The common form of iron is the “α” form, with
body centred cubic (BCC) crystalline structure; in the absence of reactive chemicals, at ambient temperature and 13
GPa of pressure it converts to the “ε” form, with
hexagonal close packing (HCP) structure. In an atmosphere of hydrogen at ambient temperature, α-Fe retains its structure up to 3.5 GPa (35,000
atmospheres), with only small amounts of hydrogen diffusing into it forming a solid
interstitial solution. Starting at about 3.5 GPa of pressure, hydrogen rapidly
diffuses into metallic iron (with diffusion length of about 500
mm per 10 s at 5 GPa) to form a crystalline solid with formula close to FeH. This reaction, in which the iron expands significantly, was first inferred from the unexpected deformation of steel gaskets in
diamond anvil cell experiments. In 1991
J. V. Badding and others analysed a sample using
X-ray diffraction, as having an approximate composition FeH0.94 and
double hexagonal close packed (DHCP) structure. Since then, the pressure-temperature phase diagram of the iron-hydrogen system has been intensively investigated up to 70 GPa. Two additional stable crystalline forms have been observed, denoted “ε’” (the original DHCP form), “ε” (
hexagonal close packed, HPC). In these phases the packing of iron atoms is less dense than in pure iron. The HCP and FCC forms have the same iron lattice as in the pure iron forms, but have different number of hydrogen neighbors, and have different local magnetic moments. The hydrogen and iron atoms are electrically neutral for the bcc form. At low temperatures the stable forms are BCC below 5 GPa and ε’ (DHCP) above 5 GPa at least up to 80 GPa; at higher temperatures γ (FCC) exists at least up to 20 GPa. The triple point ε'-γ-melt is predicted to be at 60 GPa and 2000 K. Theoretical calculations however predict that, at 300 K, the stable structures should be DHCP below 37 GPa, HCP between 37–83 GPa, and FCC above 83 GPa. Other hydrogenated forms FeH
x with
x = 0.25 (),
x = 0.50 (), and
x = 0.75 () have been the subject of theoretical studies. These compounds dissociate spontaneously at ordinary pressures, but at very low temperatures they will survive long enough in a
metastable state to be studied. At ordinary temperatures, rapid depressurization of FeH from 7.5 GPa (at 1.5 GPa/s) results in metallic iron containing many small hydrogen bubbles; with slow depressurization the hydrogen diffuses out of the metal. High pressure stability of different iron hydrides was systematically studied using density-functional calculations and evolutionary crystal structure prediction by Bazhanova et al., who found that at pressures and temperatures of the Earth's inner core only FeH, and an unexpected compound are thermodynamically stable, whereas is not.
ε’ (DHCP) form The best-known high-pressure phase in the iron-hydrogen system (characterized by
V. E. Antonov and others, 1989) has a
double hexagonal close packed (DHCP) structure. It consists of layers of hexagonal packed iron atoms, offset in a pattern ABAC; which means that even-numbered layers are vertically aligned, while the odd-numbered ones alternate between the two possible relative alignments. The c axis of the
unit cell is 0.87
nm. Hydrogen atoms occupy
octahedral cavities between the layers. The hydrogen layers come in vertically aligned pairs, bracketing the B and C layers and shifted like them. For each hydrogen added the unit cell expands by 1.8
Å3 (0.0018 nm3). This phase was denoted ε’, after the similar structure that iron assumes above 14 GPa. This phase is rapidly created at room temperature and 3.8 GPa from hydrogen and α-iron. The transformation entails an expansion by 17–20% in volume. The reaction is complex and may involve a metastable HCP intermediate form; at 9 GPa and 350 °C there are still noticeable amounts of unreacted α-Fe in the solid. The same form is obtained from by reacting hydrogen with the higher-pressure HCP form of iron (ε-Fe) at 1073 K and 20 GPa for 20 min; and also from α-iron and at 84 GPa and 1300 K. This phase is stable at room temperature at least up to 80 GPa, but turns into the γ form between 1073 and 1173 K and 20 GPa. This material has metallic appearance and is an
electrical conductor. Its
resistivity is higher than that of iron, and decreases down to a minimum at 8 GPa. Above 13 GPa the resistivity increases with pressure. The material is
ferromagnetic at the lowest pressure range, but the ferromagnetism begins to decrease at 20 GPa and disappears at 32 GPa t. The bulk
elasticity modulus of this compound is 121 ± 19 GPa, substantially lower than iron's 160 GPa. This difference means that at 3.5 GPa FeH has 51% less volume than the mixture of hydrogen and iron that forms it. The speed of compressional sound waves in FeH rises as pressure rises, at 10 GPa it is at 6.3
km/
s, at 40 GPa 8.3 km/s and 70 GPa 9 km/s. The DHCP form of iron hydride can be preserved in a metastable form at ambient pressures by first lowering the temperature below 100 K.
ε (HCP) form A
hexagonal close packed (HCP) form of FeH also exists at lower pressure hydrogen, also described by M. Yamakata and others in 1992. This is called the ε phase (no prime). The hcp phase is not ferromagnetic, probably
paramagnetic. This appears to be the most stable form in a wide pressure range. It seems to have a composition between . The hcp form of FeH can be preserved in a metastable form at ambient pressures by first lowering the temperature below 100 K.
Melting point These high pressure iron-hydrogen alloys melt at a significantly lower temperature than pure iron: The slope of the melting point curve with pressure (dT/dP) is 13 K/GPa. ==Occurrence in the Earth’s core==