Litcius/Paper detail

Quantum robustness of fracton phases

Matthias Mühlhauser, Matthias R. Walther, David A. Reiss, Kai Phillip Schmidt

2020Physical review. B./Physical review. B32 citationsDOIOpen Access PDF

Abstract

The quantum robustness of fracton phases is investigated by studying the influence of quantum fluctuations on the X-Cube model and Haah's code, which realize a type-I and type-II fracton phase, respectively. To this end, a finite uniform magnetic field is applied to induce quantum fluctuations in the fracton phase, resulting in zero-temperature phase transitions between fracton phases and polarized phases. Using high-order series expansions and a variational approach, all phase transitions are classified as strongly first order, which turns out to be a consequence of the (partial) immobility of fracton excitations. Indeed, single fractons as well as few-fracton composites can hardly lower their excitation energy by delocalization due to the intriguing properties of fracton phases, as demonstrated in this work explicitly in terms of fracton quasiparticles.

Topics & Concepts

FractonQuantumPhysicsQuantum phasesExcitationPhase (matter)Theoretical physicsQuantum phase transitionCondensed matter physicsQuantum mechanicsMathematicsFractalMathematical analysisQuantum many-body systemsTheoretical and Computational PhysicsTopological Materials and Phenomena