For phonon-mediated superconductors, a high transition temperature necessitates light atomic masses. The lightest atom available to compose a crystal lattice is hydrogen, which forms covalently bonded molecular dimmers under ambient conditions. Transforming pure molecular hydrogen, with the aid of pressure, into a metal with an atomic lattice and into a superconductor has been a long-standing challenge and the subject of contention for the high-pressure community. Yet, chemical pre-compression with certain elements reduces the pressure required for metallization; thus, stable hydrogen-rich phases can be synthesized by the current high-pressure technology. With the discovery of a superconducting transition at the critical temperature Tc = 203 K in H3S at 150 GPa1, the search for hydrogen-rich high-temperature superconductors (HTS) has intensified, with the recent report of room-temperature superconductivity in C-S-H system with a maximum Tc of 288 K2. A new family of rare-earth hydrides, such as LaH103,4 and YH95, opened a path to a significant increase in Tc, which is predicted to reach 305–326 K in YH106.

While in H3S the crystal lattice is formed by H-S covalent bonds, LaH10 forms a clathrate-like structure, where each La atom is locked at the center of a H32 hydrogen cage. The interatomic distances between hydrogen atoms in LaH10 are close to the H–H distance predicted for atomic metallic hydrogen near p = 500 GPa6. Due to the short H–H distances and the high hydrogen content, LaH10 can be considered as “doped” metallic hydrogen. A pronounced isotope effect on Tc when hydrogen is substituted by its heavier isotope deuterium, confirmed that the superconductivity in HTS hydrides is induced by electron–phonon interactions7. However, there is a dearth of experimental studies on HTS hydrides due to the very limited number of measurement techniques available at such extreme pressures. Here we explore the superconductivity and the structure of the lanthanum hydride family over a wide range of pressures, temperatures, and magnetic fields. We find that superconductivity in LaH10 is strongly affected by a crystal lattice instability toward symmetry-lowering distortions. A similar dramatic change in the Tc(p) dependence for another HTS hydride H3S was also linked to a structural phase transition8,9,10,11. The present study firmly establishes the connection between HTS and soft phonon modes that are responsible for the structural instability in hydrides.

Results and discussion

The relation between crystal structure and superconductivity

Metallic lanthanum readily reacts with hydrogen at high pressures and temperatures yielding the clathrate-like superhydride LaH10. We found that the superconducting Fm-3m phase of LaH10 can be synthesized at pressures much lower than 150–170 GPa3,4,12,13 as reported earlier. Specifically, the powder X-ray diffraction data show that the sample prepared in the present study under 138 GPa is comprised of the dominant Fm-3m phase of LaH10. The minor impurity phases are attributed to two hexagonal close-packed (hcp) phases with the P63/mmc space group but with a different c/a ratio (1.63 for hcp-I and 1.48 for hcp-II) and a composition close to LaH10 (Fig. 1). Both impurity phases were also found in various samples prepared via the direct chemical reaction between hydrogen and lanthanum or lanthanum trihydride in the previous work3 and did not distinctly affect the Tc of the superconducting Fm-3m phase, which has the highest Tc in the lanthanum–hydrogen system3.

Fig. 1: Structural data for LaH10 synthesized from La and excess H2.
figure 1

a, b Rietveld refinement for Fm-3m phase of LaH10 at 138 GPa and C2/m phase of LaH10 at 120 GPa, respectively. The peaks originating from the hcp-I (a = 3.668(4) Å; c = 5.914(11) Å; V = 68.9(1) Å3 at 138 GPa) and hcp-II (a = 3.750(3) Å; c = 5.561(7) Å; V = 67.7(1) Å3 at 138 GPa) impurity phases are indicated through blue and red dashes, respectively. The refined ratio between the main and the impurity phases is provided in the left bottom corner of each figure. The main structural building block, two connected LaH32 polyhedra, are shown in the middle inserts for each phase. Large blue and small black spheres correspond to La and H atoms, respectively. c, d The original powder X-ray diffraction patterns at 138 and 120 GPa, respectively. New reflections appear at 120 GPa due to the monoclinic distortions.

