1. Introduction

Hydrogen can be incorporated into minerals in highly variable amounts. Once incorporated, the hydrogen is circulated throughout the Earth, from the surface to the deep interior, affecting the long-term evolution of the planet (Iizuka-Oku et al., 2017; Kawakatsu & Watada, 2007; Okuchi, 1997; Thompson, 1992). A major proportion of this hydrogen is currently stored within the crystal structures of dense minerals that are thermodynamically stable under the high pressures and temperatures of the deep mantle of the Earth (Ohtani, 2015; Purevjav et al., 2014, 2016, 2018; Sano-Furukawa et al., 2018). Dense hydrous magnesium silicates (DHMSs) are the most typical among such dense mineral species; they have very large hydrogen capacities even under extreme pressure and temperature conditions (Frost, 1999; Nishi et al., 2014; Ohtani et al., 2000). Phase E [Mg_3−0.5xSi_xH_6−3xO₆] has the largest hydrogen capacity (18% H₂O weight fraction of the total mass) and one of the best thermodynamic stabilities among DHMSs; it is stable to temperatures of at least 1573 K and pressures of 13–18 GPa (Kanzaki, 1991; Frost, 1999). Fig. 1(a) shows the thermogravimetry result of DHMS phase E synthesized under high-pressure and high-temperature conditions. Most of the hydrogen was retained inside the crystal structure up to 900 K under ambient pressure, which is distinctly higher than that typically seen for common hydrogen-bearing minerals of lower density. To understand the reason for such high-temperature stability of hydrogen in the mineral structure, which fundamentally controls the circulation of hydrogen within deep Earth, its chemical bonding geometry and cation-exchange mechanisms must be fully clarified.

Figure 1 (a) Thermogravimetry results of DHMS phase E [Mg3−0.5xSixH6−3xO6] and brucite [Mg(OH)2] measured at ambient pressure using Rigaku Thermo plus EV02. The former structure retains most of its hydrogen at around 900 K, while the latter retains it at around 600 K. We consider that the difference in dehydration temperatures between these minerals is related to the difference in their hydrogen bonding strengths. (b) Two equally plausible hydrogen site models that have been adopted so far for DHMS phase E (Tomioka et al., 2016). Each corner of the octahedra is made of an oxygen anion (not shown). In the normal O—D model, the dipole is parallel to the c axis and normal to the MgO6 octahedral layers. In the tilted O—D model, the dipole is tilted from the c axis. The crystallographic illustrations were created using the software VESTA3 (Momma & Izumi, 2011).

X-ray diffraction analysis has been used to examine the framework of DHMS phase E without hydrogen. It was revealed to have a layered structure belonging to a trigonal crystal system (space group ) (Kudoh et al., 1993). The structure consists of two different magnesium sites (Mg1 and Mg2), one silicon site (Si) and one oxygen site (O). Each Mg²⁺ ion is surrounded by six O²⁻ ions to form MgO₆ octahedra, and each Si⁴⁺ ion is connected to four O²⁻ ions to form SiO₄ tetrahedra. Most of the Mg²⁺ ions are located at the Mg1 sites, which collectively form a layer of edge-sharing MgO₆ octahedra. However, there was also a minor amount of Mg²⁺ occupying the Mg2 sites outside this layer. The SiO₄ tetrahedra are distributed statistically between two adjacent MgO₆ layers together with the possible hydrogen sites; however, hydrogen was not detectable using X-ray diffraction.

In order to locate the hydrogen sites, we previously analyzed the structure of deuterated DHMS phase E using powder neutron diffraction at J-PARC, Japan (Tomioka et al., 2016). Two equally plausible hydrogen site models (normal and tilted O—D dipole models) were derived [Fig. 1(b)]. The hydrogen concentrations determined based on the two models were very similar, derived from their refined site occupancies. Thus, we concluded that the hydrogen concentration within the mineral structure was reasonably constrained, where the refined site occupancies of hydrogen were compatible with the mineral stoichiometry. On the other hand, the powder data did not allow us to discriminate between the geometries of the hydrogen bonds among these models, owing to the insufficient spatial resolution. Thus, in this study, we employed time-of-flight (TOF) single-crystal neutron Laue diffraction for our synthesized high-quality DHMS phase E crystal. To determine the most accurate bonding distances of hydrogen, we synthesized a fully deuterated crystal. We expect that the heavier mass of deuterium relative to protium should reduce its vibration/displacement at its equivalent sites. In addition, the longer coherent scattering length of deuterium relative to protium should help to increase the signal-to-noise ratio, and its shorter incoherent scattering length should reduce background scattering. Hence, to obtain the best possible dataset given the very small crystal size, we used a fully deuterated sample to reduce the background and increase the signal-to-noise ratio. Therefore, the TOF Laue scheme will allow very high sensitivity for detecting weaker reflections at lower d-spacings from a small synthetic crystal. In our previous studies conducted using this combination, reflections with minimum d-spacings (d_min) as low as 0.3 Å were successfully resolved and analyzed (Purevjav et al., 2016, 2018), enabling quantitative determination of site positions and occupancies of deuterium in DHMS phase E.

