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Wikipedia

Diborane

January 07, 2023

See also: diborane(2) and diborane(4)

Diborane(6), generally known as diborane, is the chemical compound with the formula B2H6. It is a toxic, colorless, and pyrophoric gas with a repulsively sweet odor. Diborane is a key boron compound with a variety of applications. It has attracted wide attention for its electronic structure. Several of its derivatives are useful reagents.

Diborane
Names
IUPAC name
Diborane(6)
Identifiers
  • 19287-45-7 Y
3D model (JSmol)
  • Interactive image
ChEBI
  • CHEBI:33590 Y
ChemSpider
  • 17215804 Y
ECHA InfoCard 100.039.021
EC Number
  • 242-940-6
  • 6328200 incorrect structure
RTECS number
  • HQ9275000
UNII
  • BS9K982N24
UN number 1911
  • DTXSID9024938
  • InChI=1S/B2H6/c1-3-2-4-1/h1-2H2 Y
    Key: KLDBIFITUCWVCC-UHFFFAOYSA-N Y
  • InChI=1/B2H6/c1-3-2-4-1/h1-2H2
    Key: KLDBIFITUCWVCC-UHFFFAOYAF
  • [BH2]1[H][BH2][H]1
Properties
B2H6
Molar mass 27.67 g·mol−1
Appearance Colorless gas
Odor repulsive and sweet
Density 1.131 g/L[1]
Melting point −164.85 °C (−264.73 °F; 108.30 K)[1]
Boiling point −92.49 °C (−134.48 °F; 180.66 K)[1]
Reacts[2]
Solubility in other solvents Diglyme and Diethyl Ether,[3]
Vapor pressure 39.5 atm (16.6 °C)[2]
Structure
Tetrahedral (for boron)
see text
0 D
Thermochemistry
56.7 J/(mol·K)[4]
232.1 J/(mol·K)[4]
36.4 kJ/mol[4]
Hazards
Occupational safety and health (OHS/OSH):
Main hazards
 toxic, highly flammable, reacts with water
GHS labelling:
Danger
H220, H280, H314, H330, H370, H372
P210, P260, P264, P270, P271, P280, P284, P301+P330+P331, P303+P361+P353, P304+P340, P305+P351+P338, P307+P311, P310, P314, P320, P321, P363, P377, P381, P403, P403+P233, P405, P410+P403, P501
NFPA 704 (fire diamond)
38 °C (100 °F; 311 K)
Explosive limits 0.8–88%[2]
Lethal dose or concentration (LD, LC):
40 ppm (rat, 4 h)
29 ppm (mouse, 4 h)
40–80 ppm (rat, 4 h)
159–181 ppm (rat, 15 min)[5]
125 ppm (dog, 2 h)
50 ppm (hamster, 8 h)[5]
NIOSH (US health exposure limits):
PEL (Permissible)
 TWA 0.1 ppm (0.1 mg/m3)[2]
REL (Recommended)
 TWA 0.1 ppm (0.1 mg/m3)[2]
IDLH (Immediate danger)
 15 ppm[2]
Related compounds
Related boron compounds
 Decaborane
BF3
Except where otherwise noted, data are given for materials in their standard state (at 25 °C [77 °F], 100 kPa).
Y verify (what is YN ?)

Structure and bonding

 
Bonding diagram of diborane (B2H6) showing with curved lines a pair of three-center two-electron bonds, each of which consists of a pair of electrons bonding three atoms; two boron atoms and a hydrogen atom in the middle

The structure of diborane has D2h symmetry. Four hydrides are terminal, while two bridge between the boron centers. The lengths of the B–Hbridge bonds and the B–Hterminal bonds are 1.33 and 1.19 Å respectively. This difference in bond lengths reflects the difference in their strengths, the B–Hbridge bonds being relatively weaker. The weakness of the B–Hbridge compared to B–Hterminal bonds is indicated by their vibrational signatures in the infrared spectrum, being ≈2100 and 2500 cm−1 respectively.[7]

The model determined by molecular orbital theory describes the bonds between boron and the terminal hydrogen atoms as conventional 2-center 2-electron covalent bonds. The bonding between the boron atoms and the bridging hydrogen atoms is, however, different from that in molecules such as hydrocarbons. Each boron uses two electrons in bonding to the terminal hydrogen atoms and has one valence electron remaining for additional bonding. The bridging hydrogen atoms provide one electron each. The B2H2 ring is held together by four electrons forming two 3-center 2-electron bonds. This type of bond is sometimes called a "banana bond".

B2H6 is isoelectronic with C2H62+, which would arise from the diprotonation of the planar molecule ethylene.[8] Diborane is one of many compounds with such unusual bonding.[9]

Of the other elements in group IIIA, gallium is known to form a similar compound digallane, Ga2H6. Aluminium forms a polymeric hydride, (AlH3)n; although unstable, Al2H6 has been isolated in solid hydrogen and is isostructural with diborane.[10]

Production and synthesis

Extensive studies of diborane have led to the development of multiple synthesis routes. Most preparations entail reactions of hydride donors with boron halides or alkoxides. The industrial synthesis of diborane involves the reduction of BF3 by sodium hydride (NaH), lithium hydride (LiH) or lithium aluminium hydride (LiAlH4):[11]

8 BF3 + 6 LiH → B2H6 + 6 LiBF4

Two laboratory methods start from boron trichloride with lithium aluminium hydride or from boron trifluoride ether solution with sodium borohydride. Both methods result in as much as 30% yield:

4 BCl3 + 3 LiAlH4 → 2 B2H6 + 3 LiAlCl4
4 BF3 + 3 NaBH4 → 2 B2H6 + 3 NaBF4

Older methods entail the direct reaction of borohydride salts with a non-oxidizing acid, such as phosphoric acid or dilute sulfuric acid.

