Observation of Skyrmion liquid in a chiral magnet

A wide class of condensed matter systems can be effectively described as a collection of interacting quasi-particles, like the vortices in type-II superconductors, charge density waves, Wigner crystals of electrons, and Skyrmion phase in chiral magnets, by forming a hexagonal lattice of particles. For weak disorder, the close-packed assembly generally responses to external stimulus elastically and retain their original neighbors. By contrast, for stronger disorder or longer particle-particle distance, the depinning becomes plastic with particles continuously changing neighbors over time, yielding a fluctuating liquid-like state, as confirmed experimentally in the vortices phase in Type-II superconductors. For magnetic Skyrmions, however, the liquid phase as well as a liquid to lattice phase transition have never been identified experimentally. Here, we report strong evidences for the existence of Skyrmion liquid phases in bulk MnSi by using a dynamic magnetoelectric coupling technique. This technique is able to electrically probe the ac magnetoelastic response of Skyrmion phase in MnSi via interfacial strain coupling in a composite magnetoelectric configuration. Clear out-of-phase component of the electric signal is observed only in the Skyrmion liquid phase. Moreover, by tuning the density of Skyrmion or disorder, a lattice to liquid phase transition can further be induced, in analogy to the case in vortices in type-II superconductors.