of Polystyrene 4-arm Stars Synthesized by RAFT- Mediated Miniemulsions.

Similar documents
Accessory Publication

Supporting Information. Various Polystyrene Topologies Built from. Tailored Cyclic Polystyrene via CuAAC. Reactions.

Supporting Information

SUPPORTING INFORMATION

Supporting Information

Supporting Information

Supporting Information

ELECTRONIC SUPPORTING INFORMATION Pentablock star shaped polymers in less than 90 minutes via

Molecular weight of polymers. Molecular weight of polymers. Molecular weight of polymers. Molecular weight of polymers. H i

One-pot polymer brush synthesis via simultaneous isocyanate coupling chemistry and grafting from RAFT polymerization

Sequence-controlled methacrylic multiblock. copolymers via sulfur-free RAFT emulsion. polymerization

Utilization of star-shaped polymer architecture in the creation of high-density polymer

Supporting Information.

Supporting Information. Vesicles of double hydrophilic pullulan and. poly(acrylamide) block copolymers: A combination

Molecular Weight Distribution of Living Chains in Polystyrene Pre-pared by Atom Transfer Radical Polymerization

Blending conjugated polymers without phase separation for fluorescent colour tuning of polymeric materials through FRET

Supporting Information. Precise Synthesis of Poly(N-Acryloyl Amino Acid) Through

Spin Capturing with Nitrones: Radical Coupling Reactions with Concurrent Introduction of Midchain Functionality

Efficient Magnesium Catalysts for the Copolymerization of Epoxides and CO 2 ; Using Water to Synthesize Polycarbonate Polyols

Supporting Information. Nitroxide Mediated Polymerization of methacrylates at moderate temperature

Photo-Cleavage of Cobalt-Carbon Bond: Visible. Light-Induced Living Radical Polymerization Mediated by. Organo-Cobalt Porphyrins

The ph-responsive behaviour of aqueous solutions of poly(acrylic acid) is dependent on molar mass

SUPPORTING INFORMATION

Optimizing Ion Transport in Polyether-based Electrolytes for Lithium Batteries

1 Electronic Supplementary Information (ESI) 2 Healable thermo-reversible functional polymer via RAFT

Photolabile Protecting Groups: A Strategy for Making

Bulk ring-opening transesterification polymerization of the renewable δ-decalactone using

1,1,3,3-Tetramethylguanidine-Promoted Ring-Opening Polymerization of N-Butyl N-Carboxyanhydride Using Alcohol Initiators

1. Bulk polymerization of styrene at 60 C with four different initiator concentrations

Polymerization Induced Self-Assembly: Tuning of Nano-Object Morphology by Use of CO 2

High Frequency sonoatrp of 2-Hydroxyethyl Acrylate in an Aqueous Medium

Free radical and RAFT polymerization of vinyl

Supporting information. for. hydrophobic pockets for acylation reactions in water

Preparation of 1:1 alternating, nucleobase-containing copolymers for use in sequence-controlled polymerization

RAFT /MADIX polymerization of N-vinylcaprolactam in water-ethanol solvent mixtures

Supporting Information

Supporting information

Supporting Information

Supporting Information

Supporting Information

Supporting Information for

Red Color CPL Emission of Chiral 1,2-DACH-based Polymers via. Chiral Transfer of the Conjugated Chain Backbone Structure

Supporting Information

Synthesis of Random Copolymers Poly (methylmethacrylate-co-azo monomer) by ATRP-AGET

Hydrophilic MacroRAFT-Mediated Emulsion Polymerization: Synthesis of Latexes for

RAFT and Click Chemistry : A Versatile Approach to the Block Copolymer Synthesis

Investigation into the mechanism of photo-mediated RAFT polymerization involving the reversible photolysis of the chain-transfer agent

Synthesis of pyrrolidinium-based poly(ionic liquid) electrolytes with poly(ethylene glycol) side-chains

Electronic Supplementary Information (ESI)

Supporting Information

Supporting Information

Hyperbranched Poly(N-(2-Hydroxypropyl) Methacrylamide) via RAFT Self- Condensing Vinyl Polymerization

Supporting Information. Well-defined polyelectrolyte and its copolymers by reversible. addition fragmentation chain transfer (RAFT) polymerization:

Electronic Supporting Information for

SUPPLEMENTARY INFORMATION

Supporting Information

Supplementary Information. Rational Design of Soluble and Clickable Polymers Prepared by. Conventional Free Radical Polymerization of

UV-Light as External Switch and Boost of Molar-Mass Control in Iodine-Mediated Polymerization