2 BH4 + 2 H+ → 2 H2 + B2H6

Similarly, oxidation of borohydride salts has been demonstrated and remains convenient for small-scale preparations. For example, using iodine as an oxidizer:

2 NaBH
4 + I
2 → 2 NaI + B
2H
6 + H
2

Another small-scale synthesis uses potassium hydroborate and phosphoric acid as starting materials.[12]

Reactions

 
Borane dimethylsulfide generally functions equivalently to diborane and is easier to use.[13]

Diborane is a highly reactive and versatile reagent.[14]

Air, water, oxygen

As a pyrophoric substance, diborane reacts exothermically with oxygen to form boron trioxide and water:

2 B2H6 + 6 O2 → 2 B2O3 + 6 H2O (ΔHr = −2035 kJ/mol = −73.47 kJ/g)

Diborane reacts violently with water to form hydrogen and boric acid:

B2H6 + 6 H2O → 2 B(OH)3 + 6 H2Hr = −466 kJ/mol = −16.82 kJ/g)

Diborane also reacts with alcohols similarly. Methanol for example give hydrogen and trimethylborate:[15]

B2H6 + 6 MeOH → 2 B(OMe)3 + 6 H2

Lewis acidity

One dominating reaction pattern involves formation of adducts with Lewis bases. Often such initial adducts proceed rapidly to give other products. For example, borane-tetrahydrofuran, which often behaves as an equivalently to diborane, degrades to borate esters. Its adduct with dimethyl sulfide is an important reagent in organic synthesis.

With ammonia diborane forms the diammoniate of diborane, DADB with small quantities of ammonia borane as byproduct. The ratio depends on the conditions.

Hydroboration

In the hydroboration reaction, diborane also reacts readily with alkenes to form trialkylboranes. This reaction pattern is rather general and the resulting alkyl borates can be readily derivatized, e.g. to alcohols. Although early work on hydroboration relied on diborane, it has been replaced by borane dimethylsulfide, which is more safely handled.

Other

Pyrolysis of diborane gives hydrogen and diverse boron hydride clusters. For example, pentaborane was first prepared by pyrolysis of diborane at about 200 °C.[16][17] Although this pyrolysis route is rarely employed, it ushered in a large research theme of borane cluster chemistry.

Treating diborane with sodium amalgam gives NaBH4 and Na[B3H8][15] When diborane is treated with lithium hydride in diethyl ether, lithium borohydride is formed:[15]

B2H6 + 2 LiH → 2 LiBH4

Diborane reacts with anhydrous hydrogen chloride or hydrogen bromide gas to give a boron halohydride:[15]

B2H6 + HX → B2H5X + H2 (X = Cl, Br)

Treating diborane with carbon monoxide at 470 K and 20 bar gives H3BCO.[15]

Reagent in organic synthesis

Diborane and its variants are central organic synthesis reagents for hydroboration. Alkenes add across the B–H bonds to give trialkylboranes, which can be further elaborated.[18] Diborane is used as a reducing agent roughly complementary to the reactivity of lithium aluminium hydride. The compound readily reduces carboxylic acids to the corresponding alcohols, whereas ketones react only sluggishly.

History

Diborane was first synthesised in the 19th century by hydrolysis of metal borides, but it was never analysed. From 1912 to 1936, Alfred Stock, the major pioneer in the chemistry of boron hydrides, undertook his research that led to the methods for the synthesis and handling of the highly reactive, volatile, and often toxic boron hydrides. He proposed the first ethane-like structure of diborane.[19] Electron diffraction measurements by S. H. Bauer initially appeared to support his proposed structure.[20][21]

Because of a personal communication with L. Pauling (who supported the ethane-like structure), H. I. Schlessinger and A. B. Burg did not specifically discuss 3-center 2-electron bonding in their then classic review in the early 1940s.[22] The review does, however, discuss the bridged D2h structure in some depth: "It is to be recognized that this formulation easily accounts for many of the chemical properties of diborane..."