2. Materials and methodology

3. Results and discussion

Table 1 shows the refined structural parameters at d_min = 0.50 Å. Fig. 2 shows the structure of the DHMS phase E. D⁺ is located between the MgO₆ octahedral layers [Fig. 2(a)]. The nuclear density of D in the difference Fourier map forms a triangular shape [Fig. 2(b)], indicating that there are three equivalent sites of D (Wyckoff site at 18h) around each oxygen anion. Therefore, the O—D covalent bond is not along the direction normal to the octahedral layers, but towards the three neighboring O²⁻ ions of the adjacent MgO₆ layer [Figs. 2(b) and 2(c)]. The tilted O—D dipole model is thus the suitable structural model. The O—D covalent bond distance is 0.817 (3) Å, which is identical to our previous powder diffraction results (Tomioka et al., 2016). The O⋯D hydrogen bond distance is 2.088 (3) Å. The bonding angle of O—D⋯O is 163.3 (3)°, indicating that near-straight hydrogen bonding occurs between D⁺ and one of the three nearest-neighbor O²⁻ ions.

Figure 2 Refined structure of DHMS phase E. (a) Framework structure along with tilted O—D dipoles. No cation was found at the Mg2 site. Vacancies of MgO6 octahedra (dashed area) are coupled with two adjacent SiO4 tetrahedra crosslinking the neighboring layers. The proposed locations of D+ are shown as red spheres. (b) Difference Fourier map projected from the c axis orientation. The locations of D+ were determined along with refininement of the site occupancy factor to the corresponding nuclear density distributions. There are three equivalent sites of D+ around each O2− ion. (c) Geometry of chemical bonding in the interlayer space O—D⋯O. Because of the site symmetry, three equivalent sites of D+ are observed simultaneously around each O2−, while one of them is actually filled by D+.

The structure of deuterated DHMS phase E at ambient pressure is close to that of deuterated brucite (magnesium deuteroxide) at high pressures (Okuchi et al., 2014; Parise et al., 1994). Both structures possess three-split D sites, clearly supporting the existence of interlayer hydrogen bonding in their structures (insets of Fig. 3). The interlayer distance between adjacent oxygen anions (O—D⋯O) in brucite is 3.22 Å at ambient pressure, which is too large for hydrogen bonding; on the other hand, the distance decreases to 2.88 Å at a pressure of 8.9 GPa, thereby enabling hydrogen bonding. In addition, the O—D⋯O angle of brucite is 148° at ambient pressure, which is too small for hydrogen bonding; however, this angle increases to 156° at 9.3 GPa, which again is consistent with the occurrence of hydrogen bonding. The c axis of brucite thus becomes distinctly less compressible at high pressures, indicating that its framework structure becomes harder with interlayer hydrogen bonding [Fig. 3(a)]. On the other hand, the distance of O—D⋯O in DHMS phase E is already 2.880 (1) Å at ambient pressure, which is suitable for hydrogen bonding of moderate strength. The O—D⋯O angle of 163° is also consistent with the occurrence of hydrogen bonding. Hence, hydrogen bonding occurs in DHMS phase E with a distance of 2.088 (3) Å at ambient pressure. It was previously reported that the c axis of DHMS phase E at ambient pressure is less compressible than that of brucite at high pressure, suggesting that interlayer hydrogen bonding already plays a role in hardening its framework structure [Fig. 3(b)]. Thus, we expect that interlayer hydrogen bonding in DHMS phase E becomes much stronger at high-pressure conditions inside deep Earth.

Figure 3 Compressibility along the c axis (c/c0) of brucite and DHMS phase E. (a) c/c0 of brucite reported by Nagai et al., 2000 (circles); Okuchi et al., 2014 (triangles); and Parise et al., 1994 (squares). The solid and broken lines are linear fits of these data points at lower and higher pressures, respectively. The inset numbers show the distance D⋯O across the interlayer space at room temperature, obtained from Okuchi et al. (2014), and Parise et al. (1994). The distance monotonically decreases with increasing pressure to form a hydrogen bonding interlayer, which makes the structure distinctly harder. The inset figures show the D sites of brucite at ambient and high pressures, respectively. (b) c/c0 of DHMS phase E reported by Shieh et al., 2000 (diamonds). The c axis of DHMS phase E around ambient pressure is already less compressible than that of brucite at high pressures. The inset number shows the distance D⋯O, determined in present study. The inset figure shows the D sites of DHMS phase E.