The persistence of the high-pressure, high-symmetry phase of LaH10 at pressures as low as 138 GPa corroborates recent theoretical calculations that take quantum effects into account14. In contrast to the classical ab initio calculations6,14,15, which predict structural distortions in the Fm-3m LaH10 below 230 GPa, the inclusion of the zero-point energy stemming from quantum atomic fluctuations lowers the enthalpy of the high-symmetry phase and stabilizes it at pressures as low as 129 GPa14.

The LaH10 sample under 138 GPa still exhibits a narrow superconducting transition toward zero resistance with a high Tc of 243 K, slightly lower than the maximum Tc of 250 K reported for LaH10 at 150–170 GPa3,4,13, in accordance with a “dome-shape” pressure dependence of Tc for the Fm-3m phase of LaH103. No intrinsic hysteresis between cooling and warming R(T) curves was observed (Supplementary Fig. 1). The resistivity ρ of LaH10 is estimated to be (0.3 ± 0.1) mΩ·cm at T = 300 K and is higher than the value reported for H3S16. The large error bar is mainly due to the uncertainty on the thickness of the sample.

After the abrupt decompression from 138 to 120 GPa, some reflections from the ancestral cubic phase became split (Fig. 1) and the Tc dropped to 191 K (Fig. 2). The powder X-ray diffraction patterns of the new distorted phase can be reasonably indexed within the C2/m space group (Fig. 1b). The refined cell parameters and the coordinates of the heavier La atoms are in a good agreement with theoretical models for the C2/m LaH10 phase14,17,18. According to the theoretical calculations14, the monoclinic scenario of the structural distortions is energetically more favorable than two alternative orthorhombic and rhombohedral distortions of the Fm-3m phase of LaH10 on decompression.

Fig. 2: The superconducting transitions in LaH10.
figure 2

a The electrical resistance in LaH10 after the synthesis under 138 GPa (red curve), after the abrupt decompression down to 120 GPa (brown curve), and upon a gradual increase in pressure from 120 to 136 GPa (blue, green, purple, and black curves). The data measured at 138 GPa on the upper panel are divided by 9 for better presentation. b Pressure dependence of Tc in LaH10 measured in the present study (black symbols) and from a prior study3 (open red symbols). Insets: photos of the DAC loaded with a La flake and after the synthesis of LaH10 through laser-assisted heating.

We found that these monoclinic structural distortions are reversible, and the high-symmetry phase can be restored if the pressure is increased. The observed Tc increases rapidly within a short pressure range with increasing pressure and reaches 241 K at 136 GPa (Fig. 2a). The broadening of the superconducting transition in Fig. 2a is likely caused by the deterioration of the phase crystallinity during variations of the pressure. The continuous change of the lattice volume during the Fm-3mC2/m phase transition is in close agreement with both the experimental3 and theoretical19 equations of state for LaH10 indicating the retention of the LaH10 composition (Supplementary Fig. 2). In addition, predictions suggest that the composition should not change during any structural distortion scenario for the Fm-3m phase of LaH10 upon decreasing pressure14,17,18.

The pressure dependence of Tc in Fig. 2 displays two distinct regions—a low-pressure region characterized by a sharp rise in Tc, and a high-pressure region with a much more moderate dome-like Tc(p) dependence, with a clear boundary between the two regions at 135 GPa. This distinct shape in Tc(p) in LaH10 closely resembles the Tc variation first discovered in the hydride H3S, where a sharp but continuous drop in Tc was attributed to the change of the crystalline structure8,10,11. Multiple distorted hydrogen arrangements from a high-symmetry Fm-3m phase are predicted for LaH10 as well14. One of the predictions reports a stable LaH10 Fm-3m phase at high pressures, with symmetric H positions and a Tc of 259 K at 170 GPa. The drop in pressure is predicted to stabilize a distorted R-3m phase of LaH10, with Tc = 206 K at 150 GPa18. A Tc ~ 229–245 K was calculated for the C2/m phase, although the calculations were performed for p = 200 GPa, which is substantially higher than the values presented here17.

