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  1. Towards Sustainable Materials: A Review of Acylhydrazone Chemistry for Reversible Polymers

    Article • Chemistry - A European Journal, June 2024, Wiley

    Dr Graeme Moad

  2. Enhancing photothermal depolymerization with metalloporphyrin catalyst

    Article • Journal of Polymer Science, May 2024, Wiley

    Dr Almar Postma, Dr Graeme Moad

  3. Streamlining the Generation of Advanced Polymer Materials through the Marriage of Automation and Multiblock Copolymer Synthesis in Emulsion

    Article • Angewandte Chemie International Edition, February 2024, Wiley

    Dr Graeme Moad

  4. Silicon spikes take out 96% of virus particles.

    Article • ACS Nano, December 2023, American Chemical Society (ACS)

    Dr Graeme Moad

  5. Surfaces that kill viruses

    Article • Current Opinion in Colloid & Interface Science, October 2023, Elsevier

    Dr Graeme Moad

  6. Exploiting NIR Light-Mediated Surface-Initiated PhotoRAFT Polymerization for Orthogonal Control Polymer Brushes and Facile Postmodification of Complex Architecture through Opaque Barriers

    Article • Macromolecules, September 2023, American Chemical Society (ACS)

    Dr Graeme Moad, Dr Almar Postma

  7. RAFT polymerization in presence of air

    Article • Macromolecular Chemistry and Physics, July 2023, Wiley

    Dr Graeme Moad, Dr Almar Postma

  8. Radicals adding monomers one at a time

    Article • Progress in Polymer Science, March 2023, Elsevier

    Dr Graeme Moad

  9. Room temperature RAFT polymerization initiated with electricity

    Article • ACS Macro Letters, February 2023, American Chemical Society (ACS)

    Dr Graeme Moad

  10. Multiblock copolymers by RAFT emulsion polymerization

    Article • Chemical Society Reviews, January 2023, Royal Society of Chemistry

    Dr Graeme Moad

  11. High-throughput concurrent synthesis of core-crosslinked star-polydimethylsiloxane using an arm-first approach

    Article • Polymer Chemistry, January 2023, Royal Society of Chemistry

    Dr Graeme Moad, Dr Almar Postma

  12. Calculating the molecular weight distribution of RAFT-made polymers

    Article • Polymers, November 2022, MDPI AG

    Dr Graeme Moad

  13. What is chain polymerization>

    Article • Pure and Applied Chemistry, September 2022, De Gruyter

    Dr Graeme Moad

  14. How to make a polymer

    Article • Pure and Applied Chemistry, August 2022, De Gruyter

    Dr Graeme Moad

  15. Living and controlled reversible‐activation polymerization ( RAP ) on the way to reversible‐deactivation radical polymerization ( RDRP )

    Article • Polymer International, June 2022, Wiley

    Dr Graeme Moad

  16. Terminology and the naming of conjugates based on polymers or other substrates (IUPAC Recommendations 2021)

    Article • Pure and Applied Chemistry, March 2022, De Gruyter

    Dr Graeme Moad, Michel Vert

  17. Reversible Deactivation Radical Polymerization: RAFT

    Article • March 2022, Wiley

    Dr Graeme Moad

  18. Expanding the Scope of RAFT Multiblock Copolymer Synthesis Using the Nanoreactor Concept: The Critical Importance of Initiator Hydrophobicity

    Article • Macromolecules, March 2022, American Chemical Society (ACS)

    Dr Graeme Moad

  19. Reconsidering terms for mechanisms of polymer growth: the “step-growth” and “chain-growth” dilemma

    Article • Polymer Chemistry, January 2022, Royal Society of Chemistry

    Dr Graeme Moad

  20. An Industrial History of RAFT Polymerization

    Article • October 2021, Wiley

    Dr Graeme Moad

  21. RAFT Polymerization: Mechanistic Considerations

    Article • October 2021, Wiley

    Dr Graeme Moad

  22. A short overview of RAFT polymerization, the process and its impact.

    Article • October 2021, Wiley

    Dr Graeme Moad

  23. Terminology in Reversible Deactivation Radical Polymerization ( RDRP ) and Reversible Addition–Fragmentation Chain Transfer ( RAFT ) Polymerization

    Article • October 2021, Wiley

    Dr Graeme Moad

  24. Dithiocarbamates in RAFT Polymerization

    Article • October 2021, Wiley

    Dr Graeme Moad

  25. Dithioesters in RAFT Polymerization

    Article • October 2021, Wiley

    Dr Graeme Moad

  26. Trithiocarbonates in RAFT Polymerization

    Article • October 2021, Wiley

    Dr Graeme Moad

  27. High‐Throughput/High‐Output Experimentation in RAFT Polymer Synthesis

    Article • October 2021, Wiley

    Dr Graeme Moad

  28. RAFT Polymerization

    Article • October 2021, Wiley

    Dr Graeme Moad

  29. Synthesis of Multicompositional Onion‐like Nanoparticles via RAFT Emulsion Polymerization

    Article • Angewandte Chemie International Edition, September 2021, Wiley

    Dr Graeme Moad

  30. The Critical Importance of Adopting Whole-of-Life Strategies for Polymers and Plastics

    Article • Sustainability, July 2021, MDPI AG

    Dr Graeme Moad

  31. Selective Bond Cleavage in RAFT Agents Promoted by Low‐Energy Electron Attachment

    Article • Angewandte Chemie International Edition, July 2021, Wiley

    Dr Graeme Moad

  32. “All-PVC” Flexible Poly(vinyl Chloride): Nonmigratory Star-Poly(vinyl Chloride) as Plasticizers for PVC by RAFT Polymerization

    Article • Macromolecules, May 2021, American Chemical Society (ACS)

    Dr Graeme Moad

  33. Enhanced properties of well-defined polymer networks prepared by a sequential thiol-Michael - radical thiol-ene (STMRT) strategy

    Article • European Polymer Journal, May 2021, Elsevier

    Dr Graeme Moad

  34. Multiblock Copolymer Synthesis via Reversible Addition–Fragmentation Chain Transfer Emulsion Polymerization: Effects of Chain Mobility within Particles on Control over Molecular Weight Distribution

    Article • Macromolecules, April 2021, American Chemical Society (ACS)

    Dr Graeme Moad

  35. Divergent Synthesis of Graft and Branched Copolymers through Spatially Controlled Photopolymerization in Flow Reactors

    Article • Macromolecules, March 2021, American Chemical Society (ACS)

    Dr Graeme Moad

  36. RAFT Emulsion Polymerization for (Multi)block Copolymer Synthesis: Overcoming the Constraints of Monomer Order

    Article • Macromolecules, January 2021, American Chemical Society (ACS)

    Dr Graeme Moad

  37. Definitions and notations relating to tactic polymers (IUPAC Recommendations 2020)

    Article • Chemistry International, January 2021, De Gruyter

    Dr Graeme Moad

  38. Polymerization-induced self-assembly via RAFT in emulsion: effect of Z-group on the nucleation step

    Article • Polymer Chemistry, January 2021, Royal Society of Chemistry

    Dr Graeme Moad

  39. Correction: Polymerization-induced self-assembly via RAFT in emulsion: effect of Z-group on the nucleation step

    Article • Polymer Chemistry, January 2021, Royal Society of Chemistry

    Dr Graeme Moad

  40. Initiation of RAFT Polymerization: Electrochemically Initiated RAFT Polymerization in Emulsion (Emulsion eRAFT), and Direct PhotoRAFT Polymerization of Liquid Crystalline Monomers

    Article • Australian Journal of Chemistry, January 2021, CSIRO Publishing

    Dr Graeme Moad, Dr Almar Postma

  41. Fundamentals of reversible addition–fragmentation chain transfer (RAFT)

    Article • Chemistry Teacher International, December 2020, De Gruyter

    Dr Graeme Moad

  42. Reversible-deactivation radical polymerization (Controlled/living radical polymerization): From discovery to materials design and applications

    Article • Progress in Polymer Science, December 2020, Elsevier

    Dr Graeme Moad

  43. Anthraquinone-Mediated Reduction of a Trithiocarbonate Chain-Transfer Agent to Initiate Electrochemical Reversible Addition–Fragmentation Chain Transfer Polymerization

    Article • Macromolecules, November 2020, American Chemical Society (ACS)

    Dr Graeme Moad, Dr Almar Postma

  44. A Comprehensive Platform for the Design and Synthesis of Polymer Molecular Weight Distributions

    Article • Macromolecules, October 2020, American Chemical Society (ACS)

    Dr Graeme Moad, Dr Almar Postma

  45. Definitions and notations relating to tactic polymers (IUPAC Recommendations 2020)

    Article • Pure and Applied Chemistry, October 2020, De Gruyter

    Dr Graeme Moad, Michel Vert

  46. Low-Dispersity Polymers in Ab Initio Emulsion Polymerization: Improved MacroRAFT Agent Performance in Heterogeneous Media

    Article • Macromolecules, September 2020, American Chemical Society (ACS)

    Dr Graeme Moad

  47. Versatile Approach for Preparing PVC-Based Mikto-Arm Star Additives Based on RAFT Polymerization

    Article • Macromolecules, May 2020, American Chemical Society (ACS)

    Dr Graeme Moad

  48. PET-RAFT polymer synthesis by both high-throughput plate methods and flow chemistry

    Article • Macromolecules, January 2020, American Chemical Society (ACS)

    Dr Graeme Moad

  49. Brief history and summary of recent developments in RAFT polymerization focusing on CSIRO

    Article • Polymer International, December 2019, Wiley

    Dr Graeme Moad

  50. Rapid formation of topographically active surfaces

    Article • Nanomaterials, November 2019, MDPI AG

    Dr Graeme Moad

  51. PET-RAFT SUMI into trithiocarbonate

    Article • Macromolecular Rapid Communications, November 2019, Wiley

    Dr Graeme Moad, Dr Almar Postma

  52. Kinetic modelling of the reversible addition–fragmentation chain transfer polymerisation of N-isopropylacrylamide

    Article • European Polymer Journal, November 2019, Elsevier

    Dr Graeme Moad

  53. Electrochemical Behavior of Thiocarbonylthio Chain Transfer Agents for RAFT Polymerization

    Article • ACS Macro Letters, September 2019, American Chemical Society (ACS)

    Dr Graeme Moad, Dr Almar Postma

  54. Exploitation of the Nanoreactor Concept for Efficient Synthesis of Multiblock Copolymers via MacroRAFT-Mediated Emulsion Polymerization

    Article • ACS Macro Letters, July 2019, American Chemical Society (ACS)

    Dr Graeme Moad

  55. Nano-Engineered Multiblock Copolymer Nanoparticles via Reversible Addition–Fragmentation Chain Transfer Emulsion Polymerization

    Article • Macromolecules, April 2019, American Chemical Society (ACS)

    Dr Graeme Moad

  56. Emerging Polymer Technologies

    Article • Chemistry International, April 2019, De Gruyter

    Dr Graeme Moad

  57. Nonmigratory Poly(vinyl chloride)-block-polycaprolactone Plasticizers and Compatibilizers Prepared by Sequential RAFT and Ring-Opening Polymerization (RAFT-T̵-ROP)

    Article • Macromolecules, February 2019, American Chemical Society (ACS)

    Dr Graeme Moad

  58. Exploitation of Compartmentalization in RAFT Miniemulsion Polymerization to Increase the Degree of Livingness

    Article • Journal of Polymer Science Part A Polymer Chemistry, February 2019, Wiley

    Dr Graeme Moad

  59. Ab initio RAFT emulsion polymerization mediated by small cationic RAFT agents to form polymers with low molar mass dispersity

    Article • Polymer Chemistry, January 2019, Royal Society of Chemistry

    Dr Graeme Moad

  60. Kinetics and mechanism for thermal and photochemical decomposition of 4,4′-azobis(4-cyanopentanoic acid) in aqueous media

    Article • Polymer Chemistry, January 2019, Royal Society of Chemistry

    Dr Graeme Moad, Dr Almar Postma

  61. Synthesis of sequence defined polymers by RAFT

    Article • Journal of the American Chemical Society, September 2018, American Chemical Society (ACS)

    Dr Graeme Moad

  62. A Critical Survey of Dithiocarbamate Reversible Addition-Fragmentation Chain Transfer (RAFT) Agents in Radical Polymerization

    Article • Journal of Polymer Science Part A Polymer Chemistry, September 2018, Wiley

    Dr Graeme Moad

  63. A Critical Assessment of the Kinetics and Mechanism of Initiation of Radical Polymerization with Commercially Available Dialkyldiazene Initiators

    Article • Progress in Polymer Science, August 2018, Elsevier

    Dr Graeme Moad

  64. High yield RAFT single unit monomer insertion with visible light photoinitiation

    Article • Macromolecular Rapid Communications, June 2018, Wiley

    Dr Graeme Moad, Dr Almar Postma

  65. Effect of the Z- and Macro-R-Group on the Thermal Desulfurization of Polymers Synthesized with Acid/Base “Switchable” Dithiocarbamate RAFT Agents

    Article • Macromolecular Rapid Communications, May 2018, Wiley

    Dr Graeme Moad

  66. Effect of Scandium Triflate on the RAFT Copolymerization of Methyl Acrylate and Vinyl Acetate Controlled by an Acid/Base “Switchable” Chain Transfer Agent

    Article • Macromolecules, January 2018, American Chemical Society (ACS)

    Dr Graeme Moad

  67. Synthesis of sequence defined polymers by RAFT

    Article • January 2018, American Chemical Society (ACS)

    Dr Graeme Moad, Dr Almar Postma

  68. In Focus Emerging Polymer Technologies Summit (EPTS'16)

    Article • Polymer International, October 2017, Wiley

    Dr Graeme Moad

  69. Cover Image, Volume 66, Issue 11

    Article • Polymer International, October 2017, Wiley

    Dr Graeme Moad

  70. Dithiobenzoate-Mediated RAFT Polymerization

    Article • Macromolecular Chemistry and Physics, August 2017, Wiley

    Dr Graeme Moad

  71. Broadly applicable RAFT agents

    Article • Polymer International, August 2017, Wiley

    Dr Graeme Moad

  72. Frontispiece: Synthesis of Discrete Oligomers by Sequential PET-RAFT Single-Unit Monomer Insertion

    Article • Angewandte Chemie International Edition, July 2017, Wiley

    Dr Graeme Moad

  73. Frontispiz: Synthesis of Discrete Oligomers by Sequential PET-RAFT Single-Unit Monomer Insertion

    Article • Angewandte Chemie, July 2017, Wiley

    Dr Graeme Moad

  74. Review of the use of RAFT polymerization in the synthesis of stimuli-responsive polymers

    Article • Polymer Chemistry, January 2017, Royal Society of Chemistry

    Dr Graeme Moad

  75. RAFT-mediated, visible light-initiated single unit monomer insertion and its application in the synthesis of sequence-defined polymers