Chemically recyclable alternating copolymers with low polydispersity from

Supporting information

Synthesis and characterization of poly(amino acid methacrylate)-stabilized diblock copolymer nanoobjects

High Molecular Weight Bile Acid and Ricinoleic Acid-Based Co-polyesters via Entropy-Driven Ring-Opening Metathesis Polymerisation

Scheme 1: Reaction scheme for the synthesis of p(an-co-mma) copolymer

Tunable thermo-responsive water-dispersed multi walled. carbon nanotubes

Micelles from self-assembled Double-Hydrophilic PHEMA- Glycopolymer-Diblock Copolymers as multivalent Scaffolds for Lectin Binding

by direct arylation polycondensation: End groups, defects and crystallinity

Supporting Information. Copolymers of Tetrahydrofuran and Epoxidized Vegetable Oils: Application to Elastomeric Polyurethanes

Supplementary Information

Supporting Information for

Electronic Supplementary Information RAFT polymerization with triphenylstannylcarbodithioates (Sn-RAFT)

Supplementary Information

Supporting Information

Hierarchical Micelles via Polyphilic Interactions: Hydrogen-Bonded Supramolecular Dendron and Double. Immiscible Polymers

Supplementary Material (ESI) for Chemical Communications This journal is (c) The Royal Society of Chemistry 2008

Electronic Supplementary Information. for. Self-Assembly of Dendritic-Linear Block Copolymers With Fixed Molecular Weight and Block Ratio.

Supporting information

A novel smart polymer responsive to CO 2

Supporting Information for

Xiangxiong Chen, Mohd Yusuf Khan and Seok Kyun Noh* School of Chemical Engineering, Yeungnam University, Dae-dong, Gyeongsan,

A Rational Entry to Cyclic Polymers via Selective Cyclization by Self-Assembly and Topology Transformation of Linear Polymers

Synthetic Upcycling of Polyacrylates through Organocatalyzed Post-Polymerization Modification

Lecture 4 : Gel Permeation or Size Exclusion Chromatography

Well-defined Click-able Copolymers in One-Pot Synthesis

MEASUREMENT OF THE CHAIN TRANSFER CONSTANT FOR THE POLYMERIZATION OF STYRENE USING D-LIMONENE AS RENEWABLE CTA

Supplementary Material

Electronic Supplementary Information

Supporting Information for. Effect of Molecular Weight on Lateral Microphase Separation of Mixed Homopolymer. Brushes Grafted on Silica Particles

Supporting Information for

Supplementary Materials

Silver-catalyzed decarboxylative acylfluorination of styrenes in aqueous media

Size exclusion chromatography of branched polymers: Star and comb polymers

ph dependent thermoresponsive behavior of acrylamide-acrylonitrile UCSTtype copolymers in aqueous media

Supporting Information. Aqueous Dispersions of Polypropylene and Poly(1-butene) with Variable Microstructures formed with Neutral Ni(II)-Complexes

Ring-Opening Polymerization of N-Carboxyanhydrides Initiated by a Hydroxyl Group

Polymeric Palladium-Mediated Carbene Polymerization

Synthesis and characterization of innovative well-defined difluorophosphonylated-(co)polymers by RAFT polymerization

Sunlight-induced Crosslinking of 1,2- Polybutadienes: Access to Fluorescent Polymer. Networks

Supporting Information

Supporting Information. for

One polymer for all: Benzotriazole Containing Donor-Acceptor Type Polymer as a Multi-Purpose Material

Transcription:

Supporting Information to Narrow Molecular Weight and Particle Size Distributions of Polystyrene 4-arm Stars Synthesized by RAFT- Mediated Miniemulsions. Hazit A. Zayas, Nghia P. Truong, David Valade, Zhongfan Jia and Michael J. Monteiro* Australian Institute for Bioengineering and Nanotechnology, University of Queensland, Brisbane QLD 47, Australia *author to whom correspondence should be sent: e-mail: m.monteiro@uq.edu.au