In 1943, H. Christopher Longuet-Higgins, while still an undergraduate at Oxford, was the first to explain the structure and bonding of the boron hydrides. The article reporting the work, written with his tutor R. P. Bell,[23] also reviews the history of the subject beginning with the work of Dilthey.[24] Shortly afterwards, the theoretical work of Longuet-Higgins was confirmed in an infrared study of diborane by Price. [25] The structure was re-confirmed by electron-diffraction measurement in 1951 by K. Hedberg and V. Schomaker, with the confirmation of the structure shown in the schemes on this page.[26]

William Nunn Lipscomb Jr. further confirmed the molecular structure of boranes using X-ray crystallography in the 1950s and developed theories to explain their bonding. Later, he applied the same methods to related problems, including the structure of carboranes, on which he directed the research of future 1981 Nobel Prize winner Roald Hoffmann. The 1976 Nobel Prize in Chemistry was awarded to Lipscomb "for his studies on the structure of boranes illuminating problems of chemical bonding".[27]

Traditionally, diborane has often been described as electron-deficient, because the 12 valence electrons can only form 6 conventional 2-centre 2-electron bonds, which are insufficient to join all 8 atoms.[28][29] However, the more correct description using 3-centre bonds shows that diborane is really electron-precise, since there are just enough valence electrons to fill the 6 bonding molecular orbitals.[30] Nevertheless, some leading textbooks still use the term "electron-deficient".[31]

Other uses

Because of the exothermicity of its reaction with oxygen, diborane has been tested as a rocket propellant.[32] Complete combustion is strongly exothermic. However, combustion is not complete in the rocket engine, as some boron monoxide, B2O, is produced. This conversion mirrors the incomplete combustion of hydrocarbons, to produce carbon monoxide (CO). Diborane also proved difficult to handle.[33][34][35]

Diborane has been investigated as a precursor to metal boride films[36] and for the p-doping of silicon semiconductors.[37]

Safety

Diborane is a pyrophoric gas. Commercially available adducts are typically used instead, at least for applications in organic chemistry. These adducts include borane-tetrahydrofuran (borane-THF) and borane-dimethylsulfide.[14] The toxic effects of diborane are mitigated because the compound is so unstable in air. The toxicity toward laboratory rats has been investigated.[38]