    Article • Polymer Chemistry, January 2017, Royal Society of Chemistry

    Dr Graeme Moad

  76. Pure oligomers in high yield by insertion of units of monomer one at a time into a RAFT agent.

    Article • Angewandte Chemie, December 2016, Wiley

    Dr Graeme Moad

  77. Synthesis of Discrete Oligomers by Sequential PET-RAFT Single-Unit Monomer Insertion

    Article • Angewandte Chemie International Edition, December 2016, Wiley

    Dr Graeme Moad

  78. Antiviral agents based on RAFT-synthesized polymers

    Article • Molecular Pharmaceutics, July 2016, American Chemical Society (ACS)

    Dr Graeme Moad, Dr Almar Postma

  79. Reversible addition-fragmentation chain transfer (co)polymerization of conjugated diene monomers: butadiene, isoprene and chloroprene

    Article • Polymer International, June 2016, Wiley

    Dr Graeme Moad

  80. Dithiocarbamate RAFT agents with broad applicability – the 3,5-dimethyl-1H-pyrazole-1-carbodithioates

    Article • Polymer Chemistry, January 2016, Royal Society of Chemistry

    Dr Graeme Moad

  81. Brief Guide to Polymerization Terminology

    Article • Chemistry International, January 2016, De Gruyter

    Dr Graeme Moad

  82. Antiviral agents based on RAFT-synthesized polymers

    Article • Polymer Chemistry, January 2016, Royal Society of Chemistry

    Dr Graeme Moad, Dr Almar Postma

  83. Radical Polymerization

    Article • January 2016, Elsevier

    Dr Graeme Moad

  84. Radical Addition–Fragmentation Chemistry and RAFT Polymerization

    Article • January 2016, Elsevier

    Dr Graeme Moad

  85. RAFT synthesized monoliths as catalysts in flow chemistry

    Article • Reactive and Functional Polymers, November 2015, Elsevier

    Dr Graeme Moad

  86. Aqueous hydrogen peroxide-induced degradation of polyolefins: A greener process for controlled-rheology polypropylene

    Article • Polymer Degradation and Stability, July 2015, Elsevier

    Dr Graeme Moad

  87. Concise review of developments in the use of switchable RAFT agents

    Article • Macromolecular Symposia, April 2015, Wiley

    Dr Graeme Moad

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

    Article • Polymer Chemistry, January 2015, Royal Society of Chemistry

    Dr Elizabeth G L Williams, Dr Graeme Moad

  89. RAFT polymerization of N-vinylpyrrolidone with “switchable” dithiocarbamates

    Article • Polymer Chemistry, January 2015, Royal Society of Chemistry

    Dr Graeme Moad

  90. RAFT Polymerization – Then and Now

    Article • January 2015, American Chemical Society (ACS)

    Dr Graeme Moad

  91. A history of the development of nitroxide polymerization from its discovery in 1984 through to 2000.

    Article • January 2015, Royal Society of Chemistry

    Dr Graeme Moad

  92. Viscoelastic properties of vis-breaking polypropylenes

    Article • January 2015, American Institute of Physics

    Dr Graeme Moad

  93. pH-Responsive, Endosomolytic Polymer Nanoparticles

    Article • The AAPS Journal, December 2014, American Association of Pharmaceutical Scientists (AAPS)

    Dr Graeme Moad, Dr Almar Postma

  94. RAFT crosslinking polymerization

    Article • Polymer International, June 2014, Wiley

    Dr Graeme Moad

  95. Synthesis of cleavable multi-functional mikto-arm star polymer by RAFT polymerization: example of an anti-cancer drug 7-ethyl-10-hydroxycamptothecin (SN-38) as functional moiety

    Article • Science China Chemistry, June 2014, Springer Science + Business Media

    Dr Graeme Moad

  96. Modeling the Kinetics of Monolith Formation by RAFT Copolymerization of Styrene and Divinylbenzene

    Article • Macromolecular Reaction Engineering, June 2014, Wiley

    Dr Graeme Moad

  97. Single Unit Monomer Insertion (SUMI) into Dithiobenzoate RAFT Agents

    Article • May 2014, MDPI AG

    Dr Graeme Moad

  98. An Arm-First Approach to Cleavable Mikto-Arm Star Polymers by RAFT Polymerization

    Article • Macromolecular Rapid Communications, February 2014, Wiley

    Dr Graeme Moad

  99. Porous monoliths by RAFT polymerization

    Article • Polymer Chemistry, January 2014, Royal Society of Chemistry

    Dr Graeme Moad

  100. quasi-block copolymer libraries via RAFT polymerization

    Article • Polymer Chemistry, January 2014, Royal Society of Chemistry

    Dr Graeme Moad

  101. RAFT for the Control of Monomer Sequence Distribution – Single Unit Monomer Insertion (SUMI) into Dithiobenzoate RAFT Agents

    Article • January 2014, American Chemical Society (ACS)

    Dr Graeme Moad, Dr Almar Postma

  102. Mechanism of Dithiobenzoate-Mediated RAFT Polymerization

    Article • Macromolecular Chemistry and Physics, December 2013, Wiley

    Dr Graeme Moad

  103. ChemInform Abstract: RAFT Polymerization and Some of Its Applications

    Article • ChemInform, October 2013, Wiley

    Dr Graeme Moad

  104. Rapid and Systematic Access to Quasi-Diblock Copolymer Libraries Covering a Comprehensive Composition Range by Sequential RAFT Polymerization in an Automated Synthesizer

    Article • Macromolecular Rapid Communications, August 2013, Wiley

    Dr Graeme Moad

  105. RAFT Polymerization Applications

    Article • Chemistry - An Asian Journal, April 2013, Wiley

    Dr Graeme Moad

  106. Fundamentals of RAFT Polymerization

    Article • April 2013, Royal Society of Chemistry

    Dr Graeme Moad

  107. Glossary of terms relating to thermal and thermomechanical properties of polymers (IUPAC Recommendations 2013)

    Article • Pure and Applied Chemistry, March 2013, De Gruyter

    Dr Graeme Moad

  108. A Brief Guide to Polymer Nomenclature

    Article • Polymer Testing, February 2013, Elsevier

    Dr Graeme Moad

  109. A brief guide to polymer nomenclature from IUPAC

    Article • Colloid & Polymer Science, January 2013, Springer Science + Business Media

    Dr Graeme Moad

  110. ChemInform Abstract: Living Radical Polymerization by the RAFT Process - A Third Update

    Article • ChemInform, January 2013, Wiley

    Dr Graeme Moad

  111. The reactivity of N-vinylcarbazole in RAFT polymerization: trithiocarbonates deliver optimal control for the synthesis of homopolymers and block copolymers

    Article • Polymer Chemistry, January 2013, Royal Society of Chemistry

    Dr Graeme Moad

  112. Controlled Synthesis of Multifunctional Polymers by RAFT for Personal Care Applications

    Article • January 2013, American Chemical Society (ACS)

