Synthesis of Controlled Polymer Nanospheres by a Reversible Addition- Fragmentation Chain Transfer (RAFT) Miniemulsion Polymerization

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1 Synthesis of Controlled Polymer Nanospheres by a Reversible Addition- Fragmentation Chain Transfer (RAFT) iniemulsion Polymerization Huije Lee, Sang Eun Shim, Byung H. Lee, Soonja Choe* Department of Chemical Engineering, nha University, 253 Yonghyundong, Namgu, ncheon , S. Korea

Objectives To apply a RAFT agent bearing carboxyl acid group to miniemulsion polymerization To obtain stability-enhanced functionalized polymer nanospheres with narrow PD via RAFT method ntroduction

2 Objectives To apply a RAFT agent bearing carboxyl acid group to miniemulsion polymerization To obtain stability-enhanced functionalized polymer nanospheres with narrow PD via RAFT method ntroduction Synthetic methods of functionalized particles Copolymerization with ionic monomers Polymerization with charge endowing surfactants or initiators ulti-step process in which functional groups are introduced after the colloid synthesis Applications Colloidal drug carrier, detoxification Solid-phase supports in biomedical and biochemical fields nformation technology aterials for humidity sensors.

3 Living Free-Radical Polymerizations LRP ethods Reversible Addition-Fragmentation Chain Transfer Polymerization (RAFT) Nitroxide-ediated Polymerization (NP) Atom-Transfer Radical Polymerization (ATRP) Characteristics of LRP Precise control of n & PD Precise control of stereostructure Synthesis of highly functional block copolymers Tailor-made polymer products Advanced materials applicable to T, BT, and NT

Trend in LRPs Timeline of LRP 19 198 82 86 199 95 98 2 Stable Radicals: Gomberg Living Radical Polymerization (niferter( niferter): Otsu NP: Solomon & Rizzardo ATRP:

4 Trend in LRPs Timeline of LRP Stable Radicals: Gomberg Living Radical Polymerization (niferter( niferter): Otsu NP: Solomon & Rizzardo ATRP: atyjaszewski RAFT: Rizzardo Research nterest in LRPs 1. Homogeneous: Bulk / Solution Heterogeneous: iniemulsion Heterogeneous: Emulsion 2. olecular Design in Homogeneous Polymerization

5 RAFT Polymerization Generic RAFT Agent Structure X Weak single bond X R R is free radical leaving group (R must also be able to reinitiate polymerization) Reactive double bond Z Z modifies addition and fragmentation rates S C S CH 2 S C S CH 2 (4-Toluic acid) dithiobenzoate, TADB Benzyl dithiobenzoate, BDB

6 echanism of RAFT Polymerization nitiation nitiator P n Chain transfer P n + S S R Ph K add K -add P n S Ph S R K β K -β P n S Ph S + R Reinitiation R k i R k p P m Chain equilibration P n + S Ph S P n P m S Ph S P n P m S Ph S + P n Termination P n + P m k t dead polymer

7 RAFT Polymerization Problems in conventional emulsion polymerization Lack of colloidal stability Retardation of polymerization rate Formation of a conspicuous red layer at the beginning of polymerization Broad molecular weight distribution (higher than 1.5) Techniques utilized to overcome the problems Semi-batch process Seeded emulsion polymerization iniemulsion polymerization

8 Experimental Recipe - Reaction medium : double distilled de-ionized (DD) water - onomer : ethyl methacrylate, Styrene - Surfactant : Sodium dodecyl sulfate (SDS) - Cosurfactant : Hexadecane - nitiator : 2,2 Azobis(isobutyronitrile) (ABN) - RAFT agent : (4-Toluic acid) dithiobenzoate, Benzyl dithiobenzoate Conditions O C, 22 rpm - [RAFT]/[ABN] =, 1, 2, 5 Characterizations - olecular weight measurement : GPC HPLC pump (WATERS 51), Viscometer (Viscotex) - Particle size and Zeta potential : Zetasizer (alvern, Zetasizer 4) - Conductivity measurement : Conductivity meter (KE, G - 115) - Analysis of particle size & morphology : SE (Hitachi, S - 43)

9 Polymerization Kinetics : Effect of Reaction Temperature ([TADB]/[ABN]=1), PA Fractional Conversion o C 7 o C 8 o C Ln{[]/[]} o C 7 o C 8 o C Polymerization Time (min) Polymerization Time (min)

