Microscopic model for Bose-Einstein condensation and quasiparticle decay

Fischer, Tim; Duffe, Sebastian; Uhrig, Götz S.

doi:10.1209/0295-5075/96/47001

Cited by 20 publications

(20 citation statements)

References 57 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…In recent years, a wide variety of spin-1/2 and spin-1 quantum many-particle models with exotic disordered ground states have been extensively developed [1]. Accordingly, theoretical studies examined key concepts for exotic quantum matter, as for instance, a quantum spin liquid [2], fractional excitations (spinons) and their confinement [3][4][5], quantum criticality [1,6], and Bose-Einstein condensation [7][8][9]. For a long time, the search for a physical realization of novel quantum phases was mainly limited by materials with 3d transition metals, mostly Cu 2+ or Co 2+ , as a magnetic ion.…”

Section: Introductionmentioning

confidence: 99%

Low-temperature spin dynamics in the TmFeO3 orthoferrite with a non-Kramers ion

et al. 2020

View full text Add to dashboard Cite

We investigate the magnetic dynamics of the orthorhombic perovskite TmFeO 3 at low temperatures, below the spin reorientation transition at T SR ≈ 80 K, by means of time-of-flight neutron spectroscopy. We find that the magnetic excitation spectrum combines two emergent collective modes associated with different magnetic sublattices. The Fe subsystem orders below T N ∼ 632 K into a canted antiferromagnetic structure and exhibits sharp, high-energy magnon excitations. We describe them using linear spin-wave theory, and reveal a pronounced anisotropy between in-and out-of-plane exchange interactions, which was mainly neglected in previous reports on the spin dynamics in orthoferrites. At lower energies, we find two crystalline electrical field (CEF) excitations of Tm 3+ ions at energies of ∼2 and 5 meV. In contrast to the sister compound YbFeO 3 , where the Yb 3+ ions form quasi-one-dimensional chains along the c axis, the Tm excitations show dispersion along both directions in the (0KL) scattering plane. Analysis of the neutron scattering polarization factor reveals a longitudinal polarization of the 2 meV excitation. To evaluate the effect of the CEF on the Tm 3+ ions, we perform point-charge model calculations, and their results quantitatively capture the main features of Tm single-ion physics, such as energies, intensities, and polarization of the CEF transitions, and the type of magnetic anisotropy.

show abstract

Section: Introductionmentioning

confidence: 99%

Low-temperature spin dynamics in the TmFeO3 orthoferrite with a non-Kramers ion

et al. 2020

View full text Add to dashboard Cite

show abstract

“…Lately, a lot of effort was put in the study of dimerized strong-rung spin-ladders, such as e.g. the organometallic compounds (CH 3 ) 2 CHNH 3 CuCl 3 (IPA-CuCl 3 ) 10,13,14 or (C 5 H 12 N) 2 CuBr 4 (BPCP) 6,7,15,16 . In this coupling limit, the zero-field excitation spectrum is dominated by gapped but hardly mobile dimer triplet excitations on the rung.…”

Section: Introductionmentioning

confidence: 99%

Symmetric and asymmetric excitations of a strong-leg quantum spin ladder

et al. 2013

View full text Add to dashboard Cite

The zero-field excitation spectrum of the strong-leg spin ladder (C 7 H 10 N) 2 CuBr 4 is studied with a neutron time-of-flight technique. The spectrum is decomposed into its symmetric and asymmetric parts with respect to the rung momentum and compared with theoretical results obtained by the density matrix renormalization group method. Additionally, the calculated dynamical correlations are shown for a wide range of rung and leg coupling ratios in order to point out the evolution of arising excitations, as, e.g., of the two-magnon bound state from the strong to the weak coupling limit.

show abstract

“…Open questions include the possibility to observe macroscopic quantum phenomena such as superfluidity or Josephson effects [41]. Therefore, a possible future extension of the present approach in the spirit of a bond operator formalism [42] or a microscopic model as proposed by Fischer et al [43] would be desirable. The third and fourth order terms may be further simplified by using the approximation given in equation (17) as: with m m = S + S -= S -S -( ) X X , .…”

Section: Resultsmentioning

confidence: 99%

Bose–Einstein condensation of triplons with a weakly broken U(1) symmetry

2017

View full text Add to dashboard Cite

The low-temperature properties of certain quantum magnets can be described in terms of a Bose-Einstein condensation (BEC) of magnetic quasiparticles (triplons). Some mean-field approaches (MFA) to describe these systems, based on the standard grand canonical ensemble, do not take the anomalous density into account and leads to an internal inconsistency, as it has been shown by Hohenberg and Martin, and may therefore produce unphysical results. Moreover, an explicit breaking of the U(1) symmetry as observed, for example, in TlCuCl 3 makes the application of MFA more complicated. In the present work, we develop a self-consistent MFA approach, similar to the Hartree-Fock-Bogolyubov approximation in the notion of representative statistical ensembles, including the effect of a weakly broken U(1) symmetry. We apply our results on experimental data of the quantum magnet TlCuCl 3 and show that magnetization curves and the energy dispersion can be well described within this approximation assuming that the BEC scenario is still valid. We predict that the shift of the critical temