Your search keyword '"Colbois, J."' showing total 2 results

1. Probing the topology of the quantum analog of a classical skyrmion

Author

Sotnikov, O. M., Mazurenko, V. V., Colbois, J., Mila, F., Katsnelson, M. I., and Stepanov, E. A.

Subjects

Condensed Matter - Strongly Correlated Electrons, Condensed Matter - Materials Science, Physics - Applied Physics, Quantum Physics

Abstract

In magnetism, skyrmions correspond to classical three-dimensional spin textures characterized by a topological invariant that keeps track of the winding of the magnetization in real space, a property that cannot be easily generalized to the quantum case since the orientation of a quantum spin is in general ill-defined. Moreover, as we show, the quantum skyrmion state cannot be directly observed in modern experiments that probe the local magnetization of the system. However, we show that this novel quantum state can still be identified and fully characterized by a special local three-spin correlation function defined on neighbouring lattice sites -- the scalar chirality -- which reduces to the classical topological invariant for large systems, and which is shown to be nearly constant in the quantum skyrmion phase., Comment: The paper was partially rewritten. New results on measurements of the quantum skyrmion state with a quantum computer simulator were added

Published

2020

2. Quantum Nanoskyrmions

Author

Sotnikov, O. M., Mazurenko, V. V., Colbois, J., Mila, F., Katsnelson, M. I., and Stepanov, E. A.

Subjects

Condensed Matter - Strongly Correlated Electrons, Condensed Matter - Materials Science, Quantum Physics

Abstract

Skyrmions in condensed matter physics appear as classical topological spin structures. This nontrivial state can be obtained solving the corresponding micromagnetic model, where the magnetization is treated as a continuous classical vector field. Here, we introduce a new concept of quantum skyrmions of a nanoscale size. This distinct magnetic state can be formed in spin-1/2 low dimensional magnets characterized by a strong Dzyaloshinskii-Moriya interaction. This concept can also be applied to usual spin systems characterized by a nonzero exchange interaction if the quantum solution of the problem is accessible. To perform a complete characterization of such a quantum nanoskyrmion state, we analyze basis functions giving the largest contribution to the ground state at different values of external magnetic field and temperature. We observe that the quantum skyrmionic state is stabilized even when the corresponding classical skyrmionic solution has already undergone a phase transition towards the polarized ferromagnetic state.

Published

2018