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Concepts and Tools for RAFT Polymerization

From our Controlled Radical Polymerization Guide. Adapted from contributions by researchers at CSIRO.

The RAFT Polymerization Process

Reversible addition/fragmentation chain transfer (RAFT) is a form of living radical polymerization. RAFT polymerization was discovered at CSIRO in 1998.1 It soon became the focus of intensive research, since the method allows synthetic tailoring of macromolecules with complex architectures including block, graft, comb, and star structures with controlled molecular weight.2

RAFT polymerization is applicable to a very wide range of vinyl monomers under a variety of experimental conditions, including the preparation of water-soluble materials.3 The RAFT process involves conventional free radical polymerization of a substituted monomer in the presence of a suitable chain transfer agent (RAFT agent or CTA).

Commonly used RAFT agents include thiocarbonylthio compounds such as dithioesters,1 dithiocarbamates,4,5 trithiocarbonates,6 and xanthates,7 which mediate the polymerization via a reversible chain-transfer process. Use of a proper RAFT agent allows synthesis of polymers with a high degree of functionality and narrow distribution of molecular weights also referred to as a low polydispersity index (PDI) as shown in Figure 1.

General comparison of polymers made with traditional radical polymerization against those made using RAFT process.

Figure 1.General comparison of polymers made with traditional radical polymerization against those made using RAFT process.

A RAFT CTA typically has a thiocarbonylthio group (S = C-S) with substituents R and Z that impact the polymerization reaction kinetics and therefore, the degree of structural control. Initiation of the polymerization reaction is accomplished utilizing conventional thermal, photochemical, or redox methods, and the success of the RAFT polymerization experiment is dependent upon selecting the appropriate RAFT reagent for a particular monomer and reaction medium. This general concept is depicted in Figure 2.

General structure of a RAFT agent

Figure 2.General structure of a RAFT agent, where the R and Z subtituents impact reaction kinetics. The choice of the RAFT agent is critical to obtain polymers with low PDI and controlled architecture.

Classes of RAFT Agents

Solubility and reactivity of a RAFT agent depend on the R and Z groups; as a result, different RAFT agents are more suitable for specific classes of monomers. The main classes of RAFT agents are:

Four classes of RAFT agents

Figure 3.Four classes of RAFT agents: A) Dithiobenzoates, B) Trithiocarbonates, C) Dithiocarbamates, and D) Xanthates.

  1. Dithiobenzoates
    • Very high transfer constants
    • Prone to hydrolysis
    • May cause polymerization retardation under high concentrations
  2. Trithiocarbonates
    • High transfer constants
    • More hydrolytically stable (than dithiobenzoates)
    • Cause less retardation
  3. Dithiocarbamates
    • Activity determined by substituents on N
    • Effective with electron-rich monomers
  4. Xanthates
    • Lower transfer constants
    • More effective with less activated monomers
    • Made more active by electron-withdrawing substituents

RAFT Agent to Monomer Compatibility Table

The application of RAFT agents with common monomers used in polymerizations is shown in Table 1. The plus and minus symbols represent the degree of compatibility between monomer classes and a RAFT agent. For example, Prod No. 723037 (fifth item down in Table 1) is very useful in polymerizing styrenes, methacrylates and methacrylamides, shows moderate activity for acrylates and acrylamides but cannot polymerize vinyl esters or vinyl amides. This table can be used as a guide for selecting the most appropriate RAFT agent for your needs.

RAFT agents suitability for various monomer types.

Table 1.RAFT agents suitability for various monomer types. (Adapted from CSIRO′s RAFT agent Monomer Matching guide).

Materials List
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References

1.
Chiefari J, Chong YK(, Ercole F, Krstina J, Jeffery J, Le TPT, Mayadunne RTA, Meijs GF, Moad CL, Moad G, et al. 1998. Living Free-Radical Polymerization by Reversible Addition?Fragmentation Chain Transfer:  The RAFT Process. Macromolecules. 31(16):5559-5562. https://doi.org/10.1021/ma9804951
2.
Moad G, Rizzardo E, Thang SH. 2005. Living Radical Polymerization by the RAFT Process. Aust. J. Chem.. 58(6):379. https://doi.org/10.1071/ch05072
3.
McCormick CL, Lowe AB. 2004. Aqueous RAFT Polymerization:  Recent Developments in Synthesis of Functional Water-Soluble (Co)polymers with Controlled Structures?. Acc. Chem. Res.. 37(5):312-325. https://doi.org/10.1021/ar0302484
4.
Mayadunne RTA, Rizzardo E, Chiefari J, Chong YK, Moad G, Thang SH. 1999. Living Radical Polymerization with Reversible Addition?Fragmentation Chain Transfer (RAFT Polymerization) Using Dithiocarbamates as Chain Transfer Agents. Macromolecules. 32(21):6977-6980. https://doi.org/10.1021/ma9906837
5.
Destarac. M.; Charmot. D.; Franck, X.; Zard, S. Z. Macromol. . 2000. Rapid. Commun, 21, 1035..
6.
Mayadunne RTA, Rizzardo E, Chiefari J, Krstina J, Moad G, Postma A, Thang SH. 2000. Living Polymers by the Use of Trithiocarbonates as Reversible Addition?Fragmentation Chain Transfer (RAFT) Agents:  ABA Triblock Copolymers by Radical Polymerization in Two Steps. Macromolecules. 33(2):243-245. https://doi.org/10.1021/ma991451a
7.
Francis R, Ajayaghosh A. 2000. Minimization of Homopolymer Formation and Control of Dispersity in Free Radical Induced Graft Polymerization Using Xanthate Derived Macro-photoinitiators?. Macromolecules. 33(13):4699-4704. https://doi.org/10.1021/ma991604u
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