    Dr Graeme Moad

  113. A Brief Guide to Polymer Nomenclature

    Article • Polymer, January 2013, Elsevier

    Dr Graeme Moad

  114. A brief guide to polymer nomenclature

    Article • Reactive and Functional Polymers, January 2013, Elsevier

    Dr Graeme Moad

  115. A Brief Guide to Polymer Nomenclature

    Article • Progress in Polymer Science, January 2013, Elsevier

    Dr Graeme Moad

  116. A Brief Guide to Polymer Nomenclature

    Article • Polymer Degradation and Stability, January 2013, Elsevier

    Dr Graeme Moad

  117. A Brief Guide to Polymer Nomenclature

    Article • Polymers for Advanced Technologies, December 2012, Wiley

    Dr Graeme Moad

  118. A Brief Guide to Polymer Nomenclature

    Article • Polymer International, December 2012, Wiley

    Dr Graeme Moad

  119. Terminology for aggregation and self-assembly in polymer science (IUPAC Recommendations 2013)

    Article • Pure and Applied Chemistry, December 2012, De Gruyter

    Dr Graeme Moad

  120. A brief guide to polymer nomenclature (IUPAC Technical Report)

    Article • Pure and Applied Chemistry, October 2012, De Gruyter

    Dr Graeme Moad

  121. RAFT Agent Design and Synthesis

    Article • Macromolecules, July 2012, American Chemical Society (ACS)

    Dr Graeme Moad

  122. Chain Transfer Kinetics of Acid/Base Switchable N -Aryl- N -Pyridyl Dithiocarbamate RAFT Agents in Methyl Acrylate, N -Vinylcarbazole and Vinyl Acetate Polymerization

    Article • Macromolecules, May 2012, American Chemical Society (ACS)

    Dr Graeme Moad

  123. The scope for synthesis of macro-RAFT agents by sequential insertion of single monomer units

    Article • Polymer Chemistry, January 2012, Royal Society of Chemistry

    Dr Graeme Moad

  124. Living Radical Polymerization by the RAFT Process ? A Third Update

    Article • Australian Journal of Chemistry, January 2012, CSIRO Publishing

    Dr Graeme Moad

  125. Some Recent Developments in RAFT Polymerization

    Article • January 2012, American Chemical Society (ACS)

    Dr Graeme Moad

  126. Radical Addition–Fragmentation Chemistry and RAFT Polymerization

    Article • January 2012, Elsevier

    Dr Graeme Moad

  127. Radical Polymerization

    Article • January 2012, Elsevier

    Dr Graeme Moad

  128. Switchable Reversible Addition–Fragmentation Chain Transfer (RAFT) Polymerization in Aqueous Solution,N,N-Dimethylacrylamide

    Article • Macromolecules, September 2011, American Chemical Society (ACS)

    Dr Graeme Moad

  129. Controlled RAFT Polymerization in a Continuous Flow Microreactor

    Article • Organic Process Research & Development, May 2011, American Chemical Society (ACS)

    Dr Graeme Moad

  130. Chemical modification of starch by reactive extrusion

    Article • Progress in Polymer Science, February 2011, Elsevier

    Dr Graeme Moad

  131. Block copolymers containing organic semiconductor segments by RAFT polymerization

    Article • Organic & Biomolecular Chemistry, January 2011, Royal Society of Chemistry

    Dr Graeme Moad

  132. Functional polymers for optoelectronic applications by RAFT polymerization

    Article • Polymer Chemistry, January 2011, Royal Society of Chemistry

    Dr Graeme Moad, Dr Almar Postma

  133. A Potential New RAFT - Click Reaction or a Cautionary Note on the Use of Diazomethane to Methylate RAFT-synthesized Polymers

    Article • Australian Journal of Chemistry, January 2011, CSIRO Publishing

    Dr Graeme Moad

  134. Block Copolymer Synthesis through the Use of Switchable RAFT Agents

    Article • January 2011, American Chemical Society (ACS)

    Dr Graeme Moad

  135. End-functional polymers, thiocarbonylthio group removal/transformation and reversible addition-fragmentation-chain transfer (RAFT) polymerization

    Article • Polymer International, December 2010, Wiley

    Dr Graeme Moad

  136. ChemInform Abstract: A Novel Synthesis of Functional Dithioesters, Dithiocarbamates, Xanthates and Trithiocarbonates.

    Article • ChemInform, June 2010, Wiley

    Dr Graeme Moad

  137. ChemInform Abstract: Living Radical Polymerization by the RAFT Process - A Second Update

    Article • ChemInform, March 2010, Wiley

    Dr Graeme Moad

  138. Substituent Effects on RAFT Polymerization with Benzyl Aryl Trithiocarbonates

    Article • Macromolecular Chemistry and Physics, February 2010, Wiley

    Dr Graeme Moad, Professor Loris Giorgini

  139. Polystyrene-block-poly(vinyl acetate) through the Use of a Switchable RAFT Agent

    Article • Macromolecules, December 2009, American Chemical Society (ACS)

    Dr Graeme Moad

  140. Terminology for reversible-deactivation radical polymerization previously called "controlled" radical or "living" radical polymerization (IUPAC Recommendations 2010)

    Article • Pure and Applied Chemistry, November 2009, De Gruyter

    Dr Graeme Moad

  141. Thiocarbonylthio end group removal from RAFT‐synthesized polymers by a radical‐induced process

    Article • Journal of Polymer Science Part A Polymer Chemistry, October 2009, Wiley

    Dr Graeme Moad

  142. New Features of the Mechanism of RAFT Polymerization

    Article • August 2009, American Chemical Society (ACS)

    Dr Graeme Moad

  143. Universal (Switchable) RAFT Agents

    Article • Journal of the American Chemical Society, May 2009, American Chemical Society (ACS)

    Dr Graeme Moad

  144. Refinement, Validation and Application of Cloud-Radiation Parameterization in a GCM

    Article • April 2009, Office of Scientific and Technical Information (OSTI)

    Dr Graeme Moad

  145. Reversible Addition-Fragmentation Chain Transfer Polymerization

    Article • January 2009, Wiley

    Dr Graeme Moad

  146. RAFT Polymerization: Materials of The Future, Science of Today: Radical Polymerization – The Next Stage

    Article • Australian Journal of Chemistry, January 2009, CSIRO Publishing

    Dr Graeme Moad

  147. Living Radical Polymerization by the RAFT Process – A Second Update

    Article • Australian Journal of Chemistry, January 2009, CSIRO Publishing

    Dr Graeme Moad

  148. ChemInform Abstract: Toward Living Radical Polymerization

    Article • ChemInform, December 2008, Wiley

    Dr Graeme Moad

  149. Toward Living Radical Polymerization

    Article • Accounts of Chemical Research, September 2008, American Chemical Society (ACS)

    Dr Graeme Moad

  150. Radical addition–fragmentation chemistry in polymer synthesis

    Article • Polymer, March 2008, Elsevier

    Dr Graeme Moad

  151. Glossary of terms related to kinetics, thermodynamics, and mechanisms of polymerization (IUPAC Recommendations 2008)

    Article • Pure and Applied Chemistry, January 2008, De Gruyter

    Dr Graeme Moad

  152. Reversible Addition Fragmentation Chain Transfer Polymerization of Methyl Methacrylate in the Presence of Lewis Acids:  An Approach to Stereocontrolled Living Radical Polymerization

