Covalent hydrides

print Print
Please select which sections you would like to print:
verifiedCite
While every effort has been made to follow citation style rules, there may be some discrepancies. Please refer to the appropriate style manual or other sources if you have any questions.
Select Citation Style
Share
Share to social media
URL
https://mainten.top/science/hydride
Feedback
Corrections? Updates? Omissions? Let us know if you have suggestions to improve this article (requires login).
Thank you for your feedback

Our editors will review what you’ve submitted and determine whether to revise the article.

Covalent hydrides are primarily compounds of hydrogen and nonmetals, in which the bonds are evidently electron pairs shared by atoms of comparable electronegativities. For example, most nonmetal hydrides are volatile compounds, held together in the condensed state by relatively weak van der Waals intermolecular interactions (see chemical bonding). Covalent hydrides are liquids or gases that have low melting and boiling points, except in those cases (such as water) where their properties are modified by hydrogen bonding. For example, although volatile, NH3, H2O, and HF are held together in the liquid state primarily by hydrogen bonding.

Covalent hydrides can be formed from boron (B), aluminum (Al), and gallium (Ga) of group 13 in the periodic table. Boron forms an extensive series of hydrides. The neutral hydrogen compounds of aluminum and gallium are elusive species, although AlH3 and Ga2H6 have been detected and characterized to some degree. Ionic hydrogen species of both boron (BH4) and aluminum (AlH4) are extensively used as hydride sources.

As the periodic table is traversed from group 13 to group 17, the hydrogen compounds of the nonmetals become more acidic and less hydridic in nature. That is to say, they become increasingly less capable of donating H and more likely to donate H+. In group 14, carbon forms the most extensive class of hydrogen compounds of any element in the periodic table. All the other group-14 elements form hydrides that are neither good H+ nor good H donors. This is also true for the hydrides of group 15. In group 16 all the elements form dihydrides. The hydrogen compounds formed with the elements that follow oxygen—H2S, H2Se, and H2Te—are all volatile, toxic gases with repulsive odours. They are easily prepared by adding dilute acid to the corresponding metal sulfide, selenide, and telluride. All these dihydrides of group 16 act as weak acids in water, with the acidity increasing upon going down the family. The ability of the hydride to donate a hydrogen ion can be directly correlated with the decreasing bond strength of the element-hydrogen bond. That is, as the bond strength decreases down the family, the acidity increases. For the same reason, the general chemical reactivity of nonmetal hydrides also increases with increasing atomic number of the nonmetal.

Each of the halogens forms a binary compound with hydrogen, HX. At ambient temperature and pressure, these compounds are gases, with hydrogen fluoride having the highest boiling point owing to intermolecular hydrogen bonding. As is found in group 16, the hydrogen halides are proton donors in aqueous solution. However, these compounds are, as a class, much stronger acids. The acid strength of the HX compounds increases down the group, with HF being a very weak acid and HI being the strongest proton donor. With the exception of HF, all the hydrogen halides dissolve in water to form strong acids. The difference in the proton-donating ability of HF and the other HX compounds is due to a variety of factors, among them being the strong bond that forms between hydrogen and fluorine.

Two group-13 hydridic anions are well-known reducing agents. The tetrahydridoborate (commonly called the borohydride) anion, BH4, the tetrahydridoaluminate anion, AlH4, and their derivatives are some of the most widely used reducing agents in chemistry. The cations most commonly employed are Na+ for BH4 (to form NaBH4) and Li+ for AlH4 (LiAlH4). Both compounds have specific uses in both organic and inorganic reduction reactions. Lithium gallium hydride, LiGaH4, can also be used as a reducing agent. When pure, all these compounds are white crystalline solids, and their thermal and chemical stabilities are such that those of the boron compounds are greater than those of the aluminum compounds, which are in turn greater than those of the gallium compounds.

Steven S. Zumdahl