Bypassing Dynamical Freezing in Artificial Kagome Ice

journal article in Web of Science

English

Spin liquids are correlated, disordered states of matter that fluctuate even at low temperatures. Experimentally, the extensive degeneracy characterizing their low-energy manifold is expected to be lifted, for example, because of dipolar interactions, leading to an ordered ground state at absolute zero. However, this is not what is usually observed, and many systems, whether they are chemically synthesized or nanofabricated, dynamically freeze before magnetic ordering sets in. In artificial realizations of highly frustrated magnets, ground state configurations, and even low-energy manifolds, thus remain out of reach for practical reasons. Here, we show how dynamical freezing can be bypassed in an artificial kagome ice. We illustrate the efficiency of our method by demonstrating that the a priori dynamically inaccessible ordered ground state and fragmented spin liquid configurations can be obtained reproducibly, imaged in real space at room temperature, and studied conveniently. We then identify the mechanism by which dynamical freezing occurs in the dipolar kagome ice.

SPIN ICE; COULOMB PHASE; FRAGMENTATION

SCHÁNILEC, V.; CANALS, B.; UHLÍŘ, V.; FLAJŠMAN, L.; SADÍLEK, J.; ŠIKOLA, T.; ROUGEMAILLE, N.

31. 7. 2020

AMER PHYSICAL SOC

COLLEGE PK

1079-7114

Physical Review Letters

125

5

United States of America

057203-1

057201-5

5

https://journals.aps.org/prl/abstract/10.1103/PhysRevLett.125.057203