References

  1. ^ a b c Haynes, p. 4.52.
  2. ^ a b c d e f NIOSH Pocket Guide to Chemical Hazards. "#0183". National Institute for Occupational Safety and Health (NIOSH).
  3. ^ Yerazunis, S., et al. “Solubility of Diborane in the Dimethyl Ether and Diethylene Glycol, in Mixtures of Sodium Borohydride and Dimethyl Ether of Diethylene Glycol, and in Ditertiary Butyl Sulfide.” Journal of Chemical & Engineering Data, vol. 7, no. 3, July 1962, pp. 337–39, doi:10.1021/je60014a004.
  4. ^ a b c Haynes, p. 5.6.
  5. ^ a b "Diborane". Immediately Dangerous to Life or Health Concentrations (IDLH). National Institute for Occupational Safety and Health (NIOSH).
  6. ^ "DIBORANE – CAMEO Chemicals - Chemical Datasheet - Database of Hazardous Materials – NOAA". Retrieved 2022-10-26.
  7. ^ Cooper, C. B., III; Shriver, D. F.; Onaka, S. (1978). "Ch. 17. Vibrational spectroscopy of hydride-bridged transition metal compounds". Transition Metal Hydrides. Advances in Chemistry. Vol. 167. pp. 232–247. doi:10.1021/ba-1978-0167.ch017. ISBN 9780841203907.{{cite book}}: CS1 maint: multiple names: authors list (link)
  8. ^ Rasul, G.; Prakash, G. K. S.; Olah, G. A. (2005). "Comparative ab initio Study of the Structures and Stabilities of the Ethane Dication C2H62+ and Its Silicon Analogues Si2H62+ and CSiH62+". Journal of Physical Chemistry A. 109 (5): 798–801. Bibcode:2005JPCA..109..798R. doi:10.1021/jp0404652. PMID 16838949.
  9. ^ Laszlo, P. (2000). "A Diborane Story". Angewandte Chemie International Edition. 39 (12): 2071–2072. doi:10.1002/1521-3773(20000616)39:12<2071::AID-ANIE2071>3.0.CO;2-C. PMID 10941018.
  10. ^ Andrews, L.; Wang, X. (2003). "The Infrared Spectrum of Al2H6 in Solid Hydrogen". Science. 299 (5615): 2049–2052. Bibcode:2003Sci...299.2049A. doi:10.1126/science.1082456. PMID 12663923. S2CID 45856199.
  11. ^ Brauer, Georg (1963). Handbook of Preparative Inorganic Chemistry. Vol. 1 (2nd ed.). New York: Academic Press. p. 773. ISBN 978-0121266011.
  12. ^ Norman, A. D.; Jolly, W. L.; Saturnino, D.; Shore, S. G. (1968). Diborane. Inorganic Syntheses. Vol. 11. pp. 15–19. doi:10.1002/9780470132425.ch4. ISBN 9780470132425.
  13. ^ Hutchins, Robert O.; Cistone, Frank (1981). "Utility and Applications of Borane Dimethylsulfide in Organic Synthesis. A Review". Organic Preparations and Procedures International. 13 (3–4): 225. doi:10.1080/00304948109356130.
  14. ^ a b Mikhailov, B. M. (1962). "The Chemistry of Diborane". Russian Chemical Reviews. 31 (4): 207–224. Bibcode:1962RuCRv..31..207M. doi:10.1070/RC1962v031n04ABEH001281. S2CID 250909492.
  15. ^ a b c d e Housecroft, C. E.; Sharpe, A. G. (2008). "Chapter 13: The Group 13 Elements". Inorganic Chemistry (3rd ed.). Pearson. p. 336. ISBN 978-0-13-175553-6.
  16. ^ Stock, A. (1933). The Hydrides of Boron and Silicon. New York: Cornell University Press. ISBN 0-8014-0412-6.
  17. ^ Miller, V. R.; Ryschkewitsch, G. E. (1974). Pentaborane(9) (B5H9). Inorganic Syntheses. Vol. 15. pp. 118–122. doi:10.1002/9780470132463.ch26. ISBN 9780470132463.
  18. ^ Lane, Clinton F. (1976). "Reduction of organic compounds with diborane". Chemical Reviews. 76 (6): 773–799. doi:10.1021/cr60304a005.
  19. ^ Stock, A. (1933). The Hydrides of Boron and Silicon. New York: Cornell University Press.
  20. ^ Bauer, S. H. (1937). "The Structure of Diborane". Journal of the American Chemical Society. 59 (6): 1096–1103. doi:10.1021/ja01285a041.
  21. ^ Bauer, S. H. (1942). "Structures and Physical Properties of the Hydrides of Boron and of their Derivatives". Chemical Reviews. 31 (1): 43–75. doi:10.1021/cr60098a002.
  22. ^ Schlesinger, H. I.; Burg, A. B. (1942). "Recent Developments in the Chemistry of the Boron Hydrides". Chemical Reviews. 31 (1): 1–41. doi:10.1021/cr60098a001.
  23. ^ Longuet-Higgins, H. C.; Bell, R. P. (1943). "64. The Structure of the Boron Hydrides". Journal of the Chemical Society (Resumed). 1943: 250–255. doi:10.1039/JR9430000250.
  24. ^ Dilthey, W. (1921). "Über die Konstitution des Wassers". Angewandte Chemie. 34 (95): 596. doi:10.1002/ange.19210349509.
  25. ^ Price, W. C. (1948). "The absorption spectrum of diborane". J. Chem. Phys. 16 (9): 894. Bibcode:1948JChPh..16..894P. doi:10.1063/1.1747028.
  26. ^ Hedberg, K.; Schomaker, V. (1951). "A Reinvestigation of the Structures of Diborane and Ethane by Electron Diffraction". Journal of the American Chemical Society. 73 (4): 1482–1487. doi:10.1021/ja01148a022.
  27. ^ "The Nobel Prize in Chemistry 1976". Nobelprize.org. Retrieved 2012-02-01.
  28. ^ Longuet-Higgins, H. C. (1957). "The structures of electron-deficient molecules". Quarterly Reviews, Chemical Society. 11 (2): 121–133. doi:10.1039/qr9571100121. Retrieved 15 July 2020.
  29. ^ Murrell, J. N.; Kettle, S. F. A.; Tedder, J. M. (1965). Valence theory. John Wiley and Sons. p. 243.
  30. ^ Lipscomb, William N. (11 December 1976). "The Boranes and their relatives (Nobel lecture)" (PDF). nobelprize.org. Nobel Foundation. pp. 224–245. Retrieved 16 July 2020. One of the simple consequences of these studies was that electron deficient molecules, defined as having more valence orbitals than electrons, are not really electron deficient.
  31. ^ Housecroft, Catherine E.; Sharpe, Alan G. (2005). Inorganic Chemistry (2nd ed.). Pearson Prentice-Hall. p. 326. ISBN 0130-39913-2. An electron-deficient species possesses fewer valence electrons than are required for a localized bonding scheme.
  32. ^ Bilstein, Roger. "Stages to Saturn". chapter 5: NASA Public Affairs Office. p. 133. Retrieved 14 November 2015.{{cite web}}: CS1 maint: location (link)
  33. ^ Gammon, Benson E.; Genco, Russell S.; Gerstein, Melvin (1950). A preliminary experimental and analytical evaluation of diborane as a ram-jet fuel (PDF). National Advisory Committee for Aeronautics.
  34. ^ Tower, Leonard K.; Breitwieser, Roland; Gammon, Benson E. (1958). Theoretical Combustion Performance of Several High-Energy Fuels for Ramjet Engines (PDF). National Advisory Committee for Aeronautics.
  35. ^ "LIQUID HYDROGEN AS A PROPULSION FUEL, 1945–1959. Part II: 1950–1957. Chapter 5. NACA Research on High-Energy Propellants". history.nasa.gov.
  36. ^ Brotherton, Robert J.; Weber, C. Joseph; Guibert, Clarence R.; Little, John L. (2000). Ullmann's Encyclopedia of Industrial Chemistry. Weinheim: Wiley-VCH. doi:10.1002/14356007.a04_309.
  37. ^ Mehta, Bhavesh; Tao, Meng (2005). "A Kinetic Model for Boron and Phosphorus Doping in Silicon Epitaxy by CVD". Journal of the Electrochemical Society. 152 (4): G309. Bibcode:2005JElS..152G.309M. doi:10.1149/1.1864452.
  38. ^ Nomiyama, Tetsuo; Omae, Kazuyuki; Ishizuka, Chizuru; Hosoda, Kanae; Yamano, Yuko; Nakashima, Hiroshi; Uemura, Takamoto; Sakurai, Haruhiko (1996). "Evaluation of the Subacute Pulmonary and Testicular Inhalation Toxicity of Diborane in Rats". Toxicology and Applied Pharmacology. 138 (1): 77–83. doi:10.1006/taap.1996.0100. PMID 8658516.