    Article • Macromolecules, December 2007, American Chemical Society (ACS)

    Dr Graeme Moad

  153. Thiocarbonylthio End Group Removal from RAFT-Synthesized Polymers by Radical-Induced Reduction

    Article • Macromolecules, June 2007, American Chemical Society (ACS)

    Dr Graeme Moad

  154. Living Radical Polymerization by teh RAFT Process — A First Update

    Article • ChemInform, February 2007, Wiley

    Dr Graeme Moad

  155. A small-angle X-ray scattering study of the effect of chain architecture on the shear-induced crystallization of branched and linear poly(ethylene terephthalate)

    Article • Journal of Applied Crystallography, February 2007, International Union of Crystallography

    Dr Graeme Moad

  156. Thermolysis of RAFT-Synthesized Poly(methyl methacrylate).

    Article • ChemInform, February 2007, Wiley

    Dr Graeme Moad

  157. RAFT Polymerization: Adding to the Picture

    Article • Macromolecular Symposia, February 2007, Wiley

    Dr Graeme Moad

  158. Definitions of terms relating to the structure and processing of sols, gels, networks, and inorganic-organic hybrid materials (IUPAC Recommendations 2007)

    Article • Pure and Applied Chemistry, January 2007, De Gruyter

    Dr Graeme Moad

  159. RAFT Copolymerization and Its Application to the Synthesis of Novel Dispersants—Intercalants—Exfoliants for Polymer—Clay Nanocomposites

    Article • September 2006, American Chemical Society (ACS)

    Dr Graeme Moad, Dr Almar Postma

  160. Synthesis of Well-Defined Polystyrene with Primary Amine End Groups through the Use of Phthalimido-Functional RAFT Agents

    Article • Macromolecules, August 2006, American Chemical Society (ACS)

    Dr Graeme Moad, Dr Almar Postma

  161. RAFT Polymerization with Phthalimidomethyl Trithiocarbonates or Xanthates. On the Origin of Bimodal Molecular Weight Distributions in Living Radical Polymerization

    Article • Macromolecules, July 2006, American Chemical Society (ACS)

    Thomas Davis, Dr Graeme Moad, Dr Almar Postma

  162. A simple method for determining protic end-groups of synthetic polymers by 1H NMR spectroscopy

    Article • Polymer, March 2006, Elsevier

    Dr Graeme Moad, Dr Almar Postma

  163. Novel Copolymers as Dispersants/Intercalants/Exfoliants for Polypropylene-Clay Nanocomposites

    Article • Macromolecular Symposia, February 2006, Wiley

    Dr Graeme Moad

  164. Non-Ionic, Poly(ethylene oxide)-Based Surfactants as Intercalants/Dispersants/Exfoliants for Poly(propylene)-Clay Nanocomposites

    Article • Macromolecular Materials and Engineering, January 2006, Wiley

    Dr Graeme Moad

  165. The Emergence of RAFT Polymerization

    Article • Australian Journal of Chemistry, January 2006, CSIRO Publishing

    Dr Graeme Moad

  166. Living Radical Polymerization by the RAFT Process—A First Update

    Article • Australian Journal of Chemistry, January 2006, CSIRO Publishing

    Dr Graeme Moad

  167. Thermolysis of RAFT-Synthesized Poly(Methyl Methacrylate)

    Article • Australian Journal of Chemistry, January 2006, CSIRO Publishing

    Dr Graeme Moad

  168. Crystallisation kinetics of novel branched poly(ethylene terephthalate): a small-angle X-ray scattering study

    Article • Polymer International, January 2006, Wiley

    Dr Graeme Moad

  169. Approaches to phthalimido and amino end-functional polystyrene by atom transfer radical polymerisation (ATRP)

    Article • Reactive and Functional Polymers, January 2006, Elsevier

    Dr Graeme Moad, Dr Almar Postma

  170. Mechanism and kinetics of dithiobenzoate-mediated RAFT polymerization. I. The current situation

    Article • Journal of Polymer Science Part A Polymer Chemistry, January 2006, Wiley

    Dr Graeme Moad

  171. Rheological properties of high melt strength poly(ethylene terephthalate) formed by reactive extrusion

    Article • Journal of Applied Polymer Science, January 2006, Wiley

    Dr Graeme Moad

  172. Binary Copolymerization with Catalytic Chain Transfer. A Method for Synthesizing Macromonomers Based on Monosubstituted Monomers

    Article • Macromolecules, November 2005, American Chemical Society (ACS)

    Dr Graeme Moad, Dr Almar Postma

  173. Living Radical Polymerization by the RAFT Process

    Article • ChemInform, October 2005, Wiley

    Dr Graeme Moad

  174. Advances in RAFT polymerization: the synthesis of polymers with defined end-groups

    Article • Polymer, September 2005, Elsevier

    Dr Graeme Moad, Dr Almar Postma

  175. A novel method for determination of polyester end-groups by NMR spectroscopy

    Article • Polymer, June 2005, Elsevier

    Dr Graeme Moad

  176. Thermolysis of RAFT-Synthesized Polymers. A Convenient Method for Trithiocarbonate Group Elimination

    Article • Macromolecules, June 2005, American Chemical Society (ACS)

    Dr Graeme Moad, Dr Almar Postma

  177. Introduction

    Article • January 2005, Elsevier

    Dr Graeme Moad

  178. Radical Reactions

    Article • January 2005, Elsevier

    Dr Graeme Moad

  179. Propagation

    Article • January 2005, Elsevier

    Dr Graeme Moad

  180. Termination

    Article • January 2005, Elsevier

    Dr Graeme Moad

  181. Chain Transfer

    Article • January 2005, Elsevier

    Dr Graeme Moad

  182. Copolymerization

    Article • January 2005, Elsevier

    Dr Graeme Moad

  183. Controlling Polymerization

    Article • January 2005, Elsevier

    Dr Graeme Moad

  184. Initiation

    Article • January 2005, Elsevier

    Dr Graeme Moad

  185. Preface to the First Edition

    Article • January 2005, Elsevier

    Dr Graeme Moad

  186. Preface to the Second Edition

    Article • January 2005, Elsevier

    Dr Graeme Moad

  187. Living Radical Polymerization by the RAFT Process

    Article • Australian Journal of Chemistry, January 2005, CSIRO Publishing

    Dr Graeme Moad

  188. Living Radical Polymerization

    Article • January 2005, Elsevier

    Dr Graeme Moad

  189. Chain Transfer Activity of ω-Unsaturated Methacrylic Oligomers in Polymerizations of Methacrylic Monomers

    Article • Macromolecules, June 2004, American Chemical Society (ACS)

    Dr Graeme Moad, Dr Almar Postma

  190. Macromolecules containing metal and ?metal-like? elements, Volume 2, Organoiron Polymers. Edited by Alaa S Abd-El-Aziz, Charles E Carraher, Jr, Charles U Pittman, Jr, John E Sheats and Martel Zeldin. John Wiley & Sons, New York, 2003. ISBN 0-471-45078-...