10 olecular Weight Evolution : Effect of Reaction Temperature ([TADB]/[ABN]=1), PA Number-average olecular Weight Fractional Conversion 6 o C 7 o C 8 o C PD Fractional Conversion 6 o C 7 o C 8 o C

11 Polymerization Kinetics : Effect of [TADB]/[ABN], 8 o C PA Fractional Conversion Ln{[]/[]} Polymerizaion Time (min) Polymerization Time (min)

12 olecular Weight Evolution : Effect of [TADB]/[ABN], 8 o C PA Number Average olecular Weight Fractional Conversion PD Fractional Conversion

13 GPC Traces & SE Photograph of PA : 2hr, 8 o C [TADB]/[ABN] Retention Time (min) [TADB]/[ABN]=1, 9nm

14 Synthetic echanism a d H 2 O b Stirring c Heating COO- COO- H 2 O COO - ore H 2 O H 2 O onomer Surfactant nitiator RAFT agent (TADB)

15 Particle Size Distribution of PA Latex : 2hr, 8 o C 52 1 [TADB] / [ABN] = [TADB] / [ABN] = 1 [TADB] / [ABN] = 2 [TADB] / [ABN] = ntensity Size (nm) Size (nm) [TADB] / [ABN]

16 Zeta Potential & Conductivity of PA Latex : 2hr, 8 o C ntensity [TADB] / [ABN] = [TADB] / [ABN] = 1 [TADB] / [ABN] = 2 [TADB] / [ABN] = 5 Zeta potential (mv) Conductivity (ms/cm) Zeta potential (mv) [TADB] / [ABN]

17 Polymerization Characteristics : Effect of carboxyl acid [RAFT]/[ABN] = 1.3, 8, PS Ln{[] /[]} TADB BDB n TADB BDB PD TADB BDB Reaction Time (hr) Fractional Conversion Fractional Conversion TADB : S C S CH 2 BDB : S C S CH 2

18 nfluence of RAFT agents : Particle size, Zeta potential, and Conductivity (8hr), PS [RAFT]/[nitiator] = 1.3 TABD BDB Particle Size (nm) Zeta potential (mv) Conductivity (ms( ms/cm) SE images

19 Polymerization Characteristics : Effect of [TADB]/[ABN], 8, PS Ln{[] o /[]} Reaction Time (hr) Number Average olecular Weight Fractional Conversion PD Fractional Conversion

20 Average Particle Size & SE Photographs of PS : 8hr, 8 o C 13 Average Particle Size (nm) [TADB]/[ABN]=, 9nm [TADB]/[ABN] [TADB]/[ABN]=3, 125nm

21 Zeta Potential & Conductivity of PS Latex : 8hr, 8 o C Zeta Potential (mv) Conductivity (ms/cm) [TADB]/[ABN] [TADB]/[ABN]

22 Conclusions A linear increase in n with respect to the conversion is observed, indicating the nature of living (controlled) radical polymerization. The PA-system - The higher the temperature, the faster conversion, the lower n and PD are obtained. - As the ratio of [TABD]/[ABN] increases, the conversion, molecular weight, molecular weight distribution, and particle size decrease. - With the ratio of [TABD]/[ABN], the zeta potential & conductivity increase, i.e. the stability of the PA latex is enhanced.

23 Conclusions The PS-system - A BDB (w/o carboxyl acid functionalized)-added system leads to slower conversion, similar n and PD, and larger particle size, however, decreases the zeta potential and conductivity. - As the ratio of [TABD]/[ABN] increases, the conversion, molecular weight, and molecular weight distribution decrease, however, particle size increases. - With the ratio of [TABD]/[ABN], the zeta potential & conductivity increase, i.e. the stability of the PS latex is enhanced. The polymer nanospheres functionalized with carboxylic acid group can be prepared by a novel mechanism.

Jung Min Lee, Ok Hyung Kim, Sang Eun Shim, Byung H. Lee, and Soonja Choe* Department of Chemical Engineering, Inha University, Inchon , Korea

Jung Min Lee, Ok Hyung Kim, Sang Eun Shim, Byung H. Lee, and Soonja Choe* Department of Chemical Engineering, Inha University, Inchon , Korea Macromolecular Research, Vol. 13, No. 3, pp 36-4 (005) Reversible Addition-Fragmentation Chain Transfer (RAFT) Bulk Polymerization of Styrene : Effect of R-Group Structures of Carboxyl Acid Group Functionalized