Coating of silica particles by fluorinated diblock copolymers and use of the resultant silica for superamphiphobic surfaces

“…With a less stringent polymerization procedure, namely ATRP, the same authors extended this polymer library to PIPSPMA‐ b ‐PFOEMA with higher DP (PIPSPMA 13 ‐ b ‐PFOEMA 30 , PIPSPMA 18 ‐ b ‐PFOEMA 22 , PIPSPMA 12 ‐ b ‐PFOEMA 30 , PIPSPMA 15 ‐ b ‐PFOEMA 31 and PIPSPMA 19 ‐ b ‐PFOEMA 23 ) but still low dispersities of 1.10–1.14. In this case, PIPSPMA‐ b ‐PFOEMA was synthesized by ATRP of IPSPMA from EBiB in the presence of CuCl/bpy and CuBr 2 in trifluorotoluene at 80 °C, followed by polymerization of FOEMA from the preformed PIPSPMA‐Cl macroinitiator under similar conditions . In addition, they synthesized poly[2‐(perfluorohexyl)ethyl acrylate]‐ b ‐poly[3‐(triisopropoxysilyl)propyl methacrylate] (PFHEA 21 ‐ b ‐PIPSMA 15 ), using CuBr/PMDETA‐mediated ATRP in trifluorotoluene at 80 °C for the synthesis of the PFEMA macroinitiator, followed by ATRP of IPSPMA in the same conditions except ligand bpy instead of PMDETA .…”

“…Fluorinated nano‐ and microarchitectures can also be obtained by modification of silica nano‐ or micro‐particles with diblock copolymers containing one perfluorinated block and one poly(organosilane). Indeed, by coating silica nanoparticles (≈325–460 nm) with PIPSPMA‐ b ‐PFOEMA, superamphiphobicity could be achieved in the films made thereof (Figure a) . The strategy could also be extended to the simultaneous coating of silica nanoparticles by two diblock copolymers, PIPSPMA‐ b ‐PFOEMA and PIPSPMA‐ b ‐P t BA or PIPSPMA‐ b ‐PFOEMA and PIPSPMA‐ b ‐PAA (obtained after deprotection of the tert ‐butyl groups of PIPSPMA‐ b ‐P t BA) allowing further tuning of the liquid repellent properties.…”

“…The polymerization was carried out in one-pot by sequential addition of IPSPMA and FOEMA after initiating the system with diphenylethenea nd sec-butyl lithium. [33] With al ess stringent polymerization procedure, namely ATRP,t he same authors extended this polymer library to PIPSPMA-b-PFOEMA with higher DP (PIPSPMA 13 -b-PFOEMA 30 , PIPSPMA 18 -b-PFOEMA 22 , [34] PIPSPMA 12 -b-PFOEMA 30 ,P IPSPMA 15b-PFOEMA 31 and PIPSPMA 19 -b-PFOEMA 23 [35] )b ut still low dispersities of 1.10-1.14. In this case, PIPSPMA-b-PFOEMA was synthesized by ATRP of IPSPMA from EBiB in the presence of CuCl/bpy and CuBr 2 in trifluorotoluene at 80 8C, followed by polymerization of FOEMA from the preformed PIPSPMA-Cl macroinitiator under similarc onditions.…”

“…In this case, PIPSPMA-b-PFOEMA was synthesized by ATRP of IPSPMA from EBiB in the presence of CuCl/bpy and CuBr 2 in trifluorotoluene at 80 8C, followed by polymerization of FOEMA from the preformed PIPSPMA-Cl macroinitiator under similarc onditions. [34,35] In addition, they synthesized poly [2-(perfluorohexyl)ethyl acrylate]-b-poly[3-(triisopropoxysilyl)propylm ethacrylate] (PFHEA 21 -b-PIPSMA 15 ), using CuBr/PMDETA-mediated ATRP in trifluorotoluene at 80 8C for the synthesis of the PFEMA macroinitiator, followed by ATRP of IPSPMA in the same conditions except ligand bpy instead of PMDETA. [36] PFHEA 21 -b-PIPSPMA 15 was obtained with dispersity of 1.61.…”

“…The synthesis of polymers based on ethylene oxide motif is not only limited to linear structures:m acromolecular engineering has been used to produce miktoarm and H-shapedp olymers based on such motifs.I ndeed, Ngai et al used aP EO-(Br)b-PS macroinitiator to synthesize miktoarm m-PEO 45 -b-PS 25-86 -b-PIPSPMA [25][26][27][28][29][30][31][32][33][34][35] triblock copolymers by bpy/CuBr mediated ATRP of IPSPMA in anisole at 80 8C. The diblock copolymer macroinitiator,n amely PEO-(Br)-b-PS, was synthesized via the esterification of PEO-(OH)-b-PS with 2-bromoisobutyryl bromide in dichloromethanea nd the PEO-(OH)-b-PS diblock copolymers bearing hydroxyl group on the junction point had been previously synthesized by the click reaction between aP EO bearing an azide and hydroxyl group and an a-alkynyl-w-diethylaminopolystyrene.…”

Hybrid Silicon‐Based Organic/Inorganic Block Copolymers with Sol–Gel Active Moieties: Synthetic Advances, Self‐Assembly and Applications in Biomedicine and Materials Science

