Measuring impurity-induced shifts in Coulomb crystallization

TL;DR

This study experimentally investigates how impurities affect Coulomb crystallization in ionic systems, revealing a threshold-dependent shift that impacts models of stellar and plasma crystallization.

Contribution

It provides the first laboratory measurement of impurity-induced shifts in Coulomb crystals, demonstrating a crossover behavior and local pinning effects.

Findings

Crystallization threshold remains unchanged at low impurity levels.

A linear shift occurs once impurity concentration exceeds a certain threshold.

Impurity effects can significantly alter models of stellar and plasma crystallization.

Abstract

We report a laboratory measurement of how impurities shift Coulomb crystallization in a strongly interacting ionic system. This is achieved by using laser cooled Ca$^+$ crystals doped with a controlled number of Xe$^{12+}$ highly charged ions. We find that the crystallization threshold is unchanged at low impurity concentration, but shows a clear crossover once the impurity content becomes sufficiently large, after which the shift grows approximately linearly. Complementary measurements reveal that this global effect originates from a local pinning of the crystal around the impurities. We further show how the measured shift could impact standard models of crystallization in white dwarfs and neutron stars. Our results provide an experimental route to incorporating impurity effects into models of multicomponent Coulomb matter, relevant to stellar crystallization and strongly coupled plasmas.