The softening of lattice vibrations

A likely explanation for the drastic change in the dependence of Tc with pressure <135 GPa is a structural phase transition in LaH10. The lack of a discontinuous jump in Tc in LaH10 and in H3S8,10 points to a continuous symmetry-lowering lattice distortion or a phase transition of the second order or weakly first order. We calculated phonon dispersion relations for the high-symmetry Fm-3m and distorted C2/m phases of LaH10 and identified the lattice vibrations that soften upon decompression and can be linked to the observed lattice distortion (Supplementary Fig. 4). The calculated phonon dispersions show that the Fm-3m phase is dynamically stable at 200 GPa. However, the softening of the low-lying H-H “wagging” vibration modes along the Γ–Χ direction is found in the phonon spectrum (Supplementary Figs. 4 and 5), which leads to a structural instability toward the monoclinic C2/m distortion. The classical harmonic treatment of atomic vibrations for the Fm-3m phase of LaH10 shows negative phonon frequencies at pressures <180 GPa.

The transformation of the crystallographic structure from a higher- to a lower-symmetry phase is governed by the phonon softening when the frequency of the collective atomic movement approaches zero. Such a drastic change in the phonon modes often has a profound effect on the phonon-mediated superconducting order. A boost in the Tc due to phonon softening in the vicinity of a structural transition has been reported in a number of superconducting families, ranging from Sn nanostructures20, A15 compounds21, intercalated graphite22, ternary silicides23, and even some elements under pressure24,25. The symmetry-lowering distortion in the H sub-lattice in LaH10 is driven by the softening of the low-lying H-H vibration modes below 500 cm−1 (Supplementary Figs. 4 and 5), leading to a stronger electron–phonon interaction in the Fm-3m phase, which is characterized by a coupling constant \(\lambda =2{\int }_{0}^{\infty }{{\alpha }^{2}F(\omega )\omega }^{-1}{{{{{\rm{d}}}}}}\omega\), where \(\omega\) is the phonon frequency, \(F\left(\omega \right)\) is the phonon density of states, and \({\alpha }^{2}\) is an average square electron–phonon matrix element. While the light atomic mass of hydrogen is a necessary requirement for phonon-coupled HTS, Tc is also strongly affected by \(\lambda\)26,27,28,29, with a peak in Tc predicted for large \(\lambda\) ~ 2–2.5, which should occur in the vicinity of the lattice instability in HTS hydrides30.

Lattice distortion effect on superconducting parameters

The impact of the structural instability on the key parameters of the superconducting phase, including the upper critical field, Hc2, and the superconducting coherence length, \(\xi\), for the Fm-3m and C2/m phases of LaH10 was confirmed through magnetotransport measurements. The samples were electrically connected in a van der Pauw configuration (Fig. 2c, inset), making the measurements of both resistivity and Hall effect possible. The LaH10 sample under 120 GPa was measured up to 45 T in direct current (DC) magnetic fields, and the LaH10 sample under 136 GPa was measured in a 65 T pulsed magnet.

The magnetoresistance (MR) of LaH10 collected at fixed temperatures is shown in Fig. 3. Under external magnetic fields, the superconducting transitions span tens of teslas, which correlates with the broadening of the superconducting transition at zero field (Fig. 2a). The normal state MR above Hc2 is nearly field and temperature independent, with a clear kink at the onset of superconductivity at Hc2. For the consistency with prior studies, the Hc2 values are determined as the intersection between the straight line extrapolations of the normal state MR and the slope of the superconducting transition by a method similar to the one followed in ref. 16. The irreversibility field of the high-temperature superconducting phase (H*) is taken by extrapolating the leading edge of the transition to the horizontal axis (Supplementary Fig. 6). The Hall resistance signal measured above Tc is consistent with the electron-like Fermi surface (Supplementary Fig. 7).

Fig. 3: Resistance of LaH10 as a function magnetic field at different temperatures.
figure 3

a DC field measurements for the C2/m phase of LaH10 at 120 GPa. Two dashed lines extrapolate the slope of the high-temperature superconducting transition (left line) toward the asymptotic trace representing the high-field normal state magnetoresistance (right line) at 170 K, respectively. The intersection between two lines provides an estimation of the upper critical field (Hc2). The intersection of the first line with the horizontal axis indicates the irreversibility field (H*) for the high-temperature superconducting phase. b Pulsed field measurements for the Fm-3m phase of LaH10 at 136 GPa. Both DC and pulsed field traces were recorded under isothermal conditions with no observation of eddy current-generated Joule heating due to the sweeping of the field. c Fits of the superconducting upper critical Hc2 to the Werthamer–Helfand–Hohenberg (WHH) formalism. Red and blue squares denote the loci of Hc2 of LaH10 at 136 and 120 GPa, respectively. Lines of the same color correspond to the WHH fits of the experimental data.