    Article • Polymer International, January 2004, Wiley

    Dr Graeme Moad

  191. Definitions of terms relating to reactions of polymers and to functional polymeric materials (IUPAC Recommendations 2003)

    Article • Pure and Applied Chemistry, January 2004, De Gruyter

    Dr Graeme Moad

  192. Controlled synthesis of block polyesters by reactive extrusion

    Article • Macromolecular Symposia, October 2003, Wiley

    Dr Graeme Moad

  193. Kinetics and Mechanism of RAFT Polymerization

    Article • June 2003, American Chemical Society (ACS)

    Dr Graeme Moad

  194. Effect of R, leaving, group on RAFT agent activity

    Article • Macromolecules, April 2003, American Chemical Society (ACS)

    Dr Graeme Moad, Dr Almar Postma

  195. Effect of Z, activating, Group on RAFT agent activity

    Article • Macromolecules, March 2003, American Chemical Society (ACS)

    Dr Graeme Moad, Dr Almar Postma

  196. Synthesis of novel architectures by radical polymerization with reversible addition fragmentation chain transfer (RAFT polymerization)

    Article • Macromolecular Symposia, March 2003, Wiley

    Dr Graeme Moad

  197. Living Free Radical Polymerization with Reversible Addition−Fragmentation Chain Transfer (RAFT Polymerization):  Approaches to Star Polymers

    Article • Macromolecules, March 2003, American Chemical Society (ACS)

    Dr Graeme Moad

  198. Chain Length Dependence of Radical−Radical Termination in Free Radical Polymerization:  A Pulsed Laser Photolysis Investigation

    Article • Macromolecules, March 2003, American Chemical Society (ACS)

    Dr Graeme Moad

  199. Multiarm organic compounds for use as reversible chain-transfer agents in living radical polymerizations

    Article • Tetrahedron Letters, September 2002, Elsevier

    Dr Graeme Moad

  200. Initiating free radical polymerization

    Article • Macromolecular Symposia, June 2002, Wiley

    Dr Graeme Moad, Dr Almar Postma

  201. Tailored polymer architectures by reversible addition-frasmentation chain transfer

    Article • Macromolecular Symposia, September 2001, Wiley

    Dr Graeme Moad

  202. Mechanism and Kinetics of RAFT-Based Living Radical Polymerizations of Styrene and Methyl Methacrylate

    Article • Macromolecules, January 2001, American Chemical Society (ACS)

    Dr Graeme Moad

  203. Characterization of polyolefin melts using the polymer reference interaction site model integral equation theory with a single-site united atom model

    Article • Journal of Polymer Science Part B Polymer Physics, January 2001, Wiley

    Dr Graeme Moad, Professor Robert A Shanks

  204. Preparation of Macromonomers via Chain Transfer with and without Added Chain Transfer Agent

    Article • August 2000, American Chemical Society (ACS)

    Dr Graeme Moad

  205. Synthesis of Defined Polymers by Reversible Addition—Fragmentation Chain Transfer: The RAFT Process

    Article • August 2000, American Chemical Society (ACS)

    Dr Graeme Moad

  206. Living polymerization: Rationale for uniform terminology

    Article • Journal of Polymer Science Part A Polymer Chemistry, May 2000, Wiley

    Dr Graeme Moad

  207. Living polymerization: Rationale for uniform terminology

    Article • Journal of Polymer Science Part A Polymer Chemistry, May 2000, Wiley

    Dr Graeme Moad

  208. Living polymerization: Rationale for uniform terminology

    Article • Journal of Polymer Science Part A Polymer Chemistry, May 2000, Wiley

    Dr Graeme Moad

  209. Living free radical polymerization with reversible addition - fragmentation chain transfer (the life of RAFT)

    Article • Polymer International, January 2000, Wiley

    Dr Graeme Moad, Dr Almar Postma

  210. Living Polymers by the Use of Trithiocarbonates as Reversible Addition−Fragmentation Chain Transfer (RAFT) Agents:  ABA Triblock Copolymers by Radical Polymerization in Two Steps

    Article • Macromolecules, January 2000, American Chemical Society (ACS)

    Dr Graeme Moad, Dr Almar Postma

  211. 15N CP/MAS solid-state NMR spectroscopy of a 15N-enriched hindered amine light stabilizer photolyzed in acrylic/melamine and acrylic/urethane coatings

    Article • Polymer Degradation and Stability, January 2000, Elsevier

    Dr Graeme Moad

  212. Corrigendum to “The synthesis of polyolefin graft copolymers by reactive extrusion” [Progress in Polymer Science 1999;24:81–142]

    Article • Progress in Polymer Science, December 1999, Elsevier

    Dr Graeme Moad

  213. Chain Transfer to Polymer:  A Convenient Route to Macromonomers

    Article • Macromolecules, November 1999, American Chemical Society (ACS)

    Dr Graeme Moad

  214. Imidazolidinone Nitroxide-Mediated Polymerization

    Article • Macromolecules, October 1999, American Chemical Society (ACS)

    Dr Graeme Moad

  215. Living Radical Polymerization with Reversible Addition−Fragmentation Chain Transfer (RAFT Polymerization) Using Dithiocarbamates as Chain Transfer Agents

    Article • Macromolecules, October 1999, American Chemical Society (ACS)

    Dr Graeme Moad

  216. Tailored polymers by free radical processes

    Article • Macromolecular Symposia, August 1999, Wiley

    Dr Graeme Moad

  217. Living Radical Polymerization with Reversible Addition−Fragmentation Chain Transfer (RAFT):  Direct ESR Observation of Intermediate Radicals

    Article • Macromolecules, August 1999, American Chemical Society (ACS)

    Dr Graeme Moad

  218. Measurements of Primary Radical Concentrations Generated by Pulsed Laser Photolysis Using Fluorescence Detection

    Article • The Journal of Physical Chemistry A, August 1999, American Chemical Society (ACS)

    Dr Graeme Moad

  219. The synthesis of polyolefin graft copolymers by reactive extrusion

    Article • Progress in Polymer Science, April 1999, Elsevier

    Dr Graeme Moad

  220. A novel synthesis of functional dithioesters, dithiocarbamates, xanthates and trithiocarbonates

    Article • Tetrahedron Letters, March 1999, Elsevier

    Dr Graeme Moad

  221. A More Versatile Route to Block Copolymers and Other Polymers of Complex Architecture by Living Radical Polymerization:  The RAFT Process

    Article • Macromolecules, March 1999, American Chemical Society (ACS)

    Dr Graeme Moad

  222. Living Free-Radical Polymerization by Reversible Addition−Fragmentation Chain Transfer:  The RAFT Process

    Article • Macromolecules, August 1998, American Chemical Society (ACS)

    Dr Graeme Moad

  223. Developments in the synthesis of maleated polyolefins by reactive extrusion

    Article • Macromolecular Symposia, March 1998, Wiley

    Dr Graeme Moad

  224. Controlled-Growth Free-Radical Polymerization of Methacrylate Esters: Reversible Chain Transfer versus Reversible Termination

    Article • January 1998, American Chemical Society (ACS)

    Dr Graeme Moad

  225. Direct Measurement of Primary Radical Concentrations in Pulsed Laser Photolysis

    Article • Macromolecules, December 1997, American Chemical Society (ACS)

    Dr Graeme Moad

  226. The Chemistry of Free Radical Polymerization By Graeme Moad (CSIRO, Division of Chemicals and Polymers) and David H. Solomon (University of Melbourne). Elsevier:  Oxford, U.K., 1995. xvi + 408 pp. $120.00. ISBN 0-08-042078-8.

