Skyrmion annihilation in helimagnets and the critical condition of topological phase transitions with a soft mode

Abstract

Since the 1950s, topological solitons have been used to describe elementary particles[1-3] and particle-like field configurations[4-13] that appear in almost all branches of physics ranging from subatomic to cosmological scales[3,14-16]. In this context, formation and annihilation of particles corresponds to topological phase transitions, whose actual process and mechanism remain elusive. Here, we show that annihilation of an isolated skyrmion in helimagnets as the applied magnetic field increases initiates at its center point by a local magnetization reversal. At the critical field, a soft mode of the spin-wave excitation appears, which vanishes the local magnetization modulus as well as the soft-mode-modulated emergent elastic stiffness[17] at the center, which makes it an emergent magnetic monopole[6]. This softened point vanishes the energy barrier of reversing the local magnetization at the center, which inevitably annihilates the skyrmion. On this basis, we propose a general critical condition for topological phase transitions of field solutions with a soft mode: topological phase transitions initiate at those spatial points where the soft-mode-modulated emergent stiffness matrix losses its positive-definiteness.