Upper critical field measurements in H3S HTS hydride have independently verified a large \(\lambda\) ~ 216. We find a substantially larger Hc2 for LaH10 and determined that magnetic fields of the order of 100 T are required to distinguish between a strongly coupled scenario with a large \(\lambda\) and the more commonly employed Werthamer–Helfand–Hohenberg (WHH) model derived in the weakly coupling limit, \(\lambda \ll 1\)31. To extract the key superconducting properties of LaH10 and explore the effects of the structural transition on its superconductivity, we fit the temperature dependence of Hc2 to the WHH (Fig. 3c and Table 1) formalism. The WHH model fits our data well for fields up to 60 T, which is our upper measurement limit. The WHH model considers the combined effects of the magnetic field on the orbital motion and on the spin of the electrons: \({H}_{{{{{{\rm{c}}}}}}2}^{-2}={H}_{{{{{{\rm{orb}}}}}}}^{-2}+{H}_{{{{{{\rm{p}}}}}}}^{-2}\), where \({H}_{{{{{{\rm{orb}}}}}}}\) and \({H}_{{{{{{\rm{p}}}}}}}\) are the orbital-limited and spin-limited (Pauli) critical fields, respectively. We obtain \({H}_{p}\)(0) values of 352 T at 120 GPa and 457 T at 136 GPa. \({H}_{{{{{{\rm{p}}}}}}}\)(0) values are larger by a factor of ~3 when compared to the Hc2(0) values listed in Table 1, indicating predominantly orbital-limited upper critical fields in HTS LaH10, which is similar to H3S16.

Table 1 Summary of sample properties and the associated WHH fit parameters: the critical temperature, the upper critical field at T = 0 K, coherence length at T = 0 K, BCS Fermi velocity, calculated bare-band Fermi velocity, and the slope of Hc2 at the critical temperature.

The WHH fit provides a reasonable estimate of the superconducting coherence length \(\xi =\sqrt{{{{{{{\rm{\phi }}}}}}}_{0}/2{{{{{\rm{\pi }}}}}}{H}_{{{{{{\rm{c}}}}}}2}}\), where \({{{{{{\rm{\phi }}}}}}}_{0}\) is the magnetic flux quantum. There is a significant drop in Tc in the distorted phase of LaH10 at 120 GPa when compared to the LaH10 sample at 136 GPa. Surprisingly, Hc2(0) only drops by a small amount and thus \(\xi\) (0) remains nearly unchanged. \(\xi\) is linked to both Tc and the Femi velocity \({\upsilon }_{{{{{{\rm{F}}}}}}}\): \(\xi =0.18\,\hslash {\upsilon }_{{{{{{\rm{F}}}}}}}/{k}_{{{{{{\rm{B}}}}}}}{T}_{{{{{{\rm{c}}}}}}}\) within the BCS theory7, but the \(\xi \sim {\upsilon }_{{{{{{\rm{F}}}}}}}/{T}_{{{{{{\rm{c}}}}}}}\) rule should remain valid for other models, thus signaling a lower value for \({\upsilon }_{{{{{{\rm{F}}}}}}}\) in the C2/m phase at 120 GPa when compared to that in the Fm-3m phase at 136 GPa. The onset of the lattice distortion is expected to be strongly affected by the electron dispersion, e.g. via the flattening of the bands at the boundaries of the new Brillouin zone, which may lead to a drop in \({\upsilon }_{{{{{{\rm{F}}}}}}}\) so that \(\xi\) and Hc2 remain high despite the drop in Tc in the C2/m phase. We calculated the \({\upsilon }_{{{{{{\rm{F}}}}}}}\) values along the Fermi surfaces in the first Brillouin zone for both C2/m and Fm-3m phases (Fig. 4a). The average calculated \({\upsilon }_{{{{{{\rm{F}}}}}}}\) values are listed in Table 1 alongside with the BCS values obtained from Hc2(0). The calculated \({\upsilon }_{{{{{{\rm{F}}}}}}}\) values are larger than BCS ones mainly because the calculations do not account for the renormalization of the bare-band \({\upsilon }_{{{{{{\rm{F}}}}}}}\) due to electron–phonon coupling. Nevertheless, the model provides a more reliable estimate of the relative change in \({\upsilon }_{{{{{{\rm{F}}}}}}}\). The calculations confirm a ~30% drop in \({\upsilon }_{{{{{{\rm{F}}}}}}}\) in the C2/m phase as observed in the high-field experiments. A comparative review of the \({\upsilon }_{{{{{{\rm{F}}}}}}}\) values for other hydrogen-rich HTS families, which can be extracted from the published Hc2 data, as well as the present study, reveal a surprisingly narrow distribution close to ~2.5 × 105 m/s (Fig. 4b). A similar universal Fermi velocity was first noticed in the HTS cuprates, with a surprisingly similar average value of ~2.7 × 105 m/s32. This similarity points to a renormalization of the charge carrier band dispersion both in the cuprates and in the hydrides via a strong coupling to low-lying excitations near the Fermi level, the same coupling that is commonly considered to be responsible for the high-temperature superconductivity.

