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Silane
IUPAC name	Silane
Other names	Silicon tetrahydride Silicon hydride Monosilane Silicane
Identifiers
CAS number	7803-62-5 Y
UN number	2203
RTECS number	VV1400000
Properties
Molecular formula	SiH4
Molar mass	32.12 g/mol
Appearance	Colorless gas
Density	0.7 g/ml (liquid) 1.342 kg/m3 (gas)
Melting point	88 K (−185 °C)
Boiling point	161 K (−112 °C)
Solubility in water	Insoluble, slow hydrolysis
Structure
Molecular shape	tetrahedral
Dipole moment	0 D
Thermochemistry
Std enthalpy of formation ΔfHo298	34.31kJ/mol
Standard molar entropy So298	283 J mol−1 K−1
Hazards
MSDS	ICSC 0564
EU Index	Not listed
Main hazards	Extremely flammable, potentially pyrophoric
NFPA 704	4 2 3
Flash point	flammable gas
Autoignition temperature	294 K (21 °C) (~70°F)
Explosive limits	1.37–100%
U.S. Permissible exposure limit (PEL)	5 ppm (ACGIH TLV)
Related compounds
Related hydrides	Methane Germane Stannane Plumbane
Related compounds	Disilane
Y (what is this?)  (verify) Except where noted otherwise, data are given for materials in their standard state (at 25 °C, 100 kPa)
Infobox references

Silane is a chemical compound with chemical formula SiH₄. 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.^[1] However, the difficulties in explaining the available (often contradictory) combustion data are ascribed to the fact that silane itself is stable and that the natural formation of larger silanes during production, as well as the sensitivity of combustion to impurities such as moisture and to the catalytic effects of container surfaces causes its pyrophoricity.^[2][3] Above 420°C, silane decomposes into silicon and hydrogen; it can therefore be used in the chemical vapor deposition of silicon.

Contents 1 Nomenclature 2 Production 3 Properties 4 Applications 5 Safety and precautions 6 See also 7 References

[edit] Nomenclature

More generally, silanes are any silicon analogues of an alkane hydrocarbon. Silanes consist of a chain of silicon atoms covalently bonded to each other and 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 thermodynamically more favoured than the silicon-silicon bond.

There exists a regular nomenclature for silanes. Each silane's name is the word silane preceded by a numerical prefix (mono, 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 called either monosilane or 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.

[edit] Production

Industrially, silane is produced from metallurgical grade silicon in a two-step process. In the first step, powdered silicon is reacted with hydrogen chloride 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.

For classroom demonstrations, silane can be produced (temporarily) by heating sand with magnesium powder, then pouring the mixture into a 20% dilution of hydrochloric acid. The magnesium silicide reacts with the acid to produce silane gas, which combusts on contact with air and produces tiny explosions. ^[4]

[edit] Properties

Silane has a repulsive smell.^[5]

Silane has recently been shown to act as superconductor under extremely high pressures (96 and 120 GPa), with a transition temperature of 17 K.^[6] Confusingly, there was briefly an EE Times article that grossly exaggerated this achievement and claimed that room-temperature superconductivity had been achieved.

[edit] Applications

Several industrial and medical applications exist for silane and functionalized 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,^[7] applying polycrystalline silicon layers on silicon wafers when manufacturing semiconductors, and sealants. The semiconductor industry alone used about 300 metric tons per year of silane in the late 1990s.^[3] More recently, a growth in low-cost solar panel manufacturing has led to substantial consumption of silane for depositing amorphous silicon on glass and other surfaces.

Silane is also used in supersonic combustion ramjets to initiate combustion in the compressed air stream. As it can burn using carbon dioxide as an oxidizer it is a candidate fuel for engines operating on Mars.^[8] Since this reaction has some byproducts which are solid (silicon dioxide and carbon) it is applicable only to Liquid-fuel rockets (with liquid carbon dioxide) ramjets, or other external combustion engines .

Silane and similar compounds containing Si-H-bonds are used as reducing agents in organic and organometallic chemistry.^[9]

"Magic sand" exposes regular sand to trimethylhydroxysilane vapors to make the sand waterproof.

[edit] Safety and precautions

A number of fatal industrial accidents produced by detonation and combustion of leaked silane in air have been reported.^[10][11][12] Diluted silane mixtures with inert gases such as nitrogen or argon are even more likely to ignite when leaked into open air, compared to pure silane: even a 1% mixture of silane in pure nitrogen easily ignites when exposed to air.^[13] Unlike methane, silane is also fairly toxic: the lethal concentration in air for rats (LC₅₀) is 0.96% (9,600ppm) over a 4-hour exposure. In addition, contact with eyes may form silicic acid with resultant irritation.^[14]

[edit] See also

• silanization

[edit] References

1. ^ Emeléus, H. J. and Stewart, K. (1935). "The oxidation of the silicon hydrides". Journal of the Chemical Society: 1182 - 1189. doi:10.1039/JR9350001182. 
2. ^ Koda, S. (1992). "Kinetic Aspects of Oxidation and Combustion of Silane and Related Compounds". Progress in Energy and Combustion Science 18 (6): 513-528. doi:10.1016/0360-1285(92)90037-2. 
3. ^ ^{a b} Timms, P. L. (1999). "The chemistry of volatile waste from silicon wafer processing". Journal of the Chemical Society - Dalton Transactions (6): 815-822. doi:10.1039/a806743k. 
4. ^ Making Silicon from Sand, by Theodore Gray. Originally published in Popular Science magazine.
5. ^ CFC Startec properties of Silane
6. ^ M. I. Eremets, I. A. Trojan, S. A. Medvedev, J. S. Tse, Y. Yao (2008). "Superconductivity in Hydrogen Dominant Materials: Silane". Science 319 (5869): 1506–1509. doi:10.1126/science.1153282. PMID 18339933. 
7. ^ Graffiti protection systems
8. ^ Zubrin, Robert (1996). The Case for Mars. NY: Touchstone. p. 203. ISBN 0-684-83550-9. 
9. ^ Reductions of organic compounds using silanes
10. ^ Chen, J. R. (2002). "Characteristics of fire and explosion in semiconductor fabrication processes". Process Safety Progress 21 (1): 19-25. doi:10.1002/prs.680210106. 
11. ^ Chen, J. R.; Tsai, H. Y.; Chen, S. K.; Pan, H. R.; Hu, S. C.; Shen, C. C.; Kuan, C. M.; Lee, Y. C.; and Wu, C. C. (2006). "Analysis of a silane explosion in a photovoltaic fabrication plant". Process Safety Progress 25 (3): 237-244. doi:10.1002/prs.10136. 
12. ^ Chang, Y. Y.; Peng, D. J.; Wu, H. C.; Tsaur, C. C.; Shen, C. C.; Tsai, H. Y.; and Chen, J. R. (2007). "Revisiting of a silane explosion in a photovoltaic fabrication plant". Process Safety Progress 26 (2): 155-158. doi:10.1002/prs.10194. 
13. ^ Kondo, S.; Tokuhashi, K.; Nagai, H.; Iwasaka, M.; and Kaise, M. (1995). "Spontaneous Ignition Limits of Silane and Phosphine". Combustion and Flame 101 (1-2): 170-174. doi:10.1016/0010-2180(94)00175-R. 
14. ^ See MSDS for silane.