# Charge Density Wave Modulation in Superconducting BaPbO$_3$/BaBiO$_3$   Superlattices

**Authors:** D. T. Harris, N. Cambell, C. Di, J.-M. Park, L. Luo, H. Zhou, G.-Y., Kim, K. Song,5 S.-Y. Choi, J. Wang, M. S. Rzchowski, and C. B. Eom

arXiv: 1812.08589 · 2020-02-26

## TL;DR

This study demonstrates how artificially layered BaPbO$_3$/BaBiO$_3$ superlattices can induce and control short-range charge density wave order, influencing superconductivity and offering a new way to manipulate phase competition in complex oxides.

## Contribution

It introduces a method to stabilize and control short-range CDW order in superlattices, distinct from bulk alloys, revealing new insights into phase interactions in superconducting oxides.

## Key findings

- Short-range CDW order is stabilized in superlattices.
- Charge transfer suppresses long-range CDW in the system.
- Superconductivity is weakened as CDW fluctuations increase at low temperatures.

## Abstract

The isotropic, non-magnetic doped BaBiO$_3$ superconductors maintain some similarities to high-Tc cuprates, while also providing a cleaner system for isolating charge density wave (CDW) physics that commonly competes with superconductivity. Artificial layered superlattices offer the possibility of engineering the interaction between superconductivity and CDW. Here we stabilize a low temperature, fluctuating short range CDW order by using artificially layered epitaxial (BaPbO$_3$)$_{3m}$/(BaBiO$_3$)$_m$ (m = 1-10 unit cells) superlattices that is not present in the optimally doped BaPb$_{0.75}$Bi$_{0.25}$O$_3$ alloy with the same overall chemical formula. Charge transfer from BaBiO$_3$ to BaPbO$_3$ effectively dopes the former and suppresses the long range CDW, however as the short range CDW fluctuations strengthens at low temperatures charge appears to localize and superconductivity is weakened. The monolayer structural control demonstrated here provides compelling implications to access controllable, local density-wave orders absent in bulk alloys and manipulate phase competition in unconventional superconductors.

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Source: https://tomesphere.com/paper/1812.08589