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Lithium carbide

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Lithium carbide
Wireframe model of lithium carbide
Names
Preferred IUPAC name
Lithium acetylide
Systematic IUPAC name
Lithium ethynediide
Other names
  • Dilithium acetylide
  • Lithium dicarbon
  • Lithium percarbide
Identifiers
3D model (JSmol)
ChemSpider
ECHA InfoCard 100.012.710 Edit this at Wikidata
EC Number
  • 213-980-1
UNII
  • InChI=1S/C2.2Li/c1-2;;/q-2;2*+1 checkY
    Key: ARNWQMJQALNBBV-UHFFFAOYSA-N checkY
  • InChI=1S/C2.2Li/c1-2;;/q-2;2*+1
    Key: ARNWQMJQALNBBV-UHFFFAOYSA-N
  • InChI=1/C2.2Li/c1-2;;/q-2;2*+1
    Key: ARNWQMJQALNBBV-UHFFFAOYAB
  • [Li+].[Li+].[C-]#[C-]
Properties
Li2C2
Molar mass 37.9034 g/mol
Appearance Powder
Density 1.3 g/cm3[1]
Melting point 452°C[2]
Reacts
Solubility insoluble in organic solvents
Related compounds
Related compounds
Except where otherwise noted, data are given for materials in their standard state (at 25 °C [77 °F], 100 kPa).
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Lithium carbide, Li2C2, often known as dilithium acetylide, is a chemical compound of lithium and carbon, an acetylide. It is an intermediate compound produced during radiocarbon dating procedures. Li2C2 is one of an extensive range of lithium-carbon compounds which include the lithium-rich Li4C, Li6C2, Li8C3, Li6C3, Li4C3, Li4C5, and the graphite intercalation compounds LiC6, LiC12, and LiC18.

Li2C2 is the most thermodynamically-stable lithium-rich carbide[3] and the only one that can be obtained directly from the elements. It was first produced by Moissan, in 1896[4] who reacted coal with lithium carbonate.

Li2CO3 + 4 C → Li2C2 + 3 CO

The other lithium-rich compounds are produced by reacting lithium vapor with chlorinated hydrocarbons, e.g. CCl4. Lithium carbide is sometimes confused with the drug lithium carbonate, Li2CO3, because of the similarity of its name.

Preparation and chemistry

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In the laboratory samples may be prepared by treating acetylene with a solution of lithium in ammonia, on −40°C, with creation of adduct of Li2C2·C2H2·2NH3 that decomposes in stream of hydrogen at room temperature giving white powder of Li2C2.

C2H2 + 2 Li → Li2C2 + H2

Samples prepared in this manner generally are poorly crystalline. Crystalline samples may be prepared by a reaction between molten lithium and graphite at over 1000 °C.[3] Li2C2 can also be prepared by reacting CO2 with molten lithium.

10 Li + 2 CO2 → Li2C2 + 4 Li2O

Other method for production of Li2C2 is heating of metallic lithium in atmosphere of ethylene.

6 Li + C2H4 → Li2C2 + 4 LiH

Lithium carbide hydrolyzes readily to form acetylene:

Li2C2 + 2 H2O → 2 LiOH + C2H2

Lithium hydride reacts with graphite at 400°C forming lithium carbide.

2 LiH + 4 C → Li2C2 + C2H2

Also Li2C2 can be formed when organometallic compound n-butyllithium reacts with acetylene in THF or Et2O used as a solvent, reaction is rapid and highly exothermic.

C2H2 + 2 CH3CH2CH2CH2Li → Li2C2 + 2 CH3CH2CH2CH3

Lithium carbide reacts with acetylene in liquid ammonia rapidly to give a clear solution of lithium hydrogen acetylide.

Li+[C≡C]Li+ + HC≡CH → 2 Li+[C≡CH]

Preparation of the reagent in this way sometimes improves the yield in an ethynylation over that obtained with reagent prepared from lithium and acetylene.

Structure

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Li2C2 is a Zintl phase compound and exists as a salt, with the formula [Li+]2[C≡C]. Its reactivity, combined with the difficulty in growing suitable single crystals, has made the determination of its crystal structure difficult. It adopts a distorted anti-fluorite crystal structure, similar to that of rubidium peroxide (Rb2O2) and caesium peroxide (Cs2O2). Each lithium atom is surrounded by six carbon atoms from 4 different acetylide anions, with two acetylides co-ordinating side -on and the other two end-on.[3][5] The observed relatively short C-C distance of 120 pm indicates the presence of a C≡C triple bond. At high temperatures Li2C2 transforms reversibly to a cubic anti-fluorite structure.[6]

Use in radiocarbon dating

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There are a number of procedures employed, some that burn the sample producing CO2 that is then reacted with lithium, and others where the carbon containing sample is reacted directly with lithium metal.[7] The outcome is the same: Li2C2 is produced, which can then be used to create species easy to use in mass spectroscopy, like acetylene and benzene.[8] Note that lithium nitride may be formed and this produces ammonia when hydrolyzed, which contaminates the acetylene gas.

References

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  1. ^ R. Juza; V. Wehle; H.-U. Schuster (1967). "Zur Kenntnis des Lithiumacetylids". Zeitschrift für anorganische und allgemeine Chemie. 352 (5–6): 252. doi:10.1002/zaac.19673520506.
  2. ^ Savchenko, A.P.; Kshnyakina, S.A.; H.-Majorova, A.F. (1997). "Thermal properties of lithium carbide and lithium intercalation compounds of graphite". Neorganicheskie Materialy. 33 (11): 1305–1307.
  3. ^ a b c Ruschewitz, Uwe (September 2003). "Binary and ternary carbides of alkali and alkaline-earth metals". Coordination Chemistry Reviews. 244 (1–2): 115–136. doi:10.1016/S0010-8545(03)00102-4.
  4. ^ H. Moissan Comptes Rendus hebd. Seances Acad. Sci. 122, 362 (1896)
  5. ^ Juza, Robert; Opp, Karl (November 1951). "Metallamide und Metallnitride, 24. Mitteilung. Die Kristallstruktur des Lithiumamides". Zeitschrift für anorganische und allgemeine Chemie (in German). 266 (6): 313–324. doi:10.1002/zaac.19512660606.
  6. ^ U. Ruschewitz; R. Pöttgen (1999). "Structural Phase Transition in Li
    2
    C
    2
    ". Zeitschrift für anorganische und allgemeine Chemie. 625 (10): 1599–1603. doi:10.1002/(SICI)1521-3749(199910)625:10<1599::AID-ZAAC1599>3.0.CO;2-J.
  7. ^ Swart E.R. (1964). "The direct conversion of wood charcoal to lithium carbide in the production of acetylene for radiocarbon dating". Cellular and Molecular Life Sciences. 20: 47–48. doi:10.1007/BF02146038. S2CID 31319813.
  8. ^ University of Zurich Radiocarbon Laboratory webpage Archived 2009-08-01 at the Wayback Machine