The coexistence of ferroelectricity and metallicity seems paradoxical,
since the itinerant electrons in metals should screen the long-range
dipole interactions necessary for dipole ordering. The recent discovery
of the polar metal LiOsO
3
was therefore surprising [as
discussed earlier in Y. Shi et al.,
Nat. Mater
.
2013
,
12
, 1024]. It is thought that the coordination
preferences of the Li play a key role in stabilizing the LiOsO
3
polar metal phase, but an investigation from the combined
viewpoints of core-state specificity and symmetry has yet to be done.
Here, we apply the novel technique of extreme ultraviolet second harmonic
generation (XUV-SHG) and find a sensitivity to the broken inversion
symmetry in the polar metal phase of LiOsO
3
with an enhanced
feature above the Li K-edge that reflects the degree of Li atom displacement
as corroborated by density functional theory calculations. These results
pave the way for time-resolved probing of symmetry-breaking structural
phase transitions on femtosecond time scales with element specificity.
Solid-state electrolytes overcome many challenges of present-day lithium ion batteries, such as safety hazards and dendrite formation1,2. However, detailed understanding of the involved lithium dynamics is missing due to a lack of in operando measurements with chemical and interfacial specificity. Here we investigate a prototypical solid-state electrolyte using linear and nonlinear extreme-ultraviolet spectroscopies. Leveraging the surface sensitivity of extreme-ultraviolet-second-harmonic-generation spectroscopy, we obtained a direct spectral signature of surface lithium ions, showing a distinct blueshift relative to bulk absorption spectra. First-principles simulations attributed the shift to transitions from the lithium 1 s state to hybridized Li-s/Ti-d orbitals at the surface. Our calculations further suggest a reduction in lithium interfacial mobility due to suppressed low-frequency rattling modes, which is the fundamental origin of the large interfacial resistance in this material. Our findings pave the way for new optimization strategies to develop these electrochemical devices via interfacial engineering of lithium ions.
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