The connection between vortex-like topological excitations and conventional excitations in quantum ferromagnetic spin systems on two-dimensional lattice and their stability

Sarkar, Subhajit; Chaudhury, Ranjan; Paul, Samir K.

doi:10.1142/s0217979215502094

Cited by 1 publication

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“…At higher temperatures however, more topological excitations become free and drive a large portion of the spin dynamics of the system. At this point, it is worth mentioning that for quantum ferromagnetic systems on two dimensional square lattice it has been shown that the formation of topological excitations of vortex/ meron types from the fragile magnons and multi-magnon composites is quite plausible [62]. Moreover, some of the collective modes (i.e.…”

Section: Calculations and Resultsmentioning

confidence: 99%

“…magnon and multi-magnon modes) are expected to stay intact with their damped nature and thus can provide a significant contribution to the spin dynamics. In analogy with the three dimensional systems where above the Curie temperature (T c ) the magnon-like collective excitations become fragile and damped, for pure two dimensional systems (where T c = 0) the collective excitations become fragile at any finite temperature [56,[62][63][64][65][66][67]. This process is expected to be operative too in the antiferromagnetic systems on pure two-dimensional lattices.…”

Section: Calculations and Resultsmentioning

confidence: 99%

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Semi-phenomenological analysis of neutron scattering results for quasi-two dimensional quantum anti-ferromagnet

Sarkar

Chaudhury

Paul

2017

Journal of Magnetism and Magnetic Materials

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The available results from the inelastic neutron scattering experiment performed on the quasi-two dimensional spin 1 2 anti-ferromagnetic material La2CuO4 have been analysed theoretically. The formalism of ours is based on a semi-classical like treatment involving a model of an ideal gas of mobile vortices and anti-vortices built on the background of the Néel state, using the bipartite classical spin configuration corresponding to an XY-anisotropic Heisenberg anti-ferromagnet on a square lattice. The results for the integrated intensities for our spin 1 2 model corresponding to different temperatures, show occurrence of vigorous unphysical oscillations, when convoluted with a realistic spectral window function. These results indicate failure of the conventional semi-classical theoretical model of ideal vortex/anti-vortex gas arising in the Berezinskii-Kosterlitz-Thouless theory for the low spin magnetic systems. A full fledged quantum mechanical formalism and calculations seem crucial for the understanding of topological excitations in such low spin systems. Furthermore, a severe disagreement is found to occur at finite values of energy transfer between the integrated intensities obtained theoretically from the conventional formalism and those obtained experimentally. This further suggests strongly that the full quantum treatment should also incorporate the interaction between the fragile-magnons and the topological excitations. This is quite plausible in view of the recent work establishing such a process in XXZ quantum ferromagnet on 2D lattice. The high spin XXZ quasi-two dimensional antiferromagnet like M nP S3 however follows the conventional theory quite well. Keywords: Spin dynamics, Topological spin excitations, Berezinskii-Kosterlitz-Thouless transition, Spin 1/2 easy plane Anti-ferromagnet.Highlights:• Inadequacies in the conventional meron gas phenomenology in explaining the spin dynamics corresponding to layered low-spin anti-ferromagnets.• Requirement of a full fledged quantum mechanical formalism for the understanding of spin dynamics induced by both topological and conventional excitations.• Necessity of a proper understanding of the interaction between the conventional and topological excitations at the quantum level.

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Section: Calculations and Resultsmentioning

confidence: 99%