Acetylide Explained

In chemistry, an acetylide is a compound that can be viewed as the result of replacing one or both hydrogen atoms of acetylene (ethyne) by metallic or other cations. The term is also used, more loosely, for any compound obtained in the same way from an acetylene derivative, where R is some organic side chain.

An acetylide may be a salt (ionic compound) containing the anion,, or, as in sodium acetylide or cobalt acetylide .[1] Other acetylides have the metal bound to the carbon atom(s) by covalent bonds, being therefore coordination or organometallic compounds.

When both hydrogens of acetylene are replaced by metals, the compound is a special case of carbide, and may be commonly called such, as in calcium carbide . When only one hydrogen atom is replaced, the anion may be called hydrogen acetylide or the prefix mono- may be attached to the metal, as in monosodium acetylide .

Calcium carbide is an important industrial compound, which has long been used to produce acetylene for welding and illumination. Other acetylides are reagents in organic synthesis.

Structure and bonding

Acetylides of the general formula RC≡CM (where R = H or alkyl) generally show similar properties to their doubly substituted analogues.

Ionic acetylides

Alkali metal and alkaline earth metal acetylides of the general formula MC≡CM are salt-like Zintl phase compounds, containing ions. Evidence for this ionic character can be seen in the ready hydrolysis of these compounds to form acetylene and metal oxides, and by solubility in liquid ammonia with solvated ions[2] .

The ion has a closed shell ground state of 1Σ, making it isoelectronic to a neutral molecule N2, which may afford it some gas-phase stability.[3]

Organometallic acetylides

Some acetylides, particularly of transition metals, show evidences of covalent character, e. g. for being neither dissolved nor decomposed by water and by radically different chemical reactions. That seems to be the case of silver acetylide and copper acetylide, for example.

In the absence of additional ligands, metal acetylides adopt polymeric structures wherein the acetylide groups are bridging ligands.

Preparation

Acetylene and terminal alkynes are weak acids:[4]

RC≡CH + R″M R″H + RC≡CM

Monopotassium and monosodium acetylide can be prepared by reacting acetylene with bases like sodium amide) or the elemental metals, often at room temperature and atmospheric pressure.Copper(I) acetylide can be prepared by passing acetylene through an aqueous solution of copper(I) chloride because of a low solubility equilibrium. Similarly, silver acetylides can be obtained from silver nitrate.

Calcium carbide is prepared by heating carbon with lime (calcium oxide) at approximately 2,000 °C. A similar process is used to produce lithium carbide.

In organic synthesis, acetylides are usually prepared by reacting acetylene and alkynes with organometallic[5] or inorganic[6] superbases in solvents which are less acidic than the terminal alkyne. The classical solvent was liquid ammonia, but ethers are now more commonly used.

Lithium amide, LiHMDS,[7] or organolithium reagents, such as butyllithium, are frequently used to form lithium acetylides:

+ BuLi ->[\ce{THF}][-78^\circ\ce C] + BuH

Reactions

Ionic acetylides are typically decomposed by water with evolution of acetylene:

+ 2 → +

+ → +

Acetylides of the type RC2M are widely used in alkynylations in organic chemistry. They are nucleophiles that add to a variety of electrophilic and unsaturated substrates.

A classic application is the Favorskii reaction, such as in the sequence shown below. Here ethyl propiolate is deprotonated by n-butyllithium to give the corresponding lithium acetylide. This acetylide adds to the carbonyl center of cyclopentanone. Hydrolysis liberates the alkynyl alcohol.[8]

The dimerization of acetylene to vinylacetylene proceeds by insertion of acetylene into a copper(I) acetylide complex.[9]

Coupling reactions

Acetylides are sometimes used as intermediates in coupling reactions. Examples include Sonogashira coupling, Cadiot-Chodkiewicz coupling, Glaser coupling and Eglinton coupling.

Hazards

Some acetylides are notoriously explosive.[10] Formation of acetylides poses a risk in handling of gaseous acetylene in presence of metals such as mercury, silver or copper, or alloys with their high content (brass, bronze, silver solder).

See also

Notes and References

  1. Junichi Nishijo, Kentaroh Kosugi, Hiroshi Sawa, Chie Okabe, Ken Judai, Nobuyuki Nishi (2005): "Water-induced ferromagnetism in cobalt acetylide CoC2 nanoparticles". Polyhedron, volume 24, issues 16–17, pages 2148-2152.
  2. Hamberger. Markus. Liebig. Stefan. Friedrich. Ute. Korber. Nikolaus. Ruschewitz. Uwe. Evidence of Solubility of the Acetylide Ion : Syntheses and Crystal Structures of K2C2·2 NH3, Rb2C2·2 NH3, and Cs2C2·7 NH3. Angewandte Chemie International Edition. 21 December 2012. 51. 52. 13006–13010. 10.1002/anie.201206349. 23161511.
  3. Sommerfeld. T.. Riss. U.. Meyer. H.-D.. Cederbaum. L.. Metastable Dianion. Physical Review Letters. August 1997. 79. 7. 1237–1240. 10.1103/PhysRevLett.79.1237. 1997PhRvL..79.1237S.
  4. Viehe. Heinz Günter. Chemistry of Acetylenes. Angewandte Chemie. 84. 8. 1969. Marcel Dekker. New York. 170–179 & 225–241. 1st. 10.1002/ange.19720840843.
  5. Midland. M. M.. McLoughlin. J. I.. Werley. Ralph T. Jr.. 1990. Preparation and Use of Lithium Acetylide: 1-Methyl-2-ethynyl-endo-3,3-dimethyl-2-norbornanol. Organic Syntheses. 68. 14. 10.15227/orgsyn.068.0014.
  6. Coffman. Donald D.. Dimethylethhynylcarbinol. Organic Syntheses. 1940. 40. 20. 10.15227/orgsyn.020.0040.
  7. Addition of a lithium acetylide to an aldehyde; 1-(2-pentyn-4-ol)-cyclopent-2-en-1-ol. Reich. Melanie. August 24, 2001. ChemSpider Synthetic Pages. 137. 10.1039/SP137. Data Set.
  8. Midland. M. Mark. Tramontano. Alfonso. Cable. John R.. Synthesis of alkyl 4-hydroxy-2-alkynoates. The Journal of Organic Chemistry. 1980. 45. 1. 28–29. 10.1021/jo01289a006.
  9. 10.1021/cr400357r . Catalytic Reactions of Acetylene: A Feedstock for the Chemical Industry Revisited . 2014 . Trotuş . Ioan-Teodor . Zimmermann . Tobias . Schüth . Ferdi . Chemical Reviews . 114 . 3 . 1761–1782 . 24228942 . free .
  10. Cataldo. Franco. Casari. Carlo S.. Synthesis, Structure and Thermal Properties of Copper and Silver Polyynides and Acetylides. Journal of Inorganic and Organometallic Polymers and Materials. 17. 4. 2007. 641–651. 1574-1443. 10.1007/s10904-007-9150-3. 96278932.