Cited sources

  • Haynes, William M., ed. (2011). CRC Handbook of Chemistry and Physics (92nd ed.). CRC Press. ISBN 978-1439855119.
  • Yerazunis, S., et al. “Solubility of Diborane in the Dimethyl Ether and Diethylene Glycol, in Mixtures of Sodium Borohydride and Dimethyl Ether of Diethylene Glycol, and in Ditertiary Butyl Sulfide.” Journal of Chemical & Engineering Data, vol. 7, no. 3, July 1962, pp. 337–39, doi:10.1021/je60014a004.

External links

  • International Chemical Safety Card 0432
  • NIOSH Pocket Guide to Chemical Hazards
  • U.S. EPA Acute Exposure Guideline Levels

January 07, 2023
diborane, also, diborane, diborane, generally, known, diborane, chemical, compound, with, formula, b2h6, toxic, colorless, pyrophoric, with, repulsively, sweet, odor, boron, compound, with, variety, applications, attracted, wide, attention, electronic, structu. See also diborane 2 and diborane 4 Diborane 6 generally known as diborane is the chemical compound with the formula B2H6 It is a toxic colorless and pyrophoric gas with a repulsively sweet odor Diborane is a key boron compound with a variety of applications It has attracted wide attention for its electronic structure Several of its derivatives are useful reagents Diborane NamesIUPAC name Diborane 6 IdentifiersCAS Number 19287 45 7 Y3D model JSmol Interactive imageChEBI CHEBI 33590 YChemSpider 17215804 YECHA InfoCard 100 039 021EC Number 242 940 6PubChem CID 6328200 incorrect structureRTECS number HQ9275000UNII BS9K982N24UN number 1911CompTox Dashboard EPA DTXSID9024938InChI InChI 1S B2H6 c1 3 2 4 1 h1 2H2 YKey KLDBIFITUCWVCC UHFFFAOYSA N YInChI 1 B2H6 c1 3 2 4 1 h1 2H2Key KLDBIFITUCWVCC UHFFFAOYAFSMILES BH2 1 H BH2 H 1PropertiesChemical formula B 2H 6Molar mass 27 67 g mol 1Appearance Colorless gasOdor repulsive and sweetDensity 1 131 g L 1 Melting point 164 85 C 264 73 F 108 30 K 1 Boiling point 92 49 C 134 48 F 180 66 K 1 Solubility in water Reacts 2 Solubility in other solvents Diglyme and Diethyl Ether 3 Vapor pressure 39 5 atm 16 6 C 2 StructureCoordination geometry Tetrahedral for boron Molecular shape see textDipole moment 0 DThermochemistryHeat capacity C 56 7 J mol K 4 Std molarentropy S 298 232 1 J mol K 4 Std enthalpy offormation DfH 298 36 4 kJ mol 4 HazardsOccupational safety and health OHS OSH Main hazards toxic highly flammable reacts with waterGHS labelling PictogramsSignal word DangerHazard statements H220 H280 H314 H330 H370 H372Precautionary statements P210 P260 P264 P270 P271 P280 P284 P301 P330 P331 P303 P361 P353 P304 P340 P305 P351 P338 P307 P311 P310 P314 P320 P321 P363 P377 P381 P403 P403 P233 P405 P410 P403 P501NFPA 704 fire diamond 6 443WAutoignitiontemperature 38 C 100 F 311 K Explosive limits 0 8 88 2 Lethal dose or concentration LD LC LC50 median concentration 40 ppm rat 4 h 29 ppm mouse 4 h 40 80 ppm rat 4 h 159 181 ppm rat 15 min 5 LCLo lowest published 125 ppm dog 2 h 50 ppm hamster 8 h 5 NIOSH US health exposure limits PEL Permissible TWA 0 1 ppm 0 1 mg m3 2 REL Recommended TWA 0 1 ppm 0 1 mg m3 2 IDLH Immediate danger 15 ppm 2 Related compoundsRelated boron compounds DecaboraneBF3Except where otherwise noted data are given for materials in their standard state at 25 C 77 F 100 kPa Y verify what is Y N Infobox references Contents 1 Structure and bonding 2 Production and synthesis 3 Reactions 3 1 Air water oxygen 3 2 Lewis acidity 3 3 Hydroboration 3 4 Other 4 Reagent in organic synthesis 5 History 6 Other uses 7 Safety 8 References 9 Cited sources 10 External linksStructure and bonding Edit Bonding diagram of diborane B2H6 showing with curved lines a pair of three center two electron bonds each of which consists of a pair of electrons bonding three atoms two boron atoms and a hydrogen atom in the middle The structure of diborane has D2h symmetry Four hydrides are terminal while two bridge between the boron centers The lengths of the B Hbridge bonds and the B Hterminal bonds are 1 33 and 1 19 A respectively This difference in bond lengths reflects the difference in their strengths the B Hbridge bonds being relatively weaker The weakness of the B Hbridge compared to B Hterminal bonds is indicated by their vibrational signatures in the infrared spectrum being 2100 and 2500 cm 1 respectively 7 The model determined by molecular orbital theory describes the bonds between boron and the terminal hydrogen atoms as conventional 2 center 2 electron covalent bonds The bonding between the boron atoms and the bridging hydrogen atoms is however different from that in molecules such as hydrocarbons Each boron uses two electrons in bonding to the terminal hydrogen atoms and has one valence electron remaining for additional bonding The bridging hydrogen atoms provide one electron each The B2H2 ring is held together by four electrons