili
Page 76 and 77: Furthermore within this range, lowe
Page 78 and 79: Figure - 2.22: Scanning Electron Mi
Page 80 and 81: While the resistance measurements g
Page 84 and 85: 23 Giacomelli, F. C., Riegel, I. C.
Page 86 and 87: micelles enabled the membrane to se
Page 88 and 89: The second class is represented by
Page 90 and 91: To avoid the probable clogging of t
Page 92 and 93: 181614SP2 - iNumber of Particles121
Page 94 and 95: 1000900800y = 3E+06xR² = 0,9911y =
Page 96 and 97: very high value of 1.5 g.l -1 . Thi
Page 98 and 99: Since the only change in the membra
Page 100 and 101: 100Retention (%)8060400,100,20,40,6
Page 104 and 105: (Figure - 3.20). A cursory look at
Page 106 and 107: When compared to poly(styrene) NPs,
Page 110 and 111: REFERENCES1 Metzler, R. & Klafter,
Page 112 and 113: 46 Bemporad, D., Luttmann, C. & Ess
Page 114 and 115: In this chapter, preparation of 3D
Page 116 and 117: obtain complex macromolecular archi
Page 118 and 119: The polymerization was conducted at
Page 120 and 121: proceeds, lesser monomer is availab
Page 122 and 123: mg/ml),the micelles’ hydrodynamic
Page 124 and 125: Figure - 4.15: The monolayer and mu
Page 126 and 127: monolayer of micelles and topmost l
Page 128 and 129: The presence of the dispersed micel
Page 130 and 131: Heating the multilayer micelle asse
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stable zipping of the micelles. Mul
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24 Moad, G., Rizzardo, E. & Thang,
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The concept of nano-gel based self-
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Figure - 5.4: Size distribution of
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In a typical process, the two compo
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Figure - 5.10: 1HNMR spectra obtain
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The 1 HNMR spectrum obtained for th
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REFERENCES1 White, S. R. et al. Aut
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healing ability shown by the membra
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7. PERSPECTIVESBeing the first such
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8. MATERIALS & METHODSThis chapter
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8.1.3 PEG Filtration MeasurementsTh
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addition of TEOS due to formation o
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solution was ultrasonicated for 15
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Triethylamine (TEA) (Sigma-Aldrich
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To prepare the monolayer assembly o
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was added followed by addition of 0
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ELABORATION OF SELF-HEALING POLYMER
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ELABORATION DES MEMBRANES POLYMERES
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4(%3)3 - Ecole nationale supÃ©rieure de chimie de Montpellier

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