The presently determined O—D⋯O distance of DHMS phase E was more than 0.1 Å shorter than the value reported by Shieh et al. (2000), who suggested it exhibited weak hydrogen bonding. The reason for this difference is that Shieh et al. used the relation of the OH stretching frequencies versus O⋯O bond distances, where the relation had few data points, especially in the high-frequency range. Thus, such qualitative information is inaccurate for discussing the strength of hydrogen bonding in DHMS phase E.

Thermogravimetry analyses [Fig. 1(a)] demonstrated that the dehydration of DHMS phase E at ambient pressure occurs at a much higher temperature than that of brucite. At high pressure, the dehydration temperature of brucite increases, reaching 1550 K at 15 GPa (Johnson & Walker, 1993); this demonstrates the important role that hydrogen bonding plays in the stability of the structure against heat. Furthermore, the pressure-enhanced hydrogen bonding in DHMS phase E should act to increase the dehydration temperature. We conclude that strong hydrogen bonding is the most important factor for the high-temperature stability of DHMS phase E in deep Earth. Its high-temperature stability limit has not yet been accurately determined; nevertheless, it is stable to at least 1573 K at a pressure of 15 GPa (Frost, 1999). We expect that hydrogen bonding also plays a universal role in enhancing the stability of various hydrous minerals in deep Earth, and we will seek to verify this in our future research.

It has been reported that DHMS phase E incorporates a variable amount of hydrogen (Frost, 1999; Tomioka et al., 2016), thereby allowing flexible cation substitution, including hydrogen as one of the exchangeable species. We found a considerable number of Mg²⁺ vacancies at the Mg1 site, but no cations at the previously proposed Mg2 site. We found that the Si⁴⁺ and D⁺ sites were very close to each other. Furthermore, we considered the structural relation between brucite and DHMS phase E, as well as a full disordering of cations, as required by the crystallographic symmetry. It was concluded that multiple D⁺ ions in the interlayer space were simultaneously exchanged with the Si⁴⁺ ions that connect the neighboring layers, together with the generation of Mg²⁺ vacancies inside the MgO₆ octahedral layers. By comparing the refined chemical formula of the DHMS phase E crystal (Mg_2.28Si_1.32D_2.15O₆) with that of brucite (Mg₃Si₀D₆O₆), we found that the exchange mechanism of four possible models have the DHMS phase E structure from brucite, while maintaining the cation charge balances. We calculated the balances in occupancies of Mg and D for these models and compared them with those of our refinement result (see Fig. S3). We found that most plausible model is

i.e. one Mg²⁺ in the MgO₆ octahedral layer and six D⁺ in the interlayer space are exchanged with two Si⁴⁺ at the top and bottom of the Mg²⁺ vacancy [Fig. 2(a)]. The cation-to-cation distance is too short for the SiO₄ tetrahedron and MgO₆ octahedron to share faces; consequently, Mg²⁺ must be removed to introduce two SiO₄ tetrahedra which share their faces with the same Mg1 site. These SiO₄ tetrahedra have a deformed geometry, with an Si—O distance of 1.666 (3) Å along the c axis and 1.8322 (9) Å along the other directions. The O²⁻ bonded to Si⁴⁺ with a shorter distance along the c axis does not possess a D⁺ ion, thereby avoiding repulsion between Si⁴⁺ and D⁺. Two of the other three O²⁻ bonded to Si⁴⁺ with a longer distance possess D⁺ to form two tilted O—D dipoles towards their interlayer hydrogen bonding directions. Thus, the hydrogen capacity in the DHMS phase E structure is eventually controlled by the exchanged amount of Si⁴⁺, while maintaining site disordering of all cations.

4. Conclusions

We analyzed the chemical bonding geometry around hydrogen in the framework structure of phase E, which is representative of the dense hydrous magnesium silicate (DHMS) minerals that retain hydrogen within deep Earth. A single crystal of deuterated DHMS phase E was synthesized at high pressure and temperature and subsequently analyzed using TOF neutron Laue diffraction. The nuclear density distribution of D⁺ in the DHMS phase E framework structure at 100 K was obtained with a high spatial resolution of d_min = 0.50 Å. It was found that, within the layered structure of DHMS phase E, the O—D dipole was tilted from the direction normal to the MgO₆ octahedral layers due to the occurrence of interlayer hydrogen bonding to one of the neighboring O²⁻ ions. This geometry of the hydrogen bonds was similar to that of compressed brucite at high pressures. The hydrogen bond length of DHMS phase E at ambient pressure was comparable with that of brucite at high pressure. By referring to compressibility studies on DHMS phase E and brucite, which have similar structures made of MgO₆ octahedral layers and interlayer spaces, we conclude that hydrogen bonding in these minerals plays a crucial role in increasing their dehydration temperatures. However, the role of hydrogen bonding is more significant in DHMS phase E than in brucite. We propose that cation exchange of Mg²⁺, D⁺ and Si⁴⁺ approximately −1:−6:+2 (molar ratio) occurs within the DHMS phase E structure while retaining full disordering of the cation sites.