6 research outputs found
Superconductivity in model cuprate as an S=1 pseudomagnon condensation
We make use of the S=1 pseudospin formalism to describe the charge degree of
freedom in a model high- cuprate with the on-site Hilbert space reduced to
the three effective valence centers, nominally Cu. Starting
with a parent cuprate as an analogue of the quantum paramagnet ground state and
using the Schwinger boson technique we found the pseudospin spectrum and
conditions for the pseudomagnon condensation with phase transition to a
superconducting state.Comment: Version to be published in JLT
The MFA ground states for the extended Bose-Hubbard model with a three-body constraint
We address the intensively studied extended bosonic Hubbard model (EBHM) with
truncation of the on-site Hilbert space to the three lowest occupation states
n=0,1,2 in frames of the S=1 pseudospin formalism. Similar model was recently
proposed to describe the charge degree of freedom in a model high-Tc cuprate
with the on-site Hilbert space reduced to the three effective valence centers,
nominally Cu^{1+;2+;3+} . With small corrections the model becomes equivalent
to a strongly anisotropic S=1 quantum magnet in an external magnetic field. We
have applied a generalized mean-field approach and quantum Monte-Carlo
technique for the model 2D S=1 system with a two-particle transport to find the
ground state phase with its evolution under deviation from half-filling.Comment: 9 pages, 3 figure
Unconventional phase transitions in strongly anisotropic 2D (pseudo)spin systems
We have applied a generalized mean-field approach and quantum Monte-Carlo technique for the model 2D S = 1 (pseudo)spin system to find the ground state phase with its evolution under application of the (pseudo)magnetic field. The comparison of the two methods allows us to clearly demonstrate the role of quantum effects. Special attention is given to the role played by an effective single-ion anisotropy (»on-site correlation»). © 2018 The Authors, published by EDP Sciences.The research was supported by the Government of the Russian Federation, Program 02.A03.21.0006 and by the Ministry of Education and Science of the Russian Federation, projects Nos. 2277 and 5719
Erratum to: Condensation of Pseudomagnons in a Two-Dimensional Anisotropic S = 1 Pseudospin System (Physics of the Solid State, (2018), 60, 11, (2145-2149), 10.1134/S1063783418110331)
E-mail address of the corresponding author should read: [email protected]. © 2019, Pleiades Publishing, Ltd
Strongly Anisotropic S=1 (Pseudo) Spin Systems: from Mean Field to Quantum Monte-Carlo
The S=1 pseudospin formalism was recently proposed to describe the charge degree of freedom in a model high-T_{c} cuprate with the on-site Hilbert space reduced to the three effective valence centers, nominally Cu^{1+;2+;3+}. With small corrections the model becomes equivalent to a strongly anisotropic S=1 quantum magnet in an external magnetic field. We have applied a generalized mean-field approach and quantum Monte-Carlo technique for the model 2D S=1 system to find the ground state phase with its evolution under deviation from half-filling and different correlation functions. Special attention is given to the role played by the on-site correlation ("single-ion anisotropy")