Observation of first-order quantum phase transitions and ferromagnetism in twisted double bilayer graphene

TL;DR

This paper reports the discovery of first-order quantum phase transitions and ferromagnetism in twisted double bilayer graphene, revealing complex phase behavior driven by Coulomb interactions and tunable via multiple external fields.

Contribution

It provides the first experimental observation of Coulomb-driven first-order quantum phase transitions and ferromagnetism in TDBG, expanding understanding of correlated phases in twisted multilayer graphene.

Findings

Observation of resistance jumps indicating phase transitions

Hysteresis loops suggest domain formation and memory effects

Multiple first-order transitions among metallic, ferromagnetic, and spin-polarized states

Abstract

Twisted graphene multilayers are highly tunable flatband systems for developing new phases of matter. Thus far, while orbital ferromagnetism has been observed in valley polarized phases, the long-range orders of other correlated phases as well as the quantum phase transitions between different orders mostly remain unknown. Here, we report an observation of Coulomb interaction driven first-order quantum phase transitions and ferromagnetism in twisted double bilayer graphene (TDBG). At zero magnetic field, the transitions are revealed in a series of step-like abrupt resistance jumps with prominent hysteresis loop when either the displacement field (D) or the carrier density (n) is tuned across symmetry-breaking boundary near half filling, indicating a formation of ordered domains. It is worth noting that the good turnability and switching of these states gives a rise to a memory performance with a large on/off ratio. Moreover, when both spin and valley play the roles at finite magnetic field, we observe abundant first-order quantum phase transitions among normal metallic states from charge neutral point, orbital ferromagnetic states from quarter filling, and spin-polarized states from half filling. We interpret these first-order phase transitions in the picture of phase separations and spin domain percolations driven by multi-field tunable Coulomb interactions, in agreement with Lifshitz transition from Hartree-Fock calculations. The observed multi-filed tunable domain structure and its hysteresis resembles the characteristics of multiferroics, revealing intriguing magnetoelectric properties. Our result enriches the correlated phase diagram in TDBG for discovering novel exotic phases and quantum phase transitions, and it would benefit other twisted moir\'e systems as well.