Table S. Kinetics data of RAFT agent mediated polymerization of styrene in miniemulsion using SDS (.8 g) as surfactant and hexadecane (.78 ml) as hydrophobe in water (8. g). The polymerization was initiated with ammonium persulfate (APS) at 7ºC. M n,target Styrene (g) CTA (g) Time (min) Conv. c (%) M n,theory d M n, exp e PDI e D h f (nm) (PDI) f N c g 5K a..968 - - - - 7 (.8) 7.97E+8 7 6 47. 5 (.).7E+8 4 5. 59 (.79).9E+8 6 86 85.4 47 (.).79E+8 6 4 74.9 7 (.6).7E+8 8 8 45 498.8 8 (.5) 6.57E+7 4 95 57 58.8 78 (.55) 7.49E+7 K a..484 - - - - 5 (.8) 9.66E+8 5 - - 4 (.) 5.64E+8 - - 5 (.89).99E+8 6 9 7 6. 6 (.57).6E+8 65 68 78. 7 (.5).6E+8 8 88 95.8 76 (.5) 8.6E+7 4 95 99.8 76 (.55) 8.8E+7 K b..4 - - - - 7 (.46) 8.9E+8 5 4 8-4 (.4) 5.67E+8 4 4-4 (.) 6.4E+8 5 5 9-4 (.8) 5.94E+8 6 5 66.4 4 (.64) 6.55E+8 4 9 88.4 4 (.5) 5.6E+8 45 6 48.6 49 (.86).5E+8 5 9 46 66.7 54 (.59).49E+8 6 8 69 67.6 64 (.7).48E+8 67 47 58.8 68 (.4).E+8 8 85 795 965.7 75 (.5) 8.47E+7 4K b.. - - - - 4 (.655) 6.7E+8 5-6 (.57) 8.64E+8 49-4 (.56).E+9 5 4 9 7. (.584).6E+9 5 7 5.8 6 (.49) 8.77E+8 4 7. 6 (.) 8.56E+8 45 5 4.4 6 (.6) 8.7E+8 6 4 677 9.4 66 (.).5E+8 76 76 59.6 76 (.7) 8.47E+7 8 9 8 464.4 77 (.9) 7.84E+7 4 9 94 44. 77 (.8) 7.78E+7 a Ratio of CTA:APS is maintained at :.. Ratio of CTA:APS is maintained at :.. c Monomer conversion was obtained by gravimetric analysis. d M n, theory was calculated using the equation [M Sty /M CTA ] x MW sty x %Conv. + MW CTA. e M n, exp and the corresponding polydispersity index (PDI) were measured by size exclusion chromatography using linear polystyrene standards. f Hydrodynamic radius (D h ) and the corresponding polydispersity index (PDI) were measured by dynamic light scattering (DLS). Seven measurements were taken for each sample at 5 C.

w (M) w (M) W(M) w (M) Electronic Supplementary Material (ESI) for Polymer Chemistry (A) 4 5K (B) 4 K min 4 min 6 min min 8 min 4 min 6 min min 8 min 4 min 4 5 6 log M 4 5 6 Log M (C) K min 4 min 45 min 5 min 6 min min 8 min 4 5 6 log M (D) 4K 5 min min 4 min 45 min 6 min min 8 min 4 min 4 5 6 logm Figure S. Overlaid RI SEC traces for RAFT agent -polystyrene latexes of M n targets of (A) 5K, (B) K, (C) K and (D) 4K. The polymerization was carried out in miniemulsion using SDS as surfactant and hexadecane as hydrophobe initiated with APS at 7ºC. Linear polystyrene standards were used for calibration and THF as eluent.

f b, c, g, h, i k H O d CDCl e a, j Figure S. H NMR spectra for RAFT agent -polystyrene latex of M n target of K with expanded view (inset) of region.-5. ppm. The sample was obtained from a Bruker DRX 5 MHz spectrometer and the solvent used was CDCl.

Intens. [a.u.] Intens. [a.u.] Electronic Supplementary Material (ESI) for Polymer Chemistry (A) x4 59.5..5..5. 45 5 55 6 65 7 75 8 85 m/z (B) x4 587.86 59.4 59.5. =4 m/z.5 598.9 584.. 585.657 5957.654.5. 5775 58 585 585 5875 59 595 595 5975 m/z Figure S. MALDI-ToF mass spectrometry of RAFT agent polystyrene of M n target of 5K with Ag salt as cationization agent from a DCTB matrix in linear mode. (A) The full molecular weight distribution and (B) expanded view of peaks correspond to RAFT agent -PSTY 54. Theoretical mass of RAFT agent -PSTY 54 is (59.4), found (59.5). (Sample was run on Bruker Autoflex III Smartbeam TOF/TOF.)

(A) 5K (B) K (C) K (D) 4K Figure S4. Size distribution by intensity for RAFT agent Polystyrene latexes of M n targets of (A) 5K, (B) K, (C) K and (D) 4 K measured by dynamic light scattering.

