Polymer science explained

Polymer science or macromolecular science is a subfield of materials science concerned with polymers, primarily synthetic polymers such as plastics and elastomers. The field of polymer science includes researchers in multiple disciplines including chemistry, physics, and engineering.

Subdisciplines

This science comprises three main sub-disciplines:

History of polymer science

The first modern example of polymer science is Henri Braconnot's work in the 1830s. Henri, along with Christian Schönbein and others, developed derivatives of the natural polymer cellulose, producing new, semi-synthetic materials, such as celluloid and cellulose acetate. The term "polymer" was coined in 1833 by Jöns Jakob Berzelius, though Berzelius did little that would be considered polymer science in the modern sense. In the 1840s, Friedrich Ludersdorf and Nathaniel Hayward independently discovered that adding sulfur to raw natural rubber (polyisoprene) helped prevent the material from becoming sticky. In 1844 Charles Goodyear received a U.S. patent for vulcanizing natural rubber with sulfur and heat. Thomas Hancock had received a patent for the same process in the UK the year before. This process strengthened natural rubber and prevented it from melting with heat without losing flexibility. This made practical products such as waterproofed articles possible. It also facilitated practical manufacture of such rubberized materials. Vulcanized rubber represents the first commercially successful product of polymer research. In 1884 Hilaire de Chardonnet started the first artificial fiber plant based on regenerated cellulose, or viscose rayon, as a substitute for silk, but it was very flammable.[2] In 1907 Leo Baekeland invented the first synthetic plastic, a thermosetting phenol - formaldehyde resin called Bakelite.[3]

Despite significant advances in polymer synthesis, the molecular nature of polymers was not understood until the work of Hermann Staudinger in 1922.[4] Prior to Staudinger's work, polymers were understood in terms of the association theory or aggregate theory, which originated with Thomas Graham in 1861. Graham proposed that cellulose and other polymers were colloids, aggregates of molecules having small molecular mass connected by an unknown intermolecular force. Hermann Staudinger was the first to propose that polymers consisted of long chains of atoms held together by covalent bonds. It took over a decade for Staudinger's work to gain wide acceptance in the scientific community, work for which he was awarded the Nobel Prize in 1953.

The World War II era marked the emergence of a strong commercial polymer industry. The limited or restricted supply of natural materials such as silk and rubber necessitated the increased production of synthetic substitutes, such as nylon[5] and synthetic rubber.[6] In the intervening years, the development of advanced polymers such as Kevlar and Teflon have continued to fuel a strong and growing polymer industry.

The growth in industrial applications was mirrored by the establishment of strong academic programs and research institutes. In 1946, Herman Mark established the Polymer Research Institute at Brooklyn Polytechnic, the first research facility in the United States dedicated to polymer research. Mark is also recognized as a pioneer in establishing curriculum and pedagogy for the field of polymer science.[7] In 1950, the POLY division of the American Chemical Society was formed, and has since grown to the second-largest division in this association with nearly 8,000 members. Fred W. Billmeyer, Jr., a Professor of Analytical Chemistry had once said that "although the scarcity of education in polymer science is slowly diminishing but it is still evident in many areas. What is most unfortunate is that it appears to exist, not because of a lack of awareness but, rather, a lack of interest."[8]

Nobel prizes related to polymer science

2005 (Chemistry) Robert Grubbs, Richard Schrock, Yves Chauvin for olefin metathesis.[9]

2002 (Chemistry) John Bennett Fenn, Koichi Tanaka, and Kurt Wüthrich for the development of methods for identification and structure analyses of biological macromolecules.[10]

2000 (Chemistry) Alan G. MacDiarmid, Alan J. Heeger, and Hideki Shirakawa for work on conductive polymers, contributing to the advent of molecular electronics.[11]

1991 (Physics) Pierre-Gilles de Gennes for developing a generalized theory of phase transitions with particular applications to describing ordering and phase transitions in polymers.[12]

1974 (Chemistry) Paul J. Flory for contributions to theoretical polymer chemistry.[13]

1963 (Chemistry) Giulio Natta and Karl Ziegler for contributions in polymer synthesis. (Ziegler-Natta catalysis).[14]

1953 (Chemistry) Hermann Staudinger for contributions to the understanding of macromolecular chemistry.[15]

References

External links

Notes and References

  1. McLeish (2009) p. 6811.
  2. Web site: Types of Polymer. Plastics Historical Society. https://web.archive.org/web/20090402043517/http://www.plastiquarian.com/top.htm. 2009-04-02.
  3. Web site: Bakelite: The World's First Synthetic Plastic . https://archive.today/20120722150229/http://portal.acs.org/portal/PublicWebSite/education/whatischemistry/landmarks/bakelite/index.htm . dead . July 22, 2012 . American Chemical Society . National Historic Chemical Landmarks . June 25, 2012 .
  4. Web site: Hermann Staudinger: Foundation of Polymer Science . American Chemical Society . National Historic Chemical Landmarks . June 25, 2012 . dead . https://archive.today/20130112094150/http://portal.acs.org/portal/PublicWebSite/education/whatischemistry/landmarks/staudingerpolymerscience/index.htm . January 12, 2013 .
  5. Web site: Foundation of Polymer Science: Wallace Carothers and the Development of Nylon . https://archive.today/20130223153201/http://portal.acs.org/portal/PublicWebSite/education/whatischemistry/landmarks/carotherspolymers/index.htm . dead . February 23, 2013 . American Chemical Society . National Historic Chemical Landmarks . June 25, 2012 .
  6. Web site: U.S. Synthetic Rubber Program . https://archive.today/20130223103632/http://portal.acs.org/portal/PublicWebSite/education/whatischemistry/landmarks/syntheticrubber/index.htm . dead . February 23, 2013 . American Chemical Society . National Historic Chemical Landmarks . June 25, 2012 .
  7. Web site: Herman Mark and the Polymer Research Institute . https://archive.today/20130112192725/http://portal.acs.org/portal/PublicWebSite/education/whatischemistry/landmarks/polymerresearchinstitute/index.htm . dead . January 12, 2013 . American Chemical Society . National Historic Chemical Landmarks . June 25, 2012 .
  8. Fred W. Billmeyer, Jr., (1984), Third Edition, Textbook of Polymer Science, A Wiley-Interscience Publication. preface to the second edition
  9. Web site: The Nobel Prize in Chemistry 2005 . 2024-01-11 . NobelPrize.org . en-US.
  10. Web site: The Nobel Prize in Chemistry 2002 . 2024-01-11 . NobelPrize.org . en-US.
  11. Web site: The Nobel Prize in Chemistry 2000 . 2024-01-11 . NobelPrize.org . en-US.
  12. Web site: The Nobel Prize in Physics 1991 . 2024-01-11 . NobelPrize.org . en-US.
  13. Web site: The Nobel Prize in Chemistry 1974 . 2024-01-11 . NobelPrize.org . en-US.
  14. Web site: The Nobel Prize in Chemistry 1963 . 2024-01-11 . NobelPrize.org . en-US.
  15. Web site: The Nobel Prize in Chemistry 1953 . 2024-01-11 . NobelPrize.org . en-US.