    Article • Journal of the American Chemical Society, November 1997, American Chemical Society (ACS)

    Dr Graeme Moad

  227. Characterization of poly(ethylene terephthalate) and poly(ethylene terephthalate) blends

    Article • Polymer, June 1997, Elsevier

    Dr Graeme Moad

  228. Morphology‐property relationships in ABS/PET blends. I. Compositional effects

    Article • Journal of Applied Polymer Science, December 1996, Wiley

    Dr Graeme Moad

  229. Morphology-property relationships in ABS/PET blends. I. Compositional effects

    Article • Journal of Applied Polymer Science, December 1996, Wiley

    Dr Graeme Moad

  230. Morphology-property relationships in ABS/PET blends. II. Influence of processing conditions on structure and properties

    Article • Journal of Applied Polymer Science, December 1996, Wiley

    Dr Graeme Moad

  231. A new form of controlled growth free radical polymerization

    Article • Macromolecular Symposia, December 1996, Wiley

    Dr Graeme Moad

  232. Control of polymer structure by chain transfer processes

    Article • Macromolecular Symposia, December 1996, Wiley

    Dr Graeme Moad

  233. Chain Transfer Activity of ω-Unsaturated Methyl Methacrylate Oligomers

    Article • Macromolecules, January 1996, American Chemical Society (ACS)

    Dr Graeme Moad

  234. Use of Chain Length Distributions in Determining Chain Transfer Constants and Termination Mechanisms

    Article • Macromolecules, January 1996, American Chemical Society (ACS)

    Dr Graeme Moad

  235. Alkoxyamine-Initiated Living Radical Polymerization: Factors Affecting Alkoxyamine Homolysis Rates

    Article • Macromolecules, December 1995, American Chemical Society (ACS)

    Dr Graeme Moad

  236. Evaluation of propagation rate constants for the free radical polymerization of methacrylonitrile by pulsed laser photolysis

    Article • Macromolecular Rapid Communications, November 1995, Wiley

    Dr Graeme Moad

  237. Narrow Polydispersity Block Copolymers by Free-Radical Polymerization in the Presence of Macromonomers

    Article • Macromolecules, July 1995, American Chemical Society (ACS)

    Dr Graeme Moad

  238. New Free-Radical Ring-Opening Acrylate Monomers

    Article • Macromolecules, December 1994, American Chemical Society (ACS)

    Dr Graeme Moad

  239. Compatibilisation of polystyrene-polyolefin blends

    Article • Polymer Bulletin, April 1994, Springer Science + Business Media

    Dr Graeme Moad

  240. Applications of Labelling and Multidimensional NMR in the Characterization of Synthetic Polymers

    Article • January 1994, Elsevier

    Dr Graeme Moad

  241. Article • Die Makromolekulare Chemie, June 1993, Wiley

    Dr Graeme Moad

  242. Further studies on the thermal decomposition of AIBN—implications concerning the mechanism of termination in methacrylonitrile polymerization

    Article • European Polymer Journal, February 1993, Elsevier

    Dr Graeme Moad

  243. Effect of ethyl aluminium sesquichloride on the relative reactivities of styrene and methyl methacrylate towards the 1-cyano-1-methylethyl and the 1-methyl-1-(methoxycarbonyl)ethyl radicals

    Article • European Polymer Journal, February 1993, Elsevier

    Dr Graeme Moad

  244. Absolute rate constants for radical-monomer reactions

    Article • Polymer Bulletin, December 1992, Springer Science + Business Media

    Dr Graeme Moad

  245. Consistent values of rate parameters in free radical polymerization systems. II. Outstanding dilemmas and recommendations

    Article • Journal of Polymer Science Part A Polymer Chemistry, April 1992, Wiley

    Dr Graeme Moad

  246. Effects of solvent on model copolymerization reactions. A 13C-NMR study

    Article • European Polymer Journal, March 1992, Elsevier

    Dr Graeme Moad

  247. Effect of ethyl aluminium sesquichloride on the specificity of the reactions of 1-methyl-1-methoxycarbonylethyl radical

    Article • Polymer Bulletin, January 1992, Springer Science + Business Media

    Dr Graeme Moad

  248. 13C=O NMR Signal Assignments for Poly(n-butyl methacrylate-co-methyl methacrylate). Application of 13C-1H Correlation Spectroscopy and 13C Labelling

    Article • Polymer Journal, November 1991, Springer Science + Business Media

    Dr Graeme Moad

  249. Computer simulation of the chemical properties of copolymers

    Article • Makromolekulare Chemie Macromolecular Symposia, October 1991, Wiley

    Dr Graeme Moad

  250. Synthetic macromolecules

    Article • October 1990, Royal Society of Chemistry

    Dr Graeme Moad

  251. ChemInform Abstract: Understanding and Controlling Radical Polymerization

    Article • ChemInform, July 1990, Wiley

    Dr Graeme Moad

  252. Invited Review. Understanding and Controlling Radical Polymerization

    Article • Australian Journal of Chemistry, January 1990, CSIRO Publishing

    Dr Graeme Moad

  253. The Application of Supercomputers in Modeling Chemical Reaction Kinetics: Kinetic Simulation of 'Quasi-Living' Radical Polymerization

    Article • Australian Journal of Chemistry, January 1990, CSIRO Publishing

    Dr Graeme Moad

  254. How powerful are composition data in discriminating between the terminal and penultimate models for binary copolymerization?

    Article • Macromolecules, May 1989, American Chemical Society (ACS)

    Dr Graeme Moad

  255. The philicity of tert-butoxy radicals. What factors are important in determining the rate and regiospecificity of tert-butoxy radical addition to olefins?

    Article • The Journal of Organic Chemistry, March 1989, American Chemical Society (ACS)

    Dr Graeme Moad

  256. Chemistry of Bimolecular Termination

    Article • January 1989, Elsevier

    Dr Graeme Moad

  257. Other Initiating Systems

    Article • January 1989, Elsevier

    Dr Graeme Moad

  258. Azo and Peroxy Initiators

    Article • January 1989, Elsevier

    Dr Graeme Moad

  259. “Weak links” in polystyrene—thermal degradation of polymers prepared with AIBN or benzoyl peroxide as initiator

    Article • European Polymer Journal, January 1989, Elsevier

    Dr Graeme Moad

  260. Thermal stability of poly(methyl methacrylate)

    Article • Polymer Bulletin, November 1988, Springer Science + Business Media

    Dr Graeme Moad

  261. End groups of poly(methyl methacrylate-co-styrene) prepared with tert-butoxy, methyl, and/or phenyl radical initiation: effects of solvent, monomer composition, and conversion

    Article • Macromolecules, September 1988, American Chemical Society (ACS)

    Dr Graeme Moad

  262. Consistent values of rate parameters in free radical polymerization systems

    Article • Journal of Polymer Science Polymer Letters Edition, July 1988, Wiley

    Dr Graeme Moad

  263. Thermal stability of benzoyl peroxide-initiated polystyrene

    Article • Macromolecules, May 1988, American Chemical Society (ACS)

    Dr Graeme Moad

  264. Kinetics of the coupling reactions of the nitroxyl radical 1,1,3,3-tetramethylisoindoline-2-oxyl with carbon-centered radicals

    Article • The Journal of Organic Chemistry, April 1988, American Chemical Society (ACS)

    Dr Graeme Moad

  265. Initiation. The reactions of primary radicals

    Article • Makromolekulare Chemie Macromolecular Symposia, October 1987, Wiley

    Dr Graeme Moad

  266. Influences of the initiation and termination reactions on the molecular weight distribution and compositional heterogeneity of functional copolymers: an application of Monte Carlo simulation

