Linear acetylenic carbon

History and controversy

The first claims of detection of this allotrope were made in 1960 and repeated in 1978. As cited by Kroto(2010). A 1982 re-examination of samples from several previous reports determined that the signals originally attributed to carbyne were in fact due to silicate impurities in the samples. As cited by Kroto(2010). Absence of carbyne crystalline rendered the direct observation of a pure carbyne-assembled solid still a major challenge, because carbyne crystals with well-defined structures and sufficient sizes are not available to date. This is indeed the major obstacle to general acceptance of carbyne as a true carbon allotrope. The mysterious carbyne still attracted scientists with its possible extraordinary properties.

During the past thirty five years an increasing body of experimental and theoretical work has been published in the scientific literature dealing with the preparation of carbyne and the study of its structure, properties and potential applications. In 1968 a silver-white new mineral was discovered in graphitic gneisses of the Ries Crater (Nordlingen, Bavaria, Germany). This material was found to consist entirely of carbon and its hexagonal cell dimensions matched those reported earlier for carbyne by Russian scientists. It was concluded that this novel form of natural carbon, chaoite, was generated from graphite by the combined action of high temperature and high pressure, presumably caused by the impact of meteorite. Soon afterwards this "white" carbon was synthesized by sublimation of pyrolytic graphite in vacuum.

In 1984, a group at Exxon reported the detection of clusters with even numbers of carbons, between 30 and 180, in carbon evaporation experiments, and attributed them to polyyne carbon. As cited by Kroto(2010). However, these clusters later were identified as fullerenes.

In 1991, carbyne was allegedly detected among various other allotropes of carbon in samples of amorphous carbon black vaporized and quenched by shock waves produced by shaped explosive charges.

In 1995, the preparation of carbyne chains with over 300 carbons was reported. They were claimed to be reasonably stable, even against moisture and oxygen, as long as the terminal alkynes on the chain are capped with inert groups (such as tert-butyl or trifluoromethyl) rather than hydrogen atoms. The study claimed that the data specifically indicated a carbyne-like structures rather than fullerene-like ones. However, according to H. Kroto, the properties and synthetic methods used in those studies are consistent with generation of fullerenes.Kasatockin V.I., Koudryavtsev Y.P, Sladkov A.M, Korshak V.V Inventor's certification, N°107 (07/12/1971), priority date 06/11/1960

Another 1995 report claimed detection of carbyne chains of indeterminate length in a layer of carbonized material, about thick, resulting from the reaction of solid polytetrafluoroethylene (PTFE, Teflon) immersed in alkali metal amalgam at ambient temperature (with no hydrogen-bearing species present). The assumed reaction was : , where M is either lithium, sodium, or potassium. The authors conjectured that nanocrystals of the metal fluoride between the chains prevented their polymerization.

In 1999, it was reported that copper(I) acetylide (), after partial oxidation by exposure to air or copper(II) ions followed by decomposition with hydrochloric acid, leaves a "carbonaceous" residue with the spectral signature of chains with n=2–6. The proposed mechanism involves oxidative polymerization of the acetylide anions into carbyne-type anions or cumulene-type anions . Also, thermal decomposition of copper acetylide in vacuum yielded a fluffy deposit of fine carbon powder on the walls of the flask, which, on the basis of spectral data, was claimed to be carbyne rather than graphite. Finally, the oxidation of copper acetylide in ammoniacal solution (Glaser's reaction) produces a carbonaceous residue that was claimed to consist of "polyacetylide" anions capped with residual copper(I) ions, : . On the basis of the residual amount of copper, the mean number of units n was estimated to be around 230.

In 2004, an analysis of a synthesized linear carbon allotrope found it to have a cumulene electronic structure—sequential double bonds along an sp-hybridized carbon chain—rather than the alternating triple–single pattern of linear carbyne.

In 2016, the synthesis of linear chains of up to 6,000 sp-hybridized carbon atoms was reported. The chains were grown inside double-walled carbon nanotubes, and are highly stable protected by their hosts.

Polyynes

While the existence of "carbyne" chains in pure neutral carbon material is still disputed, short chains are well established as substructures of larger molecules (polyynes). As of 2010, the longest such chain in a stable molecule had 22 acetylenic units (44 atoms), stabilized by rather bulky end groups.

Structure

The carbon atoms in this form are each linear in geometry with sp orbital hybridisation. The estimated length of the bonds is (triple) and (single).

Other possible configurations for a chain of carbon atoms include polycumulene (polyethylene-diylidene) chains with double bonds only (). This chain is expected to have slightly higher energy, with a Peierls gap of . For short molecules, however, the polycumulene structure seems favored. When n is even, two ground configurations, very close in energy, may coexist: one linear, and one cyclic (rhombic).

The limits of flexibility of the carbyne chain are illustrated by a synthetic polyyne with a backbone of 8 acetylenic units, whose chain was found to be bent by or more (about at each carbon) in the solid state, to accommodate the bulky end groups of adjacent molecules.

The highly symmetric carbyne chain is expected to have only one Raman-active mode with Σg symmetry, due to stretching of bonds in each single-double pair, with frequency typically between 1800 and ,

Properties

Carbyne chains have been claimed to be the strongest material known per density. Calculations indicate that carbyne's specific tensile strength (strength divided by density) of beats graphene (), carbon nanotubes (), and diamond (). Its specific modulus (Young's Modulus divided by density) of around is also double that of graphene, which is around .

Stretching carbyne 10% alters its electronic band gap from . Outfitted with molecular handles at chain's ends, it can also be twisted to alter its band gap. With a end-to-end twist, carbyne turns into a magnetic semiconductor.

In 2017, the band gaps of confined linear carbon chains (LCC) inside double-walled carbon nanotubes with lengths ranging from 36 up to 6000 carbon atoms were determined for the first time ranging from , following a linear relation with Raman frequency. This lower bound is the smallest band gap of linear carbon chains observed so far. In 2020, the strength (Young's modulus) of linear carbon chains (LCC) was experimentally calculated to be about which is much higher than that of other carbon materials like graphene and carbon nanotubes. The comparison with experimental data obtained for short chains in gas phase or in solution demonstrates the effect of the DWCNT encapsulation, leading to an essential downshift of the band gap.

The LCCs inside double-walled carbon nanotubes lead to an increase of the photoluminescence (PL) signal of the inner tubes up to a factor of 6 for tubes with (8,3) chirality. This behavior can be attributed to a local charge transfer from the inner tubes to the carbon chains, counterbalancing quenching mechanisms induced by the outer tubes.

Carbyne chains can take on side molecules that may make the chains suitable for energy storage.

With a differential Raman scattering cross section of 10−22 cm2 sr−1 per atom, carbyne chains confined inside carbon nanotubes are the strongest Raman scatterer ever reported, exceeding any other know material by two orders of magnitude.

References

References

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