forming two 3 center 2 electron bonds This type of bond is sometimes called a banana bond B2H6 is isoelectronic with C2H62 which would arise from the diprotonation of the planar molecule ethylene 8 Diborane is one of many compounds with such unusual bonding 9 Of the other elements in group IIIA gallium is known to form a similar compound digallane Ga2H6 Aluminium forms a polymeric hydride AlH3 n although unstable Al2H6 has been isolated in solid hydrogen and is isostructural with diborane 10 Production and synthesis EditExtensive studies of diborane have led to the development of multiple synthesis routes Most preparations entail reactions of hydride donors with boron halides or alkoxides The industrial synthesis of diborane involves the reduction of BF3 by sodium hydride NaH lithium hydride LiH or lithium aluminium hydride LiAlH4 11 8 BF3 6 LiH B2H6 6 LiBF4Two laboratory methods start from boron trichloride with lithium aluminium hydride or from boron trifluoride ether solution with sodium borohydride Both methods result in as much as 30 yield 4 BCl3 3 LiAlH4 2 B2H6 3 LiAlCl4 4 BF3 3 NaBH4 2 B2H6 3 NaBF4Older methods entail the direct reaction of borohydride salts with a non oxidizing acid such as phosphoric acid or dilute sulfuric acid 2 BH4 2 H 2 H2 B2H6Similarly oxidation of borohydride salts has been demonstrated and remains convenient for small scale preparations For example using iodine as an oxidizer 2 NaBH4 I2 2 NaI B2 H6 H2Another small scale synthesis uses potassium hydroborate and phosphoric acid as starting materials 12 Reactions Edit Borane dimethylsulfide generally functions equivalently to diborane and is easier to use 13 Diborane is a highly reactive and versatile reagent 14 Air water oxygen Edit As a pyrophoric substance diborane reacts exothermically with oxygen to form boron trioxide and water 2 B2H6 6 O2 2 B2O3 6 H2O DHr 2035 kJ mol 73 47 kJ g Diborane reacts violently with water to form hydrogen and boric acid B2H6 6 H2O 2 B OH 3 6 H2 DHr 466 kJ mol 16 82 kJ g Diborane also reacts with alcohols similarly Methanol for example give hydrogen and trimethylborate 15 B2H6 6 MeOH 2 B OMe 3 6 H2Lewis acidity Edit One dominating reaction pattern involves formation of adducts with Lewis bases Often such initial adducts proceed rapidly to give other products For example borane tetrahydrofuran which often behaves as an equivalently to diborane degrades to borate esters Its adduct with dimethyl sulfide is an important reagent in organic synthesis With ammonia diborane forms the diammoniate of diborane DADB with small quantities of ammonia borane as byproduct The ratio depends on the conditions Hydroboration Edit In the hydroboration reaction diborane also reacts readily with alkenes to form trialkylboranes This reaction pattern is rather general and the resulting alkyl borates can be readily derivatized e g to alcohols Although early work on hydroboration relied on diborane it has been replaced by borane dimethylsulfide which is more safely handled Other Edit Pyrolysis of diborane gives hydrogen and diverse boron hydride clusters For example pentaborane was first prepared by pyrolysis of diborane at about 200 C 16 17 Although this pyrolysis route is rarely employed it ushered in a large research theme of borane cluster chemistry Treating diborane with sodium amalgam gives NaBH4 and Na B3H8 15 When diborane is treated with lithium hydride in diethyl ether lithium borohydride is formed 15 B2H6 2 LiH 2 LiBH4Diborane reacts with anhydrous hydrogen chloride or hydrogen bromide gas to give a boron halohydride 15 B2H6 HX B2H5X H2 X Cl Br Treating diborane with carbon monoxide at 470 K and 20 bar gives H3BCO 15 Reagent in organic synthesis EditDiborane and its variants are central organic synthesis reagents for hydroboration Alkenes add across the B H bonds to give trialkylboranes which can be further elaborated 18 Diborane is used as a reducing agent roughly complementary to the reactivity of lithium aluminium hydride The compound readily reduces carboxylic acids to the corresponding alcohols whereas ketones react only sluggishly History EditDiborane was first synthesised in the 19th century by hydrolysis of metal borides but it was never analysed From 1912 to 1936 Alfred Stock the major pioneer in the chemistry of boron hydrides undertook his research that led to the methods for the synthesis and handling of the highly reactive volatile and often toxic boron hydrides He proposed the first ethane like structure of diborane 19 Electron diffraction measurements by S H Bauer initially appeared to support his proposed structure 20 21 Because of a personal communication with L Pauling who supported the ethane like structure H I Schlessinger and A B Burg did not specifically discuss 3 center 2 electron bonding in