# Observation of Low-Energy Einstein Phonon and Superconductivity in   Single-Crystalline LaBe$_{13}$

**Authors:** Hiroyuki Hidaka, Yusei Shimizu, Seigo Yamazaki, Naoyuki Miura, Ryoma, Nagata, Chihiro Tabata, Shota Mombetsu, Tatsuya Yanagisawa, and Hiroshi, Amitsuka

arXiv: 1701.04539 · 2017-02-01

## TL;DR

This study reveals low-energy Einstein-like phonons and superconductivity at 0.53 K in single-crystalline LaBe$_{13}$, with unique transport properties indicating novel electron-phonon interactions.

## Contribution

It reports the first observation of low-energy Einstein phonons and superconductivity in LaBe$_{13}$, with detailed thermal and electrical transport measurements.

## Key findings

- Presence of a low-energy Einstein-like phonon mode at ~177 K
- Superconducting transition at 0.53 K, higher than previous reports
- Unusual T^3 dependence in resistivity below 50 K

## Abstract

The thermal and electrical transport properties of single-crystalline LaBe$_{13}$ have been investigated by specific-heat ($C$) and electrical-resistivity ($\rho$) measurements. The specific-heat measurements in a wide temperature range revealed the presence of a hump anomaly near 40 K in the $C$($T$)/$T$ curve, indicating that LaBe$_{13}$ has a low-energy Einstein-like-phonon mode with a characteristic temperature of $\sim$ 177 K. In addition, a superconducting transition was observed in the $\rho$ measurements at the transition temperature of 0.53 K, which is higher than the value of 0.27 K reported previously by Bonville et al. Furthermore, an unusual $T^3$ dependence was found in $\rho$($T$) below $\sim$ 50 K, in contrast to the behavior expected from the electron--electron scattering or the electron--Debye phonon scattering.

## Full text

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## Figures

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## References

27 references — full list in the complete paper: https://tomesphere.com/paper/1701.04539/full.md

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Source: https://tomesphere.com/paper/1701.04539