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Chemistry Chat

- Focusing on the Elements - Compounds Composed of Two Elements (2)

 Kentaro Sato

Carbon atoms can assemble into various types of stable molecular skeletons, while they are also capable of forming strong bonds with many other elements. Because of these properties, the combination of carbon and just one other element can create an extremely diverse chemical space. In the previous article we focused on halocarbons, so this time let us take a glance of compounds composed of carbon and metallic elements, and carbon and oxygen.
You can imagine all sorts of compounds based on the combination of carbon and a metallic element. In terms of substances consisting of only the two elements, metal alloys like steel can be included in the same category.
A famous compound made of a metal and carbon is calcium carbide (CaC2). It exists as a relatively stable solid, and since it reacts with water to produce acetylene, it has long been used as a fuel source. Other metals such as sodium and copper form similar acetylides and compounds like Li4C3 and Mg2C3, which are called sesquicarbides, are also known.
There are almost completely unrelated types of compounds too. For example, there are compounds called intercalation compounds, in which metal ions are inserted into the space between the stacked layers of graphite. KC8, a typical example, contains potassium ions between the sheets of graphite and is produced by treating graphite with potassium vapor at a very high temperature. The strongly reducing property of KC8 is often used for purposes such as the formation of multiple bonds between heavy elements.
Graphite intercalation compounds containing alkali and alkaline earth metals other than potassium are known. Some of them show superconductivity as exemplified by CaC6, which is drawing an attention for becoming a superconductor at a relatively high transition temperature of 11.5 K.

When it comes to superconductivity, however, fullerenes “doped” with metallic elements such as potassium are probably more well-known. In 1991, a compound with the composition K3C60 was discovered to exhibit superconductivity at a remarkably high temperature of 33 K and received a considerable attention as a case demonstrating special possibilities of fullerenes. At present, the fullerene doped with cesium (Cs3C60) under pressurized conditions holds the record for the highest transition temperature for molecular superconductors (38 K).

An image of fullerene K3C60 doped with potassium.

An image of fullerene K3C60 doped with potassium.

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In organic compounds, oxygen is the second most important partner of carbon only behind hydrogen. Then, from just carbon and oxygen, how many oxocarbon compounds do you think exist or can be synthesized? The first ones that come to your mind are probably simple oxides such as carbon monoxide and carbon dioxide.

Besides CO and CO2, carbon trioxide and carbon tetroxide are actually known. But of course, these are very unstable species that were only detected as transient intermediates during the reaction of CO2 and O2 under electric discharge conditions.

Carbon trioxide (left, one of possible structures) and carbon tetroxide (right).

Carbon trioxide (left, one of possible structures) and carbon tetroxide (right).

A compound called carbon suboxide (or tricarbon dioxide) is also known. This atypical compound has a structure of O=C=C=C=O in which the five atoms are straightly aligned, and it can be considered as a dehydrated form of malonic acid. It is a gas with a noxious odor that polymerizes easily by external stimuli such as light.
An even longer oxocarbon compound, tetracarbon dioxide (O=C=C=C=C=O), was synthesized by Maier in 1990, and this one is also known to be very unstable. Pentacarbon dioxide (O=C=C=C=C=C=O) was also synthesized by Maier in 1988. Interestingly, though it is prone to polymerization when isolated, it is stable enough to be stored at room temperature as a solution.
A shorter sibling of this family, ethylenedione (O=C=C=O), has never been synthesized or even detected to this day. It is probably one of the simplest yet untouched organic compounds. These oxocarbons have very simple structures consisting of only carbon and oxygen atoms connected linearly, but as is often the case, predicting their physical properties is not as simple.
Cyclic compounds consisting of (CO)n units are another simple but interesting oxocarbons. Compounds with n=3 to 6 have been known, but they decompose easily to carbon monoxide and have been detected only minutely by mass spectrometry.

Among these, cyclohexanehexone (n=6) is also known as triquinoyl and commercially available as a reagent. But it is isolated in hydrated forms, so its actual shape is more like dodecahydroxycyclohexane.

Cyclohexanehexone (triquinoyl)

Cyclohexanehexone (triquinoyl)

In addition to the compounds mentioned thus far, you could come up with many more structural possibilities on paper. However, most of them would be either synthetically inaccessible or too unstable to exist for a meaningful period of time. For instance, the group of compounds shown below has never been synthesized. Even if they were synthesized, it is easy to imagine that they would fall apart quickly into carbon monoxide or carbon dioxide.

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There are compounds that have been synthesized but were either extremely short-lived or only detected to exist analytically (e.g. by NMR). Shown below are the examples of those.

An example of stable oxocarbon compounds is mellitic anhydride, which is a triply dehydrated form of benzenehexacarboxylic acid (mellitic acid) having the molecular formula of C12O9. This is actually a historically venerable compound, with its discovery dating back to 1830 and the discoverers being Justus von Liebig and Friedrich Wöhler, who were two of the founding fathers of organic chemistry. Rather unexpectedly, it was isolated from a mineral ore called mellite. Mellite is a rare rock whose major constituent turns out to be the aluminum salt of mellitic acid, so it makes sense that the rock was the source of this oxocarbon compound.

Mellitic anhydride

Mellitic anhydride

The chemistry of oxocarbons became more and more diverse after 1990’s with the advent of the age of nanocarbons. The oxides of these new carbon allotropes began to appear in journals one after another.
Fullerene C60, for example, can be epoxidized to C60O using appropriate oxidizing agents, and this epoxide is an important intermediate to synthesize various fullerene derivatives. Depending on the oxidation conditions, the polyepoxides such as C60O2 and C60O3 are also produced, and the isomers of C70O are known as well. Moreover, other interesting fullerene oxides, such as C120 in which two buckyballs are linked by an oxolane ring, have been synthesized.

In 2012, the bis-lactone derivative of fullerene C60O4 with a “cage-opened” shape was synthesized. Additionally, further derivatives have been detected by mass spectroscopy including the oxafullerene C58O2, which corresponds to C60O4 minus two molecules of carbon monoxide. Oxocarbon compounds derived from fullerene are likely to continue to expand.

Fullerene bis-lactone C60O4 (left) and oxafullerene C58O2 (right).

Fullerene bis-lactone C60O4 (left) and oxafullerene C58O2 (right).

One of the materials that have attracted an attention recently is graphene oxide. It can be obtained by oxidizing graphite with potassium permanganate or similar reagents. Surprisingly, it was discovered half a century before graphene itself.
Because graphene oxide is thought to contain oxygen atoms not only as epoxides but also as aldehydes and carboxylic acids, it is not precisely a compound composed of only carbon and oxygen. Nevertheless, it has an interesting property that its electric conductivity can be tuned by changing the degree of oxidation, which has led to a growing expectation that it could be a great material for things like electrodes.
As we have gone over, the breadth of compounds made of only carbon and oxygen atoms can be impressive indeed. In my next column, let us move on to the realm of compounds based on carbon and nitrogen.

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Kentaro Sato

[Brief career history] He was born in Ibaraki, Japan, in 1970. 1995 M. Sc. Graduate School of Science and Engineering, Tokyo Institute of Technology. 1995-2007 Researcher in a pharmaceutical company. 2008- Present Freelance science writer. 2009-2012 Project assistant professor of the graduate school of Science, the University of Tokyo. 2014-present Publicist for π-system figuration, scientific research on innovative areas.
[Specialty] Organic chemistry

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