their then classic review in the early 1940s 22 The review does however discuss the bridged D2h structure in some depth It is to be recognized that this formulation easily accounts for many of the chemical properties of diborane In 1943 H Christopher Longuet Higgins while still an undergraduate at Oxford was the first to explain the structure and bonding of the boron hydrides The article reporting the work written with his tutor R P Bell 23 also reviews the history of the subject beginning with the work of Dilthey 24 Shortly afterwards the theoretical work of Longuet Higgins was confirmed in an infrared study of diborane by Price 25 The structure was re confirmed by electron diffraction measurement in 1951 by K Hedberg and V Schomaker with the confirmation of the structure shown in the schemes on this page 26 William Nunn Lipscomb Jr further confirmed the molecular structure of boranes using X ray crystallography in the 1950s and developed theories to explain their bonding Later he applied the same methods to related problems including the structure of carboranes on which he directed the research of future 1981 Nobel Prize winner Roald Hoffmann The 1976 Nobel Prize in Chemistry was awarded to Lipscomb for his studies on the structure of boranes illuminating problems of chemical bonding 27 Traditionally diborane has often been described as electron deficient because the 12 valence electrons can only form 6 conventional 2 centre 2 electron bonds which are insufficient to join all 8 atoms 28 29 However the more correct description using 3 centre bonds shows that diborane is really electron precise since there are just enough valence electrons to fill the 6 bonding molecular orbitals 30 Nevertheless some leading textbooks still use the term electron deficient 31 Other uses EditBecause of the exothermicity of its reaction with oxygen diborane has been tested as a rocket propellant 32 Complete combustion is strongly exothermic However combustion is not complete in the rocket engine as some boron monoxide B2O is produced This conversion mirrors the incomplete combustion of hydrocarbons to produce carbon monoxide CO Diborane also proved difficult to handle 33 34 35 Diborane has been investigated as a precursor to metal boride films 36 and for the p doping of silicon semiconductors 37 Safety EditDiborane is a pyrophoric gas Commercially available adducts are typically used instead at least for applications in organic chemistry These adducts include borane tetrahydrofuran borane THF and borane dimethylsulfide 14 The toxic effects of diborane are mitigated because the compound is so unstable in air The toxicity toward laboratory rats has been investigated 38 References Edit a b c Haynes p 4 52 a b c d e f NIOSH Pocket Guide to Chemical Hazards 0183 National Institute for Occupational Safety and Health NIOSH Yerazunis S et al Solubility of Diborane in the Dimethyl Ether and Diethylene Glycol in Mixtures of Sodium Borohydride and Dimethyl Ether of Diethylene Glycol and in Ditertiary Butyl Sulfide Journal of Chemical amp Engineering Data vol 7 no 3 July 1962 pp 337 39 doi 10 1021 je60014a004 a b c Haynes p 5 6 a b Diborane Immediately Dangerous to Life or Health Concentrations IDLH National Institute for Occupational Safety and Health NIOSH DIBORANE CAMEO Chemicals Chemical Datasheet Database of Hazardous Materials NOAA Retrieved 2022 10 26 Cooper C B III Shriver D F Onaka S 1978 Ch 17 Vibrational spectroscopy of hydride bridged transition metal compounds Transition Metal Hydrides Advances in Chemistry Vol 167 pp 232 247 doi 10 1021 ba 1978 0167 ch017 ISBN 9780841203907 a href Template Cite book html title Template Cite book cite book a CS1 maint multiple names authors list link Rasul G Prakash G K S Olah G A 2005 Comparative ab initio Study of the Structures and Stabilities of the Ethane Dication C2H62 and Its Silicon Analogues Si2H62 and CSiH62 Journal of Physical Chemistry A 109 5 798 801 Bibcode 2005JPCA 109 798R doi 10 1021 jp0404652 PMID 16838949 Laszlo P 2000 A Diborane Story Angewandte Chemie International Edition 39 12 2071 2072 doi 10 1002 1521 3773 20000616 39 12 lt 2071 AID ANIE2071 gt 3 0 CO 2 C PMID 10941018 Andrews L Wang X 2003 The Infrared Spectrum of Al2H6 in Solid Hydrogen Science 299 5615 2049 2052 Bibcode 2003Sci 299 2049A doi 10 1126 science 1082456 PMID 12663923 S2CID 45856199 Brauer Georg 1963 Handbook of Preparative Inorganic Chemistry Vol 1 2nd ed New York Academic Press p 773 ISBN 978 0121266011 Norman A D Jolly W L Saturnino D Shore S G 1968 Diborane Inorganic Syntheses Vol 11 pp 15 19 doi 10 1002 9780470132425 ch4 ISBN 9780470132425 Hutchins Robert O Cistone Frank 1981 Utility and Applications of Borane Dimethylsulfide in Organic Synthesis A Review Organic Preparations and Procedures