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Development of a Machine Accessible Kinetic Databank for Radical Polymerizations

Published/Copyright: July 16, 2020
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Chemistry International
From the journal Chemistry International Volume 42 Issue 3

Machine learning is a young discipline in the chemical sciences that has nonetheless led to significant changes in research approaches in a relatively short time span. Any machine-assisted research approach requires training sets and machine-readable databases to retrieve information from. A standardization of notations allows for data exchange between computer systems and softwares. As an example, the recently introduced BigSmiles (simplified molecular-input line-entry system) notation (Lin et alACS Cent. Sci. 2019, 5, 9, 1523-1531; https://doi.org/10.1021/acscentsci.9b00476) allows to exchange structural data for polymer across computer systems.

The IUPAC working party on Modelling of Polymerization Kinetics and Processes has collated significant kinetic data on free radical polymerization in recent years, and published a series of benchmark papers on the topic. While generally available, still many researchers do not make full use of these data sets. A central database will increase awareness and foster better use of the data. More importantly, a machine-readable database will allow for direct and automated exchange of data. For example, kinetic models can always retrieve the latest and most updated kinetic data for specific monomers. In machine-learning approaches, algorithms can make use the data for deep learning and interconnection with other data such as molecular characteristics, physical properties or further kinetic data. This can range from prediction of materials properties to automated process control in synthesis.

The kinetic database will consist of all IUPAC benchmarked kinetic data for free radical polymerization. A further selection of reliable kinetic data will be made to also include monomers that have not yet been critically assessed. For these monomers, the database can serve as a future starting point for data collection. While not part of this project, the same database could later be extended by other parameters, such as overall time conversion relations, molecular weights, and physical properties of the resulting polymers from polymerization. The database will be designed in a fashion to allow facile extension to either direction. First versions of the database will be hosted via Monash University. Source codes will be published open access and long-term migration of the database to central servers is envisaged.

For more information and comments, contact Task Group Chair Tanja Junkers <> | https://iupac.org/project/2019-045-1-400

Online erschienen: 2020-07-16
Erschienen im Druck: 2020-07-01

©2020 IUPAC & De Gruyter. This work is licensed under a Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 International License. For more information, please visit: http://creativecommons.org/licenses/by-nc-nd/4.0/

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https://doi.org/10.1515/ci-2020-0319

Articles in the same Issue

  1. Masthead - Full issue pdf
  2. Treasurer's Column
  3. IUPAC during COVID-19
  4. Features
  5. Reflecting on a Year of Elements
  6. Sustaining Active Learning in Virtual Classroom
  7. Blockchain Technology
  8. Extending electronegativities to superheavy Main Group atoms
  9. Gender Gap in Science
  10. IUPAC Wire
  11. The 2020 Bright Science Award in Materials Sciences goes to Marc Hillmyer
  12. The 2020 Hanwha-Total IUPAC Young Scientist Award goes to Athina Anastasaki and Changle Chen
  13. Ang Li is the recipient of the 2020 Thieme–IUPAC Prize
  14. Winners of the 2020 IUPAC-Solvay International Award for Young Chemists
  15. 2020 IUPAC-ThalesNano Prize In Flow Chemistry and Microfluidics—Call For Nominations
  16. Understanding Chemicals in Products
  17. The Beijing Declaration on Research Data
  18. Announcement of the 2020 L’Oreal Women in Science awardees
  19. IUPAC Periodic Table Challenge 2.0
  20. In Memoriam Maurice (Mo) Williams, 1933 - 2020
  21. Project Place
  22. Guidelines on developing robust biocatalysts for biorefinery
  23. Development of a Standard for FAIR Data Management of Spectroscopic Data
  24. Development of a Machine Accessible Kinetic Databank for Radical Polymerizations
  25. A review of current status of analytical chemistry education
  26. What is the NPU Terminology, and how is it used?
  27. Bookworm
  28. Superheavy
  29. Biomass Burning in Sub-Saharan Africa: Chemical Issues and Action Outreach
  30. Successful Drug Discovery
  31. Conference Call
  32. The World Chemistry Leaders meet the century-old IUPAC
  33. Noncovalent Interactions
  34. IUPAC For Africa
  35. Where 2B & Y
  36. Mark Your Calendar
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