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Tacticity

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A ball-and-stick model of syndiotactic polypropylene.

Tacticity (from Greek: τακτικός, romanizedtaktikos, "relating to arrangement or order") is the relative stereochemistry of adjacent chiral centers within a macromolecule.[1][better source needed] The practical significance of tacticity rests on the effects on the physical properties of the polymer.[not verified in body] The regularity of the macromolecular structure influences the degree to which it has rigid, crystalline long range order or flexible, amorphous long range disorder.[not verified in body] Precise knowledge of tacticity of a polymer also helps understanding at what temperature a polymer melts, how soluble it is in a solvent,[not verified in body] as well as its mechanical properties.[not verified in body]

A tactic macromolecule in the IUPAC definition is a macromolecule in which essentially all the configurational (repeating) units are identical. In a hydrocarbon macromolecule with all carbon atoms making up the backbone in a tetrahedral molecular geometry, the zigzag backbone is in the paper plane with the substituents either sticking out of the paper or retreating into the paper;[excessive detail?], this projection is called the Natta projection after Giulio Natta.[not verified in body] Tacticity is particularly significant in vinyl polymers of the type -H
2
C-CH(R)-
where each repeating unit with a substituent R on one side of the polymer backbone is followed by the next repeating unit with the substituent on the same side as the previous one, the other side as the previous one or positioned randomly with respect to the previous one.[needs copy edit], Monotactic macromolecules have one stereoisomeric atom per repeat unit,[not verified in body] ditactic to n-tactic macromolecules have more than one stereoisomeric atom per unit.[not verified in body]

IUPAC definition

The orderliness of the succession of configurational repeating units in
the main chain of a regular macromolecule, a regular oligomer molecule,
a regular block, or a regular chain.[2]

Describing tacticity

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An example of m diads in a polypropylene molecule.
An example of r diads diads in a polypropylene molecule.
An isotactic (mm) triad in a polypropylene molecule.
A syndiotactic (rr) triad in a polypropylene molecule.
A heterotactic (rm) triad in a polypropylene molecule.

Diads

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Two adjacent structural units in a polymer molecule constitute a diad. Diads overlap: each structural unit is considered part of two diads, one diad with each neighbor. If a diad consists of two identically oriented units, the diad is called an m diad (formerly meso diad, as in a meso compound, now proscribed[3]). If a diad consists of units oriented in opposition, the diad is called an r diad (formerly racemo diad, as in a racemic compound, now proscribed[3]). In the case of vinyl polymer molecules, an m diad is one in which the substituents are oriented on the same side of the polymer backbone: in the Natta projection, they both point into the plane or both point out of the plane.

Triads

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The stereochemistry of macromolecules can be defined even more precisely with the introduction of triads. An isotactic triad (mm) is made up of two adjacent m diads, a syndiotactic triad (also spelled syndyotactic[4]) (rr) consists of two adjacent r diads, and a heterotactic triad (rm) is composed of an r diad adjacent to an m diad. The mass fraction of isotactic (mm) triads is a common quantitative measure of tacticity.

When the stereochemistry of a macromolecule is considered to be a Bernoulli process, the triad composition can be calculated from the probability Pm of a diad being m type. For example, when this probability is 0.25 then the probability of finding:

  • an isotactic triad is Pm2, or 0.0625
  • an heterotactic triad is 2Pm(1–Pm), or 0.375
  • a syndiotactic triad is (1–Pm)2, or 0.5625

with a total probability of 1. Similar relationships with diads exist for tetrads.[5]: 357 

Tetrads, pentads, etc.

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The definition of tetrads and pentads introduce further sophistication and precision to defining tacticity, especially when information on long-range ordering is desirable.[citation needed] Tacticity measurements obtained by carbon-13 NMR are typically expressed in terms of the relative abundance of various pentads within the polymer molecule, e.g. mmmm, mrrm.[according to whom?]

