Polydiacetylenes

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General chemical structure of a polydiacetylene Polydiacetylenes.png
General chemical structure of a polydiacetylene

Polydiacetylenes (PDAs) are a family of conducting polymers closely related to polyacetylene. They are created by the 1,4 topochemical polymerization of diacetylenes. They have multiple applications from the development of organic films to immobilization of other molecules. [1]

Contents

History

The first polydiacetylene to be discovered was Poly(1,6-bishydroxy hexa-2,4-diacetylene) by Gerhard Wegner in 1969. This was achieved by exposing crystals of 1,6-bishydroxy hexa-2,4-diyne to UV light. [2] Polymerization was assumed to occur because of the spatial arrangement of diynes in the crystal, but this was not confirmed until 1972 when Raymond H. Baughman coined the term "topochemical polymerization" to describe polymerization due to spatial arrangement and put forth the spatial requirements needed for a polymerization of this sort. [3]

Synthesis

Ideal spatial parameters for topochemical polymerization Spatial Arrangement of Diynes for PDAs.png
Ideal spatial parameters for topochemical polymerization

Synthesis of polydiacetylenes occurs through topochemical polymerization of 1,3-diynes. Typically, this must occur in the solid state, because many diynes undergo both 1,2 and 1,4 polymerization in solution – such is the case with diiodobutadiyne, [4] and other diynes with electron withdrawing substituents. The ideal arrangement of diynes in the solid state is a repeat distance of 5Å, a 45° tilt angle, and a 3.5Å distance between C1 of one monomer and C4 of the adjacent diyne monomer. [3]

Usually, polymerization is accompanied by a color change, due to the presence of an extended π-system. In addition, many PDAs exhibit thermochromism caused by twisting of the polymer backbone, changing the amount of conjugation in the system. [5] Depending upon the structure of the monomer, the resulting PDA can have interesting properties such as formation of a vesicle or tube structure. [6]

The chromatic transition from blue to red phase of PDA is caused by the electronic structure of PDAs' backbone which is featured by the alternative carbon double bond and carbon triple bond. Upon exposure to the external stimuli such as thermal, chemical and mechanical stimulus, the conjugation effect will endow the chromatic properties to this type material. As far as the pure or "intrinsic" PDAs are concerned, the blue to red phase transition is irreversible, however if the head groups of the PDAs' side chain are strengthened by other structure, for example chelation with metal oxide nanoparticles, it could provide resilience of the backbone to conduct the reversible color change. [7] Several recent researches which assisted by DFT simulation have shown that the chromatic properties could be modified by adjusting the side chain structures of PDA. [8] With the development thin film fabrication technology such as inkjet printing, PDAs could be coated on different substrate materials as multifunctional sensor, for example Kapton films, aluminum foil or even conventional paper. [9] [10]

Zhu et al. have recently published an article about the synthesis of polydiacetylene using copper catalyst. This is first report on synthesis of polydiacetylenes in the solution phase. [11]

Related Research Articles

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<span class="mw-page-title-main">Polyacetylene</span> Organic polymer made of the repeating unit [C2H2]

Polyacetylene usually refers to an organic polymer with the repeating unit [C2H2]n. The name refers to its conceptual construction from polymerization of acetylene to give a chain with repeating olefin groups. This compound is conceptually important, as the discovery of polyacetylene and its high conductivity upon doping helped to launch the field of organic conductive polymers. The high electrical conductivity discovered by Hideki Shirakawa, Alan Heeger, and Alan MacDiarmid for this polymer led to intense interest in the use of organic compounds in microelectronics. This discovery was recognized by the Nobel Prize in Chemistry in 2000. Early work in the field of polyacetylene research was aimed at using doped polymers as easily processable and lightweight "plastic metals". Despite the promise of this polymer in the field of conductive polymers, many of its properties such as instability to air and difficulty with processing have led to avoidance in commercial applications.

<span class="mw-page-title-main">Polythiophene</span>

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<span class="mw-page-title-main">Michael addition reaction</span> Reaction in organic chemistry

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<span class="mw-page-title-main">Polylactic acid</span> Biodegradable polymer

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3
H
4
O
2
)
n
or [–C(CH
3
)HC(=O)O–]
n
, formally obtained by condensation of lactic acid C(CH
3
)(OH)HCOOH
with loss of water. It can also be prepared by ring-opening polymerization of lactide [–C(CH
3
)HC(=O)O–]
2
, the cyclic dimer of the basic repeating unit.

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<span class="mw-page-title-main">PIDA (polymer)</span> Chemical compound

PIDA, or poly(diiododiacetylene), is an organic polymer that has a polydiacetylene backbone. It is one of the simplest polydiacetylenes that has been synthesized, having only iodine atoms as side chains. It is created by 1,4 topochemical polymerization of diiodobutadiyne. It has many implications in the field of polymer chemistry as it can be viewed as a precursor to other polydiacetylenes by replacing iodine atoms with other side chains using organic synthesis, or as an iodinated form of the carbon allotrope carbyne.