Table S. Kinetics data of RAFT agent (R-approach) mediated polymerization of styrene in miniemulsion using SDS (.8 g) as surfactant and hexadecane (.78 ml) as hydrophobe in water (8. g). The polymerization was initiated with ammonium persulfate (APS) at 7ºC. M n,target Styrene (g) CTA (g) Time (min) Conv. c (%) M n,theory d M n, exp e PDI e D h f (nm) (PDI) f N c 5K a..98 - - - - 47 (.6).84E+8 9 54 95.7 57 (.87).9E+8 4 44 57.7 57 (.98).4E+8 6 5 7 95.7 6 (.77).57E+8 7 484 96.6 6 (.8).55E+8 8 88 56 465.6 67 (.8).8E+8 4 89 564 48.6 67 (.8).8E+8 K a..954 - - - - 49 (.96).56E+8 7 49 8.6 47 (.7).67E+8 4 6 75 588.5 46 (.66).8E+8 6 74 877 69.5 46 (.7).7E+8 9 6 84.5 49 (.99).98E+8 8 95 86 885.6 5 (.).94E+8 K b..977 - - - - (.47).E+9 5 6 5.8 4 (.9) 5.8E+8 5 8 68.7 47 (.9).69E+8 9 9 744.8 5 (.6).99E+8 86 9 5.8 56 (.78).E+8 8 9 7 586.7 57 (.75).99E+8 94 6 598.8 58 (.74).87E+8 4K b..489 - - - - 4 (.48) 5.59E+8 5 586 474.9 45 (.54) 4.4E+8 7 798 69.9 46 (.49) 4.7E+8 5 6 85.5 5 (.).E+8 46 56.5 58 (.66).E+8 6 65 79 69.7 57 (.64).7E+8 85 65 876.9 58 (.59).85E+8 8 88 757 998. 54 (.8).6E+8 4 88 77 6.9 56 (.7).6E+8 a Ratio of CTA:APS is maintained at :.4. b Ratio of CTA:APS is maintained at :.. c Monomer conversion was obtained by gravimetric analysis. d M n, theory was calculated using the equation [M Sty /M CTA ] x MW sty x %Conv. + MW CTA. e M n, exp and the corresponding polydispersity index (PDI) were measured by size exclusion chromatography using linear polystyrene standards. f Hydrodynamic radius (D h ) and the corresponding polydispersity index (PDI) were measured by dynamic light scattering (DLS). Seven measurements were taken for each sample at 5 C.

W (M) w (M) w (M) W (M) Electronic Supplementary Material (ESI) for Polymer Chemistry (A) 5 5K (B) 5 K 4 4 min 4 min 6 min min 8 min 4 min min 4 min 6 min min 8 min.5.5 4.5 5.5 log M.5.5 4.5 5.5 Log M (C) 4 K (D) 4K 5 min min min min 8 min min.5.5 4.5 5.5 Log M 5 min min 5 min min 6 min min 8 min 4 min.5.5 4.5 5.5 Log M Figure S5. Overlaid RI SEC traces for RAFT agent -polystyrene latexes of M n target of (A) 5K, (B) K, (C) K and (D) 4K.The polymerization was carried out in miniemulsion using SDS as surfactant and hexadecane as hydrophobe initiated with APS at 7ºC. Linear polystyrene standards were used for calibration and THF as eluent.

f b, c, e, g, h, i d H O CHCl e k a, j Figure S6. H NMR spectra for RAFT agent -polystyrene latex of M n target of K with expanded view (inset) of region.-5. ppm. The sample was obtained from abruker DRX 5 MHz spectrometer and the solvent used was CDCl.

Intens. [a.u.] Electronic Supplementary Material (ESI) for Polymer Chemistry x4 (A) 566.55 4 5 55 6 65 7 75 m/z (B) (57.76) (579.754) 547.945 55. 566.55 =4 m/z 574.574 5844.87 56.4 555.86 588.99 54.566 57.96 568.79 59.46 55 56 57 58 59 Figure S7. MALDI-ToF mass spectrometry of RAFT agent polystyrene of M n target of 5K with Ag salt as cationization agent from a DCTB matrix in linear mode. (A) The full molecular weight distribution and (B) expanded view of peaks correspond to RAFT agent (4 arm)-psty a,b,c,d (where a+b+c+d=44). Theoretical masses of RAFT agent (4 arm)- PSTY a,b,c,d (where a+b+c+d=44) are (57.76) and (579.754), found are (57.96) and (574.574), respectively. (Sample was run on Bruker Autoflex III Smartbeam TOF/TOF.) m/z

(A) 5K (B) K (C) K (D) 4K Figure S8. Size distribution by intensity of RAFT agent Polystyrene latexes of M n targets of (A) 5K, (B) K, (C) K and (D) 4 K measured by dynamic light scattering.