Other conventions for quantifying tacticity

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The primary convention for expressing tacticity is in terms of the relative weight fraction of triad or higher-order components, as described above. An alternative expression for tacticity is the average length of m and r sequences within the polymer molecule. The average m-sequence length may be approximated from the relative abundance of pentads as follows:[6]

Polymers

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IUPAC definition for a tactic block in a polymer

Isotactic polymers

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Isotactic polymers are composed of isotactic macromolecules (IUPAC definition).[7] In isotactic macromolecules all the substituents are located on the same side of the macromolecular backbone. An isotactic macromolecule consists of 100% m diads, though IUPAC also allows the term for macromolecules with at least 95% m diads if that looser usage is explained.[3] Polypropylene formed by Ziegler–Natta catalysis is an example isotactic polymer.[8] Isotactic polymers are usually semicrystalline and often form a helix configuration.[citation needed]

isotactic polymers
isotactic polypropylene

Syndiotactic polymers

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In syndiotactic or syntactic macromolecules the substituents have alternate positions along the chain. The macromolecule comprises 100% r diads, though IUPAC also allows the term for macromolecules with at least 95% r diads if that looser usage is explained. Syndiotactic polystyrene, made by metallocene catalysis polymerization, is crystalline with a melting point of 161 °C. Gutta percha is also an example syndiotactic polymer.[9]

syndiotactic polymers
syndiotactic polypropylene

Atactic polymers

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In atactic macromolecules the substituents are placed randomly along the chain. The percentage of m diads is understood to be between 45 and 55% unless otherwise specified, but it could be any value other than 0 or 100% if that usage is clarified.[3] With the aid of spectroscopic techniques such as NMR, it is possible to pinpoint the composition of a polymer in terms of the percentages for each triad.[10][better source needed]

atactic polymers

Polymers that are formed by free-radical mechanisms such as polyvinyl chloride are usually atactic.[citation needed] Due to their random nature atactic polymers are usually amorphous.[citation needed] In hemi-isotactic macromolecules every other repeat unit has a random substituent.[citation needed]

Atactic polymers such as polystyrene (PS) are technologically very important.[citation needed] If a special catalyst[clarification needed] is used in its synthesis, it is possible to obtain the syndiotactic version of this polymer, but most industrial polystyrene produced is atactic.[citation needed] The two materials have very different properties because the irregular structure of the atactic version makes it impossible for the polymer chains to stack in a regular fashion: whereas syndiotactic PS is a semicrystalline material, the more common atactic version cannot crystallize and forms a glass instead.[citation needed] This example is quite general in that many polymers of economic importance are atactic glass formers.[citation needed]

Eutactic polymers

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In eutactic macromolecules, substituents may occupy any specific (but potentially complex) sequence of positions along the chain.[citation needed] Isotactic and syndiotactic polymers are instances of the more general class of eutactic polymers, which also includes heterogeneous macromolecules in which the sequence consists of substituents of different kinds (for example, the side-chains in proteins and the bases in nucleic acids).[citation needed]

Head/tail configuration

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In vinyl polymers the complete configuration can be further described by defining polymer head/tail configuration. In a regular macromolecule all monomer units are normally linked in a head to tail configuration so that all β-substituents are separated by three carbon atoms. In head to head configuration this separation is only by two carbon atoms and the separation with tail to tail configuration is by four atoms. Head/tail configurations are not part of polymer tacticity but should be taken into account when considering polymer defects.

Techniques for measuring tacticity

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Tacticity may be measured directly using proton or carbon-13 NMR. This technique enables quantification of the tacticity distribution by comparison of peak areas or integral ranges corresponding to known diads (r, m), triads (mm, rm+mr, rr) and/or higher order n-ads, depending on spectral resolution. In cases of limited resolution, stochastic methods such as Bernoullian or Markovian analysis may also be used to fit the distribution and predict higher n-ads and calculate the isotacticity of the polymer to the desired level.[11]

Other techniques sensitive to tacticity include x-ray powder diffraction, secondary ion mass spectrometry (SIMS),[12] vibrational spectroscopy (FTIR) [13] and especially two-dimensional techniques.[14] Tacticity may also be inferred by measuring another physical property, such as melting temperature, when the relationship between tacticity and that property is well-established.[15]