<span class="mw-page-title-main">Diiodobutadiyne</span> Chemical compound

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<span class="mw-page-title-main">Polyrotaxane</span>

Polyrotaxane is a type of mechanically interlocked molecule consisting of strings and rings, in which multiple rings are threaded onto a molecular axle and prevented from dethreading by two bulky end groups. As oligomeric or polymeric species of rotaxanes, polyrotaxanes are also capable of converting energy input to molecular movements because the ring motions can be controlled by external stimulus. Polyrotaxanes have attracted much attention for decades, because they can help build functional molecular machines with complicated molecular structure.

<span class="mw-page-title-main">Topochemical polymerization</span>

Topochemical polymerization is a polymerization method performed by monomers aligned in the crystal state. In this process, the monomers are crystallised and polymerised under external stimuli such as heat, light, or pressure. Compared to traditional polymerisation, the movement of monomers was confined by the crystal lattice in topochemical polymerisation, giving rise to polymers with high crystallinity, tacticity, and purity. Topochemical polymerisation can also be used to synthesise unique polymers such as polydiacetylene that are otherwise hard to prepare.

References

  1. Reppy, Mary A.; Pindzola, Bradford A. (2007). "Biosensing with polydiacetylene materials: structures, optical properties and applications". Chemical Communications (42): 4317–38. doi:10.1039/b703691d. PMID   17957278.
  2. Wegner, Gerhard (1969), "Topochemische Reaktionen von Monomeren mit konjugierten Dreifachbindungen / Tochemical Reactions of Monomers with conjugated triple Bonds", Zeitschrift für Naturforschung B, 24 (7): 824–832, doi: 10.1515/znb-1969-0708 , S2CID   98080997
  3. 1 2 Baughman, Raymond H. (1972), "Solid state polymerization of diacetylenes", Journal of Applied Physics, 43 (11): 4362–4378, Bibcode:1972JAP....43.4362B, doi:10.1063/1.1660929
  4. Luo, Liang; Wilhelm, Christopher; Sun, Aiwu; Grey, Clare P.; Lauher, Joseph W.; Goroff, Nancy S. (2008), "Poly(Diiododiacetylene): Preparation, Isolation, and Full Characterization of a Very Simple Poly(diacetylene)", Journal of the American Chemical Society, 130 (24): 7702–7709, doi:10.1021/ja8011403, PMID   18489101
  5. Xuemei Sun; Tao Chen; Sanqing Huang; Li Li; Huisheng Peng (2010). "Chromatic polydiacetylene with novel sensitivity". Chem. Soc. Rev. 39 (11): 4244–4257. doi:10.1039/C001151G. PMID   20877863. S2CID   5317564.
  6. Hsu, Te-Jung; Fowler, Frank W.; Lauher, Joseph (2012), "Preparation and Structure of a Tubular Addition Polymer: A True Synthetic Nanotube", Journal of the American Chemical Society, 134 (1): 142–145, doi:10.1021/ja209792f, PMID   22168532
  7. Wu, Aide; Beck, Christian; Federici, John; Iqbal, Zafar (3 September 2013). "Thermochromism in Polydiacetylene−ZnO Nanocomposites". J. Phys. Chem. C. 117 (38): 19593–19600. doi:10.1021/jp403939p.
  8. Wu, Aide; Gu, Yuan; Tian, Huiquan; Federici, John; Iqbal, Zafar (12 August 2014). "Effect of alkyl chain length on chemical sensing of polydiacetylene and polydiacetylene/ZnO nanocomposites". Colloid Polym Sci. 292 (12): 3137–3146. doi:10.1007/s00396-014-3365-y. S2CID   95537167.
  9. Wu, Aide; Gu, Yuan; Beck, Christian; Iqbal, Zafar; Federici, John (28 November 2013). "Reversible chromatic sensor fabricated by inkjet printing TCDA-ZnO on a paper substrate". Sens. Actuator B-Chem. 193: 10–18. doi:10.1016/j.snb.2013.10.130.
  10. Wu, Aide; Gu, Yuan; Starvou, Constantino; Kazerani, Hamed; Federici, John; Iqbal, Zafar (8 July 2014). "Inkjet printing colorimetric controllable and reversiblepoly-PCDA/ZnO composites". Sens. Actuator B-Chem. 203: 320–326. doi:10.1016/j.snb.2014.06.132.
  11. Sun, Han-Li; Wu, Bin; Liu, Da-Qi; Yu, Zi-Di; Wang, Jun-Jie; Liu, Qianyi; Liu, Xingchen; Niu, Dawen; Dou, Jin-Hu; Zhu, Rong (2022). "Synthesis of Polydiynes via an Unexpected Dimerization/Polymerization Sequence of C3 Propargylic Electrophiles". Journal of the American Chemical Society. 144 (19): 8807–8817. doi:10.1021/jacs.2c02816.