Resistivity near a nematic quantum critical point: Impact of acoustic phonons

We revisit the issue of the resistivity of a two-dimensional electronic system tuned to a nematic quantum critical point (QCP), focusing on the non-trivial impact of the coupling to the acoustic phonons. Due to the unavoidable linear coupling between the electronic nematic order parameter and the la...

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Bibliographic Details
Published inarXiv.org
Main Authors de Carvalho, V S, Fernandes, R M
Format Paper Journal Article
LanguageEnglish
Published Ithaca Cornell University Library, arXiv.org 04.09.2019
Subjects
Acoustic coupling
Boltzmann transport equation
Coupling
Critical point
Distribution functions
Electrical resistivity
Fermi liquids
Impurities
Lattice strain
Order parameters
Phonons
Physics - Strongly Correlated Electrons
Scattering
Temperature
Temperature dependence
Trigonometric functions
Variations
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Summary:We revisit the issue of the resistivity of a two-dimensional electronic system tuned to a nematic quantum critical point (QCP), focusing on the non-trivial impact of the coupling to the acoustic phonons. Due to the unavoidable linear coupling between the electronic nematic order parameter and the lattice strain fields, long-range nematic interactions mediated by the phonons emerge in the problem. By solving the semi-classical Boltzmann equation in the presence of scattering by impurities and nematic fluctuations, we determine the temperature-dependence of the resistivity as the nematic QCP is approached. One of the main effects of the nemato-elastic coupling is to smooth the electronic non-equilibrium distribution function, making it approach the simple cosine angular dependence even when the impurity scattering is not too strong. We find that at temperatures lower than a temperature scale set by the nemato-elastic coupling, the resistivity shows the \(T^2\) behavior characteristic of a Fermi liquid. This is in contrast to the \(T^{4/3}\) low-temperature behavior expected for a lattice-free nematic quantum critical point. More importantly, we show that the effective resistivity exponent \(\alpha_\text{eff}(T)\) in \(\rho(T)-\rho_0\sim T^{\alpha_\text{eff}(T)}\) displays a pronounced temperature dependence, implying that a nematic QCP cannot generally be characterized by a simple resistivity exponent. We discuss the implications of our results to the interpretation of experimental data, particularly in the nematic superconductor FeSe\(_{1-x}\)S\(_x\).
ISSN:2331-8422
DOI:10.48550/arxiv.1906.03205