References

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  1. ^ Introduction to polymers R.J. Young ISBN 0-412-22170-5[page needed][full citation needed]
  2. ^ Jenkins, A. D.; Kratochvíl, P.; Stepto, R. F. T.; Suter, U. W. (1996). "Glossary of basic terms in polymer science (IUPAC Recommendations 1996)" (PDF). Pure and Applied Chemistry. 68 (12): 2287–2311. doi:10.1351/pac199668122287. S2CID 98774337. Archived from the original (PDF) on 2016-03-04. Retrieved 2013-07-25.
  3. ^ a b c d Fellows, Christopher M.; Hellwich, Karl-Heinz; Meille, Stefano V.; Moad, Graeme; Nakano, Tamaki; Vert, Michel (2020). "Definitions and notations relating to tactic polymers (IUPAC Recommendations 2020)". Pure and Applied Chemistry. 92 (11): 1769–1779. doi:10.1515/pac-2019-0409. hdl:11311/1163218.
  4. ^ Webster's Third New International Dictionary of the English Language, Unabridged; Oxford English Dictionary.
  5. ^ Bovey, F. A. (1967). "Configurational Sequence Studies by N.M.R. And the Mechanism of Vinyl Polymerisation" (PDF). Pure and Applied Chemistry. 15 (3–4): 349–368. doi:10.1351/pac196715030349. S2CID 59059402.
  6. ^ Paukkeri, R; Vaananen, T; Lehtinen, A (1993). "Microstructural analysis of polypropylenes produced with heterogeneous Ziegler–Natta catalysts". Polymer. 34 (12): 2488. doi:10.1016/0032-3861(93)90577-W.
  7. ^ IUPAC macromolecular glossary Archived 2008-02-11 at the Wayback Machine
  8. ^ Stevens, P. S. Polymer Chemistry: An Introduction, 3rd ed.; Oxford Press: New York, 1999; pp 234-235
  9. ^ Brandrup, Immergut, Grulke (Editors), Polymer Handbook 4th edition, Wiley-Interscience, New York, 1999. VI/11
  10. ^ Noble, Benjamin Brock (August 2016). Towards Stereocontrol in Radical Polymerization (PDF) (Thesis). Australian National University. doi:10.25911/5d723e5a7c412. S2CID 98943399. Archived from the original (PDF) on 2019-07-14. Retrieved 2019-07-13.
  11. ^ Wu, Ting Kai; Sheer, M. Lana (1977). "Carbon-13 NMR Determination of Pentad Tacticity of Poly(vinyl alcohol)". Macromolecules. 10 (3): 529. Bibcode:1977MaMol..10..529W. doi:10.1021/ma60057a006.
  12. ^ Vanden Eynde, X.; Weng, L. T.; Bertrand, P. (1997). "Influence of Tacticity on Polymer Surfaces Studiedby ToF-SIMS". Surface and Interface Analysis. 25: 41–45. doi:10.1002/(SICI)1096-9918(199701)25:1<41::AID-SIA211>3.0.CO;2-T.
  13. ^ Dybal, J.; Krimm, S. (1990). "Normal-mode analysis of infrared and Raman spectra of crystalline isotactic poly(methyl methacrylate)". Macromolecules. 23 (5): 1301. Bibcode:1990MaMol..23.1301D. doi:10.1021/ma00207a013.
  14. ^ Schilling, Frederic C.; Bovey, Frank A.; Bruch, Martha D.; Kozlowski, Sharon A. (1985). "Observation of the stereochemical configuration of poly(methyl methacrylate) by proton two-dimensional J-correlated and NOE-correlated NMR spectroscopy". Macromolecules. 18 (7): 1418. Bibcode:1985MaMol..18.1418S. doi:10.1021/ma00149a011.
  15. ^ Gitsas, A.; Floudas, G. (2008). "Pressure Dependence of the Glass Transition in Atactic and Isotactic Polypropylene". Macromolecules. 41 (23): 9423. Bibcode:2008MaMol..41.9423G. doi:10.1021/ma8014992.

Further reading

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