Transition metal hydrides are chemical compounds containing a transition metal bonded to hydrogen. Most transition metals form hydride complexes and some are significant in various catalytic and synthetic reactions. The term "hydride" is used loosely: some of them are acidic (e.g., H₂Fe(CO)₄), whereas some others are hydridic, having H⁻-like character (e.g., ZnH₂).

Many transition metals form compounds with hydrogen. These materials are called binary hydrides, because they contain only two elements. The hydrogenic ligand is assumed to have hydridic (H⁻-like) character. These compounds are invariably insoluble in all solvents, reflecting their polymeric structures. They often exhibit metal-like electrical conductivity. Many are nonstoichiometric compounds. Electropositive metals (Ti, Zr, Hf, Zn) and some other metals form hydrides with the stoichiometry MH or sometimes MH₂ (M = Ti, Zr, Hf, V, Zn). The best studied are the binary hydrides of palladium, which readily forms a limiting monohydride. In fact, hydrogen gas diffuses through Pd windows via the intermediacy of PdH.

Ternary metal hydrides have the formula A_xMH_n, where A⁺ is an alkali or alkaline earth metal cation, e.g. K⁺ and Mg²⁺. A celebrated example is K₂ReH₉, a salt containing two K⁺ ions and the ReH₉²⁻ anion. Other homoleptic metal hydrides include the anions in Mg₂FeH₆ and Mg₂NiH₄. Some of these anionic polyhydrides satisfy the 18-electron rule, many do not. Because of their high lattice energy, these salts are typically not soluble in any solvents, a well known exception being K₂ReH₉.

The most prevalent hydrides of the transition metals are metal complexes that contain a mix of ligands in addition to hydride. The range of coligands is large. Virtually all of the metals form such derivatives. The main exceptions include the late metals silver, gold, cadmium, and mercury, which form few or unstable complexes with direct M-H bonds. Examples of an industrially useful hydrides are HCo(CO)₄ and HRh(CO)(PPh₃)₃, which are catalysts for hydroformylation.

The first molecular hydrides of the transition metals were first reported in the 1930s by Walter Hieber and coworkers. They described H₂Fe(CO)₄ and HCo(CO)₄. After a hiatus of several years, and following the release of German war documents on the postulated role of HCo(CO)₄ in hydroformylation, several new hydrides were reported in the mid-1950s by three prominent groups in organometallic chemistry: HRe(C₅H₅)₂ by Geoffrey Wilkinson, HMo(C₅H₅)(CO)₃ by E. O. Fischer, and HPtCl(PEt₃)₂ by Joseph Chatt. Thousands of such compounds are now known.

Like hydrido coordination complexes, many clusters feature terminal (bound by one M–H bond) hydride ligands. Hydride ligands can also bridge pairs of metals, as illustrated by [HW₂(CO)₁₀]⁻. The cluster H₂Os₃(CO)₁₀ features both terminal and doubly bridging hydride ligands. Hydrides can also span the triangular face of a cluster as in [Ag₃{(PPh₂)₂CH₂}₃(μ₃-H)(μ₃-Cl)]BF₄. In the cluster [Co₆H(CO)₁₅]⁻, the hydride is "interstitial", occupying a position at the center of the Co₆ octahedron. The assignment for cluster hydrides can be challenging as illustrated by studies on Stryker's reagent [Cu₆(PPh₃)₆H₆].

Nucleophilic main group hydrides convert many transition metal halides and cations into the corresponding hydrides:

These conversions are metathesis reactions, and the hydricity of the product is generally less than of the hydride donor. Classical (and relatively cheap) hydride donor reagents include sodium borohydride and lithium aluminium hydride. In the laboratory, more control is often offered by "mixed hydrides" such as lithium triethylborohydride and Red-Al. Alkali metal hydrides, e.g. sodium hydride, are not typically useful reagents.