A polyhydride or superhydride is a compound that contains an abnormally large amount of hydrogen. This can be described as high hydrogen

stoichiometry Stoichiometry refers to the relationship between the quantities of reactants and products before, during, and following chemical reactions. Stoichiometry is founded on the law of conservation of mass where the total mass of the reactants equal ...

. Examples include

iron pentahydride Iron pentahydride FeH5 is a superhydride compound of iron and hydrogen, stable under high pressures. It is important because it contains atomic hydrogen atoms that are not bonded into smaller molecular clusters, and may be a superconductor. Pairs ...

FeH₅, LiH₆, and LiH₇. By contrast, the more well known lithium hydride only has one hydrogen atom. Polyhydrides are only known to be stable under high pressure. Polyhydrides are important because they can form substances with a very high density of hydrogen. They may resemble the elusive metallic hydrogen, but can be made under lower pressures. One possibility is that they could be superconductors.

Hydrogen sulfide Hydrogen sulfide is a chemical compound with the formula . It is a colorless chalcogen-hydride gas, and is poisonous, corrosive, and flammable, with trace amounts in ambient atmosphere having a characteristic foul odor of rotten eggs. The unde ...

under high pressures forms SH₃ units, and can be a superconductor at and a pressure of 1.5 million

atmospheres The standard atmosphere (symbol: atm) is a unit of pressure defined as Pa. It is sometimes used as a ''reference pressure'' or ''standard pressure''. It is approximately equal to Earth's average atmospheric pressure at sea level. History The s ...

Structures

The polyhydrides of alkaline earth and

alkali metal The alkali metals consist of the chemical elements lithium (Li), sodium (Na), potassium (K),The symbols Na and K for sodium and potassium are derived from their Latin names, ''natrium'' and ''kalium''; these are still the origins of the names ...

s contain cage structures. Also hydrogen may be clustered into H⁻, H₃⁻, or H₂ units. Polyhydrides of transition metals may have the hydrogen atoms arranged around the metal atom. Computations suggest that increasing hydrogen levels will reduce the dimensionality of the metal arrangement, so that layers form separated by hydrogen sheets. The H₃⁻ substructure is linear. H₃⁺ would form triangular structures in the hypothetical H₅Cl.

Compounds

When sodium hydride is compressed with hydrogen, NaH₃ and NaH₇ form. These are formed at 30 GPa and 2,100 K. Heating and compressing a metal with

ammonia borane Ammonia borane (also systematically named amminetrihydridoboron), also called borazane, is the chemical compound with the formula H3NBH3. The colourless or white solid is the simplest molecular boron-nitrogen-hydride compound. It has attracted att ...

avoids using bulky hydrogen, and produces boron nitride as a decomposition product in addition to the polyhydride.

Predicted

Using

computational chemistry Computational chemistry is a branch of chemistry that uses computer simulation to assist in solving chemical problems. It uses methods of theoretical chemistry, incorporated into computer programs, to calculate the structures and properties of m ...

many other polyhydrides are predicted, including LiH₈, LiH₉, LiH₁₀, CsH₃, KH₅ RbH₅, RbH₉, NaH₉, BaH₆, CaH⁶, MgH₄, MgH₁₂, MgH₁₆, SrH₄, SrH₁₀, SrH₁₂, ScH₄, ScH₆, ScH₈, YH₄ and YH₆, YH₂₄, LaH₈, LaH₁₀, YH₉, LaH₁₁, CeH₈, CeH₉, CeH₁₀, PrH₈, PrH₉, ThH₆, ThH₇ and ThH₁₀, U₂H₁₃, UH₇, UH₈, UH₉, AlH₅, GaH₅, InH₅, SnH₈, SnH₁₂, SnH₁₄, PbH₈, SiH₈ (subsequently discovered), GeH₈, (although Ge₃H₁₁ may be stable instead) AsH₈, SbH₄, BiH₄, BiH₅, BiH₆, H₃Se, H₃S, Te₂H₅, TeH₄, PoH₄, PoH₆, H₂F, H₃F, H₂Cl, H₃Cl, H₅Cl, H₇Cl, H₂Br, H₃Br, H₄Br, H₅Br, H₅I, XeH₂, XeH₄,. Among the transition elements, VH₈ in a ''C''2/''m'' structure around 200 GPa is predicted to have a superconducting transition temperature of 71.4 K. VH₅ in a ''P''6₃/''mmm'' space group has a lower transition temperature.

Properties

Superconduction

Under suitably high pressures polyhydrides may become superconducting. Characteristics of substances that are predicted to have high superconducting temperatures are a high phonon frequency, which will happen for light elements, and strong bonds. Hydrogen is the lightest and so will have the highest frequency of vibration. Even changing the isotope to deuterium will lower the frequency and lower the transition temperature. Compounds with more hydrogen will resemble the predicted metallic hydrogen. However, superconductors also tend to be substances with high symmetry and also need the electrons not to be locked into molecular subunits, and require large numbers of electrons in states near the

Fermi level The Fermi level of a solid-state body is the thermodynamic work required to add one electron to the body. It is a thermodynamic quantity usually denoted by ''µ'' or ''E''F for brevity. The Fermi level does not include the work required to remove ...

. There should also be electron-phonon coupling which happens when the electric properties are tied to the mechanical position of the hydrogen atoms. The highest superconduction critical temperatures are predicted to be in groups 3 and 3 of the periodic table. Late transitions elements, heavy lanthanides or actinides have extra d- or f-electrons that interfere with superconductivity. For example, lithium hexahydride is predicted to lose all electrical resistance below 38 K at a pressure of 150 GPa. The hypothetical LiH₈ has a predicted superconducting transition temperature at 31 K at 200 GPa. MgH₆ is predicted to have a T_c of 400 K around 300 GPa. CaH₆ could have a T_c of 260 K at 120 GPa. PH₃ doped H₃S is also predicted to have a transition temperature above the 203 K measured for H₃S (contaminated with solid sulfur). Rare earth and actinide polyhydrides may also have highish transition temperatures, for example, ThH₁₀ with T_c = 241 K. UH₈, which can be decompressed to room temperature without decomposition, is predicted to have a transition temperature of 193 K. AcH₁₀, if it could be ever made, is predicted to superconduct at temperatures over 204 K, and AcH₁₀ would be similarly conducting under lower pressures (150 GPa). H₃Se actually is a van der Waals solid with formula 2H₂Se•H₂ with a measured T_c of 105 K under a pressure of 135 GPa.

Ternary superhydrides

Ternary superhydrides open up the possibility of many more formulas. For example, Li₂MgH₁₆ may also be superconducting at high temperatures (200 °C). A compound of lanthanum, boron and hydrogen is speculated to be a "hot" superconductor (550K). Elements may substitute for others and so modify the properties eg (La,Y)H₆ and (La,Y)H₁₀ can be made to have a slightly higher critical temperature than YH₆ or LaH₁₀.

References

{{Reflist Hydrogen compounds High-temperature superconductors