“…With a less stringent polymerization procedure, namely ATRP, the same authors extended this polymer library to PIPSPMA‐ b ‐PFOEMA with higher DP (PIPSPMA 13 ‐ b ‐PFOEMA 30 , PIPSPMA 18 ‐ b ‐PFOEMA 22 , PIPSPMA 12 ‐ b ‐PFOEMA 30 , PIPSPMA 15 ‐ b ‐PFOEMA 31 and PIPSPMA 19 ‐ b ‐PFOEMA 23 ) but still low dispersities of 1.10–1.14. In this case, PIPSPMA‐ b ‐PFOEMA was synthesized by ATRP of IPSPMA from EBiB in the presence of CuCl/bpy and CuBr 2 in trifluorotoluene at 80 °C, followed by polymerization of FOEMA from the preformed PIPSPMA‐Cl macroinitiator under similar conditions . In addition, they synthesized poly[2‐(perfluorohexyl)ethyl acrylate]‐ b ‐poly[3‐(triisopropoxysilyl)propyl methacrylate] (PFHEA 21 ‐ b ‐PIPSMA 15 ), using CuBr/PMDETA‐mediated ATRP in trifluorotoluene at 80 °C for the synthesis of the PFEMA macroinitiator, followed by ATRP of IPSPMA in the same conditions except ligand bpy instead of PMDETA .…”

“…Fluorinated nano‐ and microarchitectures can also be obtained by modification of silica nano‐ or micro‐particles with diblock copolymers containing one perfluorinated block and one poly(organosilane). Indeed, by coating silica nanoparticles (≈325–460 nm) with PIPSPMA‐ b ‐PFOEMA, superamphiphobicity could be achieved in the films made thereof (Figure a) . The strategy could also be extended to the simultaneous coating of silica nanoparticles by two diblock copolymers, PIPSPMA‐ b ‐PFOEMA and PIPSPMA‐ b ‐P t BA or PIPSPMA‐ b ‐PFOEMA and PIPSPMA‐ b ‐PAA (obtained after deprotection of the tert ‐butyl groups of PIPSPMA‐ b ‐P t BA) allowing further tuning of the liquid repellent properties.…”

“…The polymerization was carried out in one-pot by sequential addition of IPSPMA and FOEMA after initiating the system with diphenylethenea nd sec-butyl lithium. [33] With al ess stringent polymerization procedure, namely ATRP,t he same authors extended this polymer library to PIPSPMA-b-PFOEMA with higher DP (PIPSPMA 13 -b-PFOEMA 30 , PIPSPMA 18 -b-PFOEMA 22 , [34] PIPSPMA 12 -b-PFOEMA 30 ,P IPSPMA 15b-PFOEMA 31 and PIPSPMA 19 -b-PFOEMA 23 [35] )b ut still low dispersities of 1.10-1.14. In this case, PIPSPMA-b-PFOEMA was synthesized by ATRP of IPSPMA from EBiB in the presence of CuCl/bpy and CuBr 2 in trifluorotoluene at 80 8C, followed by polymerization of FOEMA from the preformed PIPSPMA-Cl macroinitiator under similarc onditions.…”

“…In this case, PIPSPMA-b-PFOEMA was synthesized by ATRP of IPSPMA from EBiB in the presence of CuCl/bpy and CuBr 2 in trifluorotoluene at 80 8C, followed by polymerization of FOEMA from the preformed PIPSPMA-Cl macroinitiator under similarc onditions. [34,35] In addition, they synthesized poly [2-(perfluorohexyl)ethyl acrylate]-b-poly[3-(triisopropoxysilyl)propylm ethacrylate] (PFHEA 21 -b-PIPSMA 15 ), using CuBr/PMDETA-mediated ATRP in trifluorotoluene at 80 8C for the synthesis of the PFEMA macroinitiator, followed by ATRP of IPSPMA in the same conditions except ligand bpy instead of PMDETA. [36] PFHEA 21 -b-PIPSPMA 15 was obtained with dispersity of 1.61.…”

“…The synthesis of polymers based on ethylene oxide motif is not only limited to linear structures:m acromolecular engineering has been used to produce miktoarm and H-shapedp olymers based on such motifs.I ndeed, Ngai et al used aP EO-(Br)b-PS macroinitiator to synthesize miktoarm m-PEO 45 -b-PS 25-86 -b-PIPSPMA [25][26][27][28][29][30][31][32][33][34][35] triblock copolymers by bpy/CuBr mediated ATRP of IPSPMA in anisole at 80 8C. The diblock copolymer macroinitiator,n amely PEO-(Br)-b-PS, was synthesized via the esterification of PEO-(OH)-b-PS with 2-bromoisobutyryl bromide in dichloromethanea nd the PEO-(OH)-b-PS diblock copolymers bearing hydroxyl group on the junction point had been previously synthesized by the click reaction between aP EO bearing an azide and hydroxyl group and an a-alkynyl-w-diethylaminopolystyrene.…”

Hybrid Silicon‐Based Organic/Inorganic Block Copolymers with Sol–Gel Active Moieties: Synthetic Advances, Self‐Assembly and Applications in Biomedicine and Materials Science

Superamphiphobic Coatings from Combination of a Biomimetic Catechol‐Bearing Fluoropolymer and Halloysite Nanotubes

Fabrication of Superamphiphobic Surfaces via Spray Coating; a Review