Polymer chemistry: Difference between revisions

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'''Polymer chemistry''' or '''macromolecular chemistry''' is a multidisciplinary [[science]] that deals with the [[chemical synthesis]] and [[Chemical property|chemical properties]] of [[polymer]]s or [[macromolecule]]s. According to [[IUPAC]] recommendations, macromolecules refer to the individual molecular chains and are the domain of [[chemistry]]. [[Polymer]]s describe the bulk properties of polymer materials and belong to the field of [[polymer physics]] as a subfield of [[physics]].
'''Polymer chemistry''' or '''[[Macromolecular chemistry]]''' is a multidisciplinary [[science]] that deals with the [[chemical synthesis]] and [[Chemical property|chemical properties]] of [[polymer]]s or [[macromolecule]]s. According to [[IUPAC]] recommendations, macromolecules refer to the individual molecular chains and are the domain of [[chemistry]]. [[Polymer]]s describe the bulk properties of polymer materials and belong to the field of [[polymer physics]] as a subfield of [[physics]].
*[[Biopolymer]]s produced by living organisms:
*[[Biopolymer]]s produced by living organisms:
**structural [[protein]]s: [[collagen]], [[keratin]], [[elastin]]…
**structural [[protein]]s: [[collagen]], [[keratin]], [[elastin]]…

Revision as of 14:14, 21 February 2007

Polymer chemistry or Macromolecular chemistry is a multidisciplinary science that deals with the chemical synthesis and chemical properties of polymers or macromolecules. According to IUPAC recommendations, macromolecules refer to the individual molecular chains and are the domain of chemistry. Polymers describe the bulk properties of polymer materials and belong to the field of polymer physics as a subfield of physics.

Polymers form by polymerization of monomers. A polymer is chemically described by its degree of polymerisation, molar mass distribution, tacticity, copolymer distribution, the degree of branching, by its end-groups, crosslinks, crystallinity and thermal properties such as its glass transition temperature and melting temperature. Polymers in solution have special characteristics with respect to solubility, viscosity and gelation.

History

The work of Henri Braconnot in 1832 and Christian Schönbein in1846 led to the discovery of nitrocellulose, which, when treated with camphor produced celluloid. Dissolved in ether or acetone, it is collodion, used as a wound dressing since the U.S. Civil War. Cellulose acetate was first prepared in 1865. In 1834, 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 rubber with sulfur and heat. Thomas Hancock had received a patent for the same process in the U.K. the year before.

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.[1] In 1907 Leo Baekeland invented the first synthetic polymer, a thermosetting phenol-formaldehyde resin called Bakelite. Cellophane was invented in 1908 by Jocques Brandenberger who squirted sheets of viscose rayon into an acid bath.[2] In 1922 Hermann Staudinger was the first to propose that polymers consisted of long chains of atoms held together by covalent bonds. He also proposed to name these compounds macromolecules. Before that, scientists believed that polymers were clusters of small molecules (called colloids), without definite molecular weights, held together by an unknown force. Staudinger received the Nobel Prize in Chemistry in 1953. Wallace Carothers invented the first synthetic rubber called neoprene in 1931, the first polyester, and went on to invent nylon, a true silk replacement, in 1935. Paul Flory was awarded the Nobel Prize in Chemistry in 1974 for his work on polymer random coil configurations in solution in the 1950s. Stephanie Kwolek developed an aramid, or aromatic nylon named Kevlar, patented in 1966.

There are now a large number of commercial polymers, including composite materials such as carbon fiber-epoxy, polystyrene-polybutadiene (HIPS), acrylonitrile-butadiene-styrene (ABS), and other such materials that combine the best properties of their various components, including polymers designed to work at high temperatures in automobile engines.

External links

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