SILANE

Silane
Silane Silane
General
Systematic name	Silane
Other names	Silicon tetrahydride Silicon hydride Monosilane Silicane
Molecular formula	SiH₄
Molar mass	32.12 g mol⁻¹
Appearance	Colourless gas
CAS number	[7803-62-5]
Properties
Density and phase	? kg m⁻³ (solid) 0.7 g/ml (liquid) 1.342 g L⁻¹ (gas)
Solubility in water	Insoluble
Melting point	88 K (−185°C)
Boiling point	161 K (−112°C)
Δ_f''H''⁰_solid	-1615 kJ mol⁻¹
''S''⁰_solid	283 J mol⁻¹ K⁻¹
Structure
Molecular shape	tetrahedral
Dipole moment	0 D
Hazards
MSDS	External MSDS
Main hazards	low toxicity, avoid exposure to skin, irritant, may cause redness and swelling
NFPA 704
Flash point	N/A
Autoignition temperature	294 K (21°C)
R/S statement	R: ? S: ?
UN number	2203
RTECS number	VV1400000
Supplementary data page
Structure and properties	''n'', ε_r, etc.
Thermodynamic data	Phase behaviour Solid, liquid, gas
Spectral data	UV, IR, NMR, MS
Related compounds
Related silanes	disilane trisilane tetrasilane cyclosilane
Related hydrides	methane
Related compounds	disilene
Except where noted otherwise, data are given for materials in their standard state (at 25°C, 100 kPa)

'Silane' is a chemical compound with chemical formula Si H₄. It is the silicon analogue of methane. At room temperature, silane is a gas, and is pyrophoric — it undergoes spontaneous combustion in air, without the need for external ignition. However, one school of thought holds that silane itself is stable and that the natural formation of larger silanes during production causes its pyrophoricity. Above 420°C, silane decomposes into silicon and hydrogen; it can therefore be used in the chemical vapor deposition of silicon.
More generally, a silane is any silicon analogue of an alkane hydrocarbon. Silanes consist of a chain of silicon atoms covalently bound to hydrogen atoms. The general formula of a silane is Si_nH_2n+2. Silanes tend to be less stable than their carbon analogues because the Si–Si bond has a strength slightly lower than the C–C bond. Oxygen decomposes silanes easily, because the silicon-oxygen bond is quite stable.
There exists a regular nomenclature for silanes. Each silane's name is the word silane preceded by a numerical prefix (di, tri, tetra, etc.) for the number of silicon atoms in the molecule. Thus Si₂H₆ is disilane, Si₃H₈ is trisilane, and so forth. There is no need for a prefix for one; SiH₄ is simply silane. Silanes can also be named like any other inorganic compound; in this naming system, silane is named silicon tetrahydride. However, with longer silanes, this becomes cumbersome.
A cyclosilane is a silane in a ring, just as a cycloalkane is an alkane in a ring.
Branched silanes are possible. The radical ·SiH₃ is termed silyl, ·Si₂H₅ is disilanyl, and so on. Trisilane with a silyl group attached to the middle silicon is named silyltrisilane. The nomenclature parallels that of alkyl radicals.
Silanes can also incorporate the same functional groups as alkanes, e.g. –OH to make a silanol. There is (at least in principle) a silicon analogue for all carbon alkanes.

Production

Applications

References

Production

Industrially, silane is produced from metallurgical grade silicon in a two-step process. In the first step, powdered silicon is reacted with hydrochloric acid at about 300 °C to produce trichlorosilane, HSiCl₃, along with hydrogen gas, according to the chemical equation:
:Si + 3HCl → HSiCl₃ + H₂
The trichlorosilane is then boiled on a resinous bed containing a catalyst which promotes its disproportionation to silane and silicon tetrachloride according to the chemical equation:
:4HSiCl₃ → SiH₄ + 3SiCl₄
The most commonly used catalysts for this process are metal halides, particularly aluminium chloride.

Applications

Several industrial and medical applications exist for silanes. For instance, silanes are used as coupling agents to adhere glass fibers to a polymer matrix, stabilizing the composite material. They can also be used to couple a bio-inert layer on a titanium implant. Other applications include water repellents, masonry protection, control of graffiti,^[1] applying polycrystalline silicon layers on silicon wafers when manufacturing semiconductors, and sealants.
Silane and similar compounds containing Si-H-bonds are used as reducing agents in organic and organometallic chemistry.^[2]

References

1. Graffiti protection systems
2. Reductions of organic compounds using silanes

External links

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