Diborane

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Diborane[edit | edit source]

Diborane is a chemical compound with the formula B2H6. It is a colorless, highly flammable gas at room temperature with a distinctively sweet odor. Diborane belongs to the class of compounds known as boranes, which are compounds of boron and hydrogen. It is of significant interest in the field of chemistry due to its unique structure and bonding, which have implications for its reactivity and use in various chemical syntheses.

Structure and Properties[edit | edit source]

The structure of diborane is notable for its bridging hydrogen atoms. Two hydrogen atoms bridge the two boron atoms, forming a four-center two-electron bond, a concept that is fundamental in understanding the bonding in boranes. This structure is quite different from conventional covalent bonds, where two electrons are shared between two atoms. Diborane's molecular structure is a key example of three-center two-electron bonding.

Diborane is highly reactive, particularly towards water and oxygen. It hydrolyzes to produce boric acid and hydrogen gas:

\[ B_2H_6 + 6H_2O \rightarrow 2B(OH)_3 + 6H_2 \]

This reaction is exothermic and can be violently explosive under certain conditions.

Synthesis[edit | edit source]

Diborane can be synthesized through several methods, including the reduction of boron trifluoride (BF3) with lithium aluminum hydride (LiAlH4) or by the reaction of sodium borohydride (NaBH4) with an acid. Historically, it was also produced by the high-temperature reaction of boron oxides with hydrogen gas.

Uses[edit | edit source]

Diborane has been used as a rocket fuel due to its high energy content and as a reducing agent in organic synthesis. It is particularly useful in hydroboration reactions, where it adds across the double bond of alkenes to give trialkylboranes, which can be further processed to produce a variety of organic compounds. However, its use is limited by its toxicity and the difficulty in handling the gas safely.

Safety[edit | edit source]

Diborane is toxic and requires careful handling. Inhalation can lead to respiratory irritation and, in severe cases, pulmonary edema. It is also highly flammable and poses a significant fire and explosion hazard. Safety measures include the use of appropriate protective equipment and the storage of diborane in gas cylinders under an inert atmosphere.

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