Conversion (%) M n (x ) PDI Electronic Supplementary Material (ESI) for Polymer Chemistry Synthesis of -arm PSTY by RAFT Solution Polymerization in Toluene The molar ratios of [STY]:[RAFT]:[AIBN] were set up as ::. and 4::. to target K and 4 K molecular weight at the % conversion, respectively. Typically, for the molar ratio 4::., RAFT agent (. mg, 4.8 x -5 mol) and AIBN (.788 mg, 4.8 x -6 mol) were dissolved in g (.9 x - mol) of STY and 8 ml of toluene. The solution was purged with argon for min and then polymerization mixture immersed in a preheated oil-bath at 7 o C. Aliquots were then taken out for the analysis at regular intervals and the reaction stopped after 4 h. (A) (B) (C) 8 6 K 4K 5 9 K 4K K Mn theory 4K Mn theory.8.6 K 4K 4 6.4. 5 5 5 Time (h) Conversion (%) Conversion (%) Figure S9. Kinetics data for RAFT agent mediated styrene polymerization in toluene at 7 C initiated with AIBN. (A) Conversion vs time, (B) number average molecular weight (M n ) vs conversion and (C) polydispersity index (PDI MWD ) vs conversion. [STY]:[RAFT]:[AIBN] = ::. and 4::. to target K and 4 K molecular weight at the % conversion, respectively.

Conversion (%) M n (x ) Electronic Supplementary Material (ESI) for Polymer Chemistry Synthesis of 4-arm PSTY by RAFT Solution Polymerization in Toluene A typical RAFT-mediated polymerization of styrene in toluene in the presence of the 4-arm RAFT agent was carried out as follows. An initial [STY]:[RAFT]:[AIBN] ratio = ::. : STY ( g, 9. - mol), (97.7 mg mg, 9.6-5 mol), AIBN (.58 mg, 9.6-6 mol) and 8 ml of toluene were introduced in a Schlenk tube equipped with a magnetic stirrer. The solution was purged with argon for min and heated at 7 o C. Aliquots were regularly taken and analyzed by GPC (MWD) and gravimetry (conversion). After 4 h, AIBN (. eq to ) was added to the polymerization and continued for a further 4 h. (A) (B) (C) 8 6 4 K 4K 4 k 4k K mn theory 4K Mn theory PDI MWD..6..8 k 4k.4 4 6 8 Time (h) 4 6 8 Conversion (%) 4 6 8 Conversion (%) Figure S. Kinetics data for RAFT agent (4-arm RAFT agent) mediated styrene polymerization in toluene at 7 C initiated with AIBN. (A) Conversion vs time, (B) number average molecular weight (M n ) vs conversion and (C) polydispersity index (PDI MWD ) vs conversion. [STY]:[RAFT]:[AIBN] ratio = ::. : STY ( g, 9. - mol), (97.7 mg mg, 9.6-5 mol), AIBN (.58 mg, 9.6-6 mol) and 8 ml of toluene. After 4 h, AIBN (. eq to ) was added to the polymerization and continued for a further 4 h.

Conversion (%) M n (x ) Electronic Supplementary Material (ESI) for Polymer Chemistry Synthesis of 4-arm PSTY by RAFT Solution Polymerization in bulk A typical RAFT-mediated polymerization of styrene in bulk in the presence of the 4-arm RAFT agent was carried out as follows. An initial [STY]:[RAFT]:[AIBN] ratio = ::. : STY ( g, 8.8 - mol), (46.6 mg, 4.4-5 mol) and AIBN (.4 mg, 4.4-6 mol) were introduced in a Schlenk tube equipped with a magnetic stirrer. The solution was purged with argon during min and heated at 7 o C for h. Aliquots were regularly taken and analyzed by GPC (MWD) and gravimetry (conversion). (A) 8 6 4 K 4K (B) 4 k 4k K mn theory 4K Mn theory (C) PDI MWD..6..8 k 4k.4 4 Time (h) 5 Conversion (%) 4 6 8 Conversion (%) Figure S. Kinetics data for RAFT agent (4-arm RAFT agent) mediated styrene polymerization in bulk at 7 C initiated with AIBN. (A) Conversion vs time, (B) number average molecular weight (M n ) vs conversion and (C) polydispersity index (PDI MWD ) vs conversion. [STY]:[RAFT]:[AIBN] ratio = ::. : STY ( g, 8.8 - mol), (46.6 mg, 4.4-5 mol) and AIBN (.4 mg, 4.4-6 mol).

. Hart-Smith, G.; Chaffey-Millar, H.; Barner-Kowollik, C., Living Star Polymer Formation: Detailed Assessment of Poly(acrylate) Radical Reaction Pathways via ESI-MS. Macromolecules 8, 4 (9), -4.

2024 © sciencedocbox.com Privacy Policy | Terms of Service | Feedback