International 13 3 4 225 doi 10 1080 00304948109356130 a b Mikhailov B M 1962 The Chemistry of Diborane Russian Chemical Reviews 31 4 207 224 Bibcode 1962RuCRv 31 207M doi 10 1070 RC1962v031n04ABEH001281 S2CID 250909492 a b c d e Housecroft C E Sharpe A G 2008 Chapter 13 The Group 13 Elements Inorganic Chemistry 3rd ed Pearson p 336 ISBN 978 0 13 175553 6 Stock A 1933 The Hydrides of Boron and Silicon New York Cornell University Press ISBN 0 8014 0412 6 Miller V R Ryschkewitsch G E 1974 Pentaborane 9 B5H9 Inorganic Syntheses Vol 15 pp 118 122 doi 10 1002 9780470132463 ch26 ISBN 9780470132463 Lane Clinton F 1976 Reduction of organic compounds with diborane Chemical Reviews 76 6 773 799 doi 10 1021 cr60304a005 Stock A 1933 The Hydrides of Boron and Silicon New York Cornell University Press Bauer S H 1937 The Structure of Diborane Journal of the American Chemical Society 59 6 1096 1103 doi 10 1021 ja01285a041 Bauer S H 1942 Structures and Physical Properties of the Hydrides of Boron and of their Derivatives Chemical Reviews 31 1 43 75 doi 10 1021 cr60098a002 Schlesinger H I Burg A B 1942 Recent Developments in the Chemistry of the Boron Hydrides Chemical Reviews 31 1 1 41 doi 10 1021 cr60098a001 Longuet Higgins H C Bell R P 1943 64 The Structure of the Boron Hydrides Journal of the Chemical Society Resumed 1943 250 255 doi 10 1039 JR9430000250 Dilthey W 1921 Uber die Konstitution des Wassers Angewandte Chemie 34 95 596 doi 10 1002 ange 19210349509 Price W C 1948 The absorption spectrum of diborane J Chem Phys 16 9 894 Bibcode 1948JChPh 16 894P doi 10 1063 1 1747028 Hedberg K Schomaker V 1951 A Reinvestigation of the Structures of Diborane and Ethane by Electron Diffraction Journal of the American Chemical Society 73 4 1482 1487 doi 10 1021 ja01148a022 The Nobel Prize in Chemistry 1976 Nobelprize org Retrieved 2012 02 01 Longuet Higgins H C 1957 The structures of electron deficient molecules Quarterly Reviews Chemical Society 11 2 121 133 doi 10 1039 qr9571100121 Retrieved 15 July 2020 Murrell J N Kettle S F A Tedder J M 1965 Valence theory John Wiley and Sons p 243 Lipscomb William N 11 December 1976 The Boranes and their relatives Nobel lecture PDF nobelprize org Nobel Foundation pp 224 245 Retrieved 16 July 2020 One of the simple consequences of these studies was that electron deficient molecules defined as having more valence orbitals than electrons are not really electron deficient Housecroft Catherine E Sharpe Alan G 2005 Inorganic Chemistry 2nd ed Pearson Prentice Hall p 326 ISBN 0130 39913 2 An electron deficient species possesses fewer valence electrons than are required for a localized bonding scheme Bilstein Roger Stages to Saturn chapter 5 NASA Public Affairs Office p 133 Retrieved 14 November 2015 a href Template Cite web html title Template Cite web cite web a CS1 maint location link Gammon Benson E Genco Russell S Gerstein Melvin 1950 A preliminary experimental and analytical evaluation of diborane as a ram jet fuel PDF National Advisory Committee for Aeronautics Tower Leonard K Breitwieser Roland Gammon Benson E 1958 Theoretical Combustion Performance of Several High Energy Fuels for Ramjet Engines PDF National Advisory Committee for Aeronautics LIQUID HYDROGEN AS A PROPULSION FUEL 1945 1959 Part II 1950 1957 Chapter 5 NACA Research on High Energy Propellants history nasa gov Brotherton Robert J Weber C Joseph Guibert Clarence R Little John L 2000 Ullmann s Encyclopedia of Industrial Chemistry Weinheim Wiley VCH doi 10 1002 14356007 a04 309 Mehta Bhavesh Tao Meng 2005 A Kinetic Model for Boron and Phosphorus Doping in Silicon Epitaxy by CVD Journal of the Electrochemical Society 152 4 G309 Bibcode 2005JElS 152G 309M doi 10 1149 1 1864452 Nomiyama Tetsuo Omae Kazuyuki Ishizuka Chizuru Hosoda Kanae Yamano Yuko Nakashima Hiroshi Uemura Takamoto Sakurai Haruhiko 1996 Evaluation of the Subacute Pulmonary and Testicular Inhalation Toxicity of Diborane in Rats Toxicology and Applied Pharmacology 138 1 77 83 doi 10 1006 taap 1996 0100 PMID 8658516 Cited sources EditHaynes William M ed 2011 CRC Handbook of Chemistry and Physics 92nd ed CRC Press ISBN 978 1439855119 Yerazunis S et al Solubility of Diborane in the Dimethyl Ether and Diethylene Glycol in Mixtures of Sodium Borohydride and Dimethyl Ether of Diethylene Glycol and in Ditertiary Butyl Sulfide Journal of Chemical amp Engineering Data vol 7 no 3 July 1962 pp 337 39 doi 10 1021 je60014a004 External links EditInternational Chemical Safety Card 0432 National Pollutant Inventory Boron and compounds NIOSH Pocket Guide to Chemical Hazards U S EPA Acute Exposure Guideline Levels Retrieved from https en wikipedia org w index php title Diborane amp oldid 1130423010, wikipedia, wiki, book, books, library,

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