    Article • Macromolecules, May 1987, American Chemical Society (ACS)

    Dr Graeme Moad

  267. 13C-1H heteronuclear chemical shift correlation spectroscopy applied to poly(methyl [carbonyl-13C]methacrylate): an unambiguous method for assigning resonances to configurational sequences

    Article • Macromolecules, October 1986, American Chemical Society (ACS)

    Dr Graeme Moad

  268. Kinetic data for coupling of primary alkyl radicals with a stable nitroxide

    Article • Journal of the Chemical Society Chemical Communications, January 1986, Royal Society of Chemistry

    Dr Graeme Moad

  269. Critical-Points (Azeotropic Compositions) in Multicomponent Copolymerization

    Article • Australian Journal of Chemistry, January 1986, CSIRO Publishing

    Dr Graeme Moad

  270. Kinetic Simulation of Polymerization Involving Termination by Reversible Chain Transfer

    Article • Australian Journal of Chemistry, January 1986, CSIRO Publishing

    Dr Graeme Moad

  271. Tacticity of Poly(Methyl Methacrylate). Evidence for a Penpenultimate Group Effect in Free-Radical Polymerization

    Article • Australian Journal of Chemistry, January 1986, CSIRO Publishing

    Dr Graeme Moad

  272. Correction

    Article • Australian Journal of Chemistry, January 1986, CSIRO Publishing

    Dr Graeme Moad

  273. Slow nitrogen inversion–N–O rotation in 2-alkoxy-1,1,3,3-tetramethylisoindolines

    Article • Journal of the Chemical Society Chemical Communications, January 1985, Royal Society of Chemistry

    Dr Graeme Moad

  274. Structural defects in polymers - their identification and significance

    Article • Pure and Applied Chemistry, January 1985, De Gruyter

    Dr Graeme Moad

  275. Critical Points in Binary Copolymerization and the Penultimate Group Effect

    Article • Australian Journal of Chemistry, January 1985, CSIRO Publishing

    Dr Graeme Moad

  276. Fate of the initiator in the azobisisobutyronitrile-initiated polymerization of styrene

    Article • Macromolecules, September 1984, American Chemical Society (ACS)

    Dr Graeme Moad

  277. Evaluation of end groups in poly(methyl methacrylate-co-styrene) by 13C NMR

    Article • Polymer Bulletin, January 1984, Springer Science + Business Media

    Dr Graeme Moad

  278. The use of model compounds in interpreting the thermal degradation of poly(methy methacrylate)

    Article • Polymer Bulletin, January 1984, Springer Science + Business Media

    Dr Graeme Moad

  279. Synthesis of the radical scavenger 1,1,3,3-Tetramethylisoindolin-2-yloxyl

    Article • Australian Journal of Chemistry, January 1983, CSIRO Publishing

    Dr Graeme Moad

  280. On the regioselectivity of free radical processes ; reactions of benzoyloxy, phenyl and t-butoxy radicals with some α,β-unsaturated esters

    Article • Australian Journal of Chemistry, January 1983, CSIRO Publishing

    Dr Graeme Moad

  281. Solvent effects on the reaction of t-butoxy radicals with methyl methacrylate

    Article • Australian Journal of Chemistry, January 1983, CSIRO Publishing

    Dr Graeme Moad

  282. Article • Die Makromolekulare Chemie Rapid Communications, August 1982, Wiley

    Dr Graeme Moad

  283. Structure of benzoyl peroxide initiated polystyrene: determination of the initiator-derived functionality by carbon-13 NMR

    Article • Macromolecules, July 1982, American Chemical Society (ACS)

    Dr Graeme Moad

  284. Selectivity of the reaction of free radicals with styrene

    Article • Macromolecules, May 1982, American Chemical Society (ACS)

    Dr Graeme Moad

  285. A product study of the nitroxide inhibited thermal polymerization of styrene

    Article • Polymer Bulletin, January 1982, Springer Science + Business Media

    Dr Graeme Moad

  286. Head additon of radicals to methyl methacrylate

    Article • Polymer Bulletin, January 1982, Springer Science + Business Media

    Dr Graeme Moad

  287. The Reaction of Benzoyloxy Radicals with Styrene—Implications Concerning the Structure of Polystyrene

    Article • Journal of Macromolecular Science Part A - Chemistry, January 1982, Taylor & Francis

    Dr Graeme Moad

  288. Dr. Young Replies

    Article • Radiology, October 1981, Radiological Society of North America (RSNA)

    Dr Graeme Moad

  289. The reaction of acyl peroxides with 2,2,6,6-tetramethylpiperidinyl-1-oxy

    Article • Tetrahedron Letters, January 1981, Elsevier

    Dr Graeme Moad

  290. Ring-opening of some radicals containing the cyclopropylmethyl system

    Article • Journal of the Chemical Society Perkin Transactions 2, January 1980, Royal Society of Chemistry

    Dr Graeme Moad

  291. The kinetics and mechanism of ring opening of radicals containing the cyclobutylcarbinyl system

    Article • Journal of the Chemical Society Perkin Transactions 2, January 1980, Royal Society of Chemistry

    Dr Graeme Moad

  292. Studies on 6-methyl-5-deazatetrahydropterin and its 4a adducts

    Article • Journal of the American Chemical Society, September 1979, American Chemical Society (ACS)

    Dr Graeme Moad

  293. On the mechanism of decomposition of geminal diamines

    Article • Journal of the American Chemical Society, August 1978, American Chemical Society (ACS)

    Dr Graeme Moad

  294. The mechanism of oxidation of 6-methyl-5-carba-5-deazatetrahydropterin. Evidence for the involvement cf a 4a-adduct in the oxidation of tetrahydropterins.

    Article • Tetrahedron Letters, January 1978, Elsevier

    Dr Graeme Moad

  295. Aluminium-chloride-promoted reactions of ethyl acrylate with olefins

    Article • Australian Journal of Chemistry, January 1977, CSIRO Publishing

    Dr Graeme Moad

  296. ChemInform Abstract: CYCLIZATION OF 3-ALLYLHEX-5-ENYL RADICAL. MECHANISM, AND IMPLICATIONS CONCERNING THE STRUCTURES OF CYCLOPOLYMERS

    Article • Chemischer Informationsdienst, March 1976, Wiley

    Dr Graeme Moad

  297. Cyclization of 3-allylhex-5-enyl radical: mechanism, and implications concerning the structures of cyclopolymers

    Article • Journal of the Chemical Society Perkin Transactions 2, January 1975, Royal Society of Chemistry

    Dr Graeme Moad

  298. Intramolecular addition in hex-5-enyl, hept-6-enyl, and oct-7-enyl radicals

    Article • Journal of the Chemical Society Chemical Communications, January 1974, Royal Society of Chemistry

    Dr Graeme Moad

  299. RAFT Polymerization: Adding to the Picture

    Article • Wiley

    Dr Graeme Moad

  300. RAFT Polymerization in Bulk Monomer or in (Organic) Solution

    Article • Wiley

    Dr Graeme Moad

  301. The Mechanism and Kinetics of the RAFT Process: Overview, Rates, Stabilities, Side Reactions, Product Spectrum and Outstanding Challenges

    Article • Wiley

    Dr Graeme Moad