# Quantum phase transition and unusual critical behavior in multi-Weyl   semimetals

**Authors:** Jing-Rong Wang, Guo-Zhu Liu, Chang-Jin Zhang

arXiv: 1705.04001 · 2017-11-22

## TL;DR

This paper investigates how long-range Coulomb interactions and quenched disorder influence the low-energy phases of double- and triple-Weyl semimetals, revealing distinct quantum phase transitions and critical behaviors.

## Contribution

It provides a comprehensive renormalization group analysis of the interplay between Coulomb interaction and disorder in multi-Weyl semimetals, highlighting their different responses and phase transitions.

## Key findings

- Weak disorder induces a transition to a diffusive metal in double-Weyl semimetals.
- Triple-Weyl semimetals exhibit disorder-dependent ground states, including stable critical points.
- Coupling Coulomb interaction with disorder can lead to Mott insulating behavior.

## Abstract

The low-energy behaviors of gapless double- and triple-Weyl fermions caused by the interplay of long-range Coulomb interaction and quenched disorder are studied by performing a renormalization group analysis. It is found that an arbitrarily weak disorder drives the double-Weyl semimetal to undergo a quantum phase transition into a compressible diffusive metal, independent of the disorder type and the Coulomb interaction strength. In contrast, the nature of the ground state of triple-Weyl fermion system relies sensitively on the specific disorder type in the noninteracting limit: The system is turned into a compressible diffusive metal state by an arbitrarily weak random scalar potential or $z$ component of random vector potential but exhibits stable critical behavior when there is only $x$ or $y$ component of random vector potential. In case the triple-Weyl fermions couple to random scalar potential, the system becomes a diffusive metal in the weak interaction regime but remains a semimetal if Coulomb interaction is sufficiently strong. Interplay of Coulomb interaction and $x$, or $y$, component of random vector potential leads to a stable infrared fixed point that is likely to be characterized by critical behavior. When Coulomb interaction coexists with the $z$ component of random vector potential, the system flows to the interaction-dominated strong coupling regime, which might drive a Mott insulating transition. It is thus clear that double- and triple-Weyl fermions exhibit distinct low-energy behavior in response to interaction and disorder. The physical explanation of such distinction is discussed in detail. The role played by long-range Coulomb impurity in triple-Weyl semimetal is also considered.

## Full text

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## Figures

17 figures with captions in the complete paper: https://tomesphere.com/paper/1705.04001/full.md

## References

120 references — full list in the complete paper: https://tomesphere.com/paper/1705.04001/full.md

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