Fig. 4: Fermi velocities for the different hydrides.
figure 4

a Calculated Fermi velocities associated with the electronic states on the Fermi surfaces in the first Brillouin zone (frame) where the color scale goes from blue (slowest) to the red (fastest). The perspective comprises angles of rotation with respect to the x-, y-, z-axis of 0°, 0°, and 0° for the C2/m-LaH10 and 13°, −13°, and 1° for the Fm-3m-LaH10, respectively. b Extracted coherence lengths ξ (cyan circles, left axis) and BCS Fermi velocities vF (magenta circles, right axis) for the different hydrides5,13,19,41,42,43. The labels associated with the C2/m-LaH10 and Fm-3m-LaH10 phases correspond to results from the present study.

In conclusion, we have measured the properties of the superconducting LaH10 compound as a function of pressure, temperature, and high magnetic fields. We find evidence for a pressure-induced Fm-3mC2/m structural transition in LaH10 at pc = 135 GPa, resulting in a steep but continuous decrease in Tc(p) below pc. A likely mechanism for the structural instability is phonon softening associated with a gradual distortion of the lattice, as proposed for another HTS hydride H3S. We established key superconducting quantities of superhydrides under high magnetic fields, including upper critical fields and coherence lengths. We found that the drop in the Femi velocity in LaH10 is consistent with the distortion-induced changes in the Brillouin zone. The proximity of a peak in Tc to a symmetry-lowering structural transition, which is now experimentally established for at least two HTS hydride families, indicates that the tuning of the soft phonon modes should be viewed as one of the main pathways toward maximizing Tc in the hydrogen-rich superconductors.


Diamond anvil cell

The superconducting sample of LaH10 were synthesized in situ in a miniature diamond anvil cell (DAC) with a maximum diameter of 8.8 mm and a body length of 30 mm. The DAC was designed by reworking and modifying the prototype piston/locking nut design and briefly discussed in ref. 1. To minimize the heating effect under high magnetic fields and provide a high mechanical strength, the body of the high-pressure cell was made of a high-purity Cu–Ti alloy with 3 wt % Ti and Cu–Be alloy with 1.8–2.0 wt % Be. These DACs allow one to reach high pressures up to 200 GPa, perfectly fit the narrow bore of high field DC and pulsed magnets, and still have wide opening-angle appropriate to the routine X-ray diffraction and spectroscopic measurements.

Sample preparation

For the sample synthesis, a small piece of metallic lanthanum (Alfa Aesar, 99.9%) with a lateral dimension of about 10 μm and a thickness of 1–2 μm was placed in the center of the beveled diamond anvil with a culet size of 35 μm onto the tips of four sputtered leads. The 120-nm-thick tantalum leads covered by a 50-nm-thick gold layer were sputtered onto the diamond surface in a van der Pauw configuration with a distance of 4 μm between tips (see Supplementary Fig. 7 inserts). The electrical leads were thoroughly isolated from the metal rhenium gasket by a protecting layer made from magnesium oxide, calcium fluoride, and epoxy glue mixture. Excess hydrogen (Westfalen, 99.999%) was introduced in the DAC at a gas pressure of about 150 MPa and served as both a reactant and a pressure-transmitting medium. After the cell was thoroughly clamped, the sample was pressurized to a pressure of 138 GPa and then heated up to 1500–2000 K by a microsecond pulse YAG laser to initiate the chemical reaction between reactants. Hydrogen was always in excess, and its presence in the DAC throughout the experiment was monitored visually and by Raman spectroscopy. The pressure was estimated from the Raman shift of the diamond line edge33 and the vibron of H234. Although both scales indicated the same pressure values within an error of ±5 GPa, we used the hydrogen scale throughout the manuscript.

After electrical transport and X-ray diffraction measurements for the sample of the Fm-3m LaH10 at 138 GPa, the pressure in the DAC abruptly dropped to 120 GPa during transportation. Then the pressure was increased stepwise up to 136 GPa. Zero field electrical transport properties were measured at each pressure step. X-ray diffraction data were collected at 138 and 120 GPa and magnetotransport measurements under external magnetic fields were done at 120 and 136 GPa.

Structure characterization

X-ray diffraction data were collected at the beamline 13-IDD at GSECARS, Advanced Photon Source using λ1 = 0.2952 Å and λ2 = 0.3344 Å, beam spot size of 3 × 3 μm, and Pilatus 1 M CdTe detector. Typical exposure time varied between 10 and 300 s. Processing and integration of the powder X-ray diffraction patterns were carried out using the Dioptas software35. Indexing and Rietveld refinement were performed in GSAS and EXPGUI packages36,37. The coordinates of the heavier lanthanum atoms were refined from the experimental data, whereas H atoms were placed in the theoretically calculated positions. With the lattice parameters and La atom positions fixed, structural relaxation for H atom positions was carried out using the Quantum-ESPRESSO package38. Structural data for the refined Fm-3m and C2/m phases of LaH10 can be obtained as Crystallographic Information Files from the Cambridge Crystallographic Data Centre via, on quoting the Deposition Number: 2033292–2033293.

The present structural data contradict the antecedent experimental work12, in which the Fm-3m phase of LaH10 was studied upon decompression from 169 to 27 GPa. Geballe et al. found a phase transition that breaks the face-centered cubic symmetry of the crystal lattice at pressures of 152–121 GPa and a subsequent decomposition of LaH10 compound at lower pressures. The authors proposed an R-3m structural model for the distorted phase of LaH10, though the observed peaks in powder X-ray diffraction patterns did not match the calculated positions for this model. The same inconsistency between the observed and calculated peaks can be seen if one fits the present X-ray diffraction data at 120 GPa within the R-3m model (Supplementary Fig. 2), which indicates that the suggested R-3m model is erroneous.

We also found that the instability of the Fm-3m LaH10 phase occurs at much lower pressures than was claimed by Geballe et al.12 This discrepancy likely stems from the different pressure scales, which were used for estimation of the pressure values in samples. The hydrogen scale used in the present study is more accurate in comparison with the diamond scale, which is based on the stresses in diamonds and strongly depends on the arrangement of the experiment. Hydrogen is very soft even in the solid state and uniformly transmits pressure over the sample. Therefore, the peak of the hydrogen vibron is sharp and the corresponding pressure values can be determined with accuracy greater than ±3 GPa. The uncertainty of the estimation of pressure values in DAC using the diamond scale is shown in Supplementary Fig. 3b. Based on the spectroscopic study of 21 various samples of D2, the dispersion of the pressure values estimated using the diamond scale for the same positions of the high-wavenumber D2 vibron can be as high as 25 GPa in the pressure range of 100–200 GPa. The similar difference of 18 GPa is observed between the present data and data from ref. 12 on the pressure dependence of the volume per La atom in LaH10. Our data are in very close agreement with the equation of state of LaH10 calculated using the Quantum Espresso pseudopotentials19. Thus, the overestimated pressure value of 152 GPa, which was claimed as the beginning of the structural instability of the Fm-3m phase of LaH10 in ref. 12 should be reduced to 134 GPa, which is in perfect agreement with pc = 135 GPa found in the present study.

Zero field electrical transport measurements

Zero field electrical resistance was measured through a four-probe technique in van der Pauw geometry with currents ranging from 10−4 A at p = 138 GPa to 10−3 A at p = 120–136 GPa samples. No apparent effect of the current value on the measured Tc was observed. The electrical measurements are presented in a warming part of a thermal cycle as it yields a more accurate temperature reading: the sample is warmed up slowly (0.2 K/min) under nearly isothermal environmental conditions (no coolant flow). The temperature was measured by a Si diode thermometer attached to the DAC with an accuracy of 1 K. Tc was determined at the offset of superconductivity—at the point of apparent deviation in the temperature dependence of the resistance from the normal metallic behavior.

Magnetotransport measurements

MR and Hall effect measurements under high magnetic fields were conducted in the 45 T hybrid magnet and in the 65 T pulsed magnet at the National High Magnetic Field Laboratory. A copper thermal shield was placed around the DAC during DC field measurements. The thermal shield was heated uniformly to reduce the thermal gradients, and a secondary Cernox thermometer was attached to the DAC gasket for accurate measurements of the sample temperature. There is no observable heating from the ramping of the magnetic field at rates up to 3 T/min. The Hall effect was measured for the sample at 120 GPa above Tc in the hybrid DC magnet from 11.5 to 45 T. Reverse-field reciprocity method was employed to determine Hall resistance \({R}_{{xy}}\)39 because the field direction of the hybrid magnet cannot be reversed during the day shift. A high-frequency (290 kHz) lock-in amplifier technique was employed to measure sample MR in 65 T pulsed magnet. AC current 500 µA was applied to the sample, and the voltage drop across the sample was amplified by an instrumentation amplifier and detected by a lock-in. No sample heating was observed during ~50 ms long magnet pulse based on comparisons of up sweep and down sweep resistance traces at different field sweep rates.

Computational details

Structural relaxation, electronic structures, and phonon calculations were carried out within the framework of density functional theory (DFT) as implemented in the Quantum-ESPRESSO package38. Structure relaxations were performed using DFT using the Perdew–Burke–Ernzerhof generalized gradient approximation40. Phonon dispersion calculations were performed with the density functional perturbation theory. Ultrasoft pseudopotentials for La and H were used with a kinetic energy cutoff of 80 Ry. To reliably calculate the phonon dispersion, we have employed dense k-meshes and q-meshes for all the phonon calculations: 8 × 8 × 4 k-meshes and 4 × 4 × 2 q-meshes for the C2/m-LaH10 structure and 12 × 12 × 12 k-meshes and 6 × 6 × 6 q-meshes for the Fm-3m-LaH10 structure. The visualization of the atomic vibrations was done by using a visualization tool ( For visualization in three-dimensional of the Fermi velocities associated with the electronic states on the Fermi surfaces in the first Brillouin zone, we have used FermiSurfer open software drawing code (

WHH model

Numerical fit to the WHH model for the temperature dependence of Hc2(T) defined by orbital and spin-paramagnetic effects in the dirty limit is given by WHH31:

$${{{{{\rm{ln}}}}}}\left(\frac{1}{t}\right)=\mathop{\sum }_{\nu =-\infty }^{\infty}\left\{\frac{1}{\left|2\nu +1\right|}-{\left[\left|2\nu +1\right|+\frac{{\bar{h}}}{t}+\frac{{(\alpha \bar{h}/t)}^{2}}{\left|2\nu +1\right|+({\bar{h}}+{\lambda }_{{{{{{\rm{SO}}}}}}})/t}\right]}^{-1}\right\}$$

where \(\bar{h}\) = (4/π2)[Hc2(T)/Tc(−dHc2/dT)Tc], α is the Maki parameter, and λSO is the spin–orbit constant. The Maki parameter for each sample is estimated from the slope of Hc2(T) at T = Tc: \(\alpha =\sqrt{2}\,{H}_{{{{{{{{\rm{c}}}}}}\; {{{{{\rm{orb}}}}}}}}}/{H}_{{{{{{{{\rm{c}}}}}}\; {{{{{\rm{p}}}}}}}}} \sim {\left.-0.52758{{{{{\rm{d}}}}}}{H}_{{{{{{\rm{c}}}}}}2}/{{{{{{\rm{d}}}}}}T}\right|}_{{T_{{{{{\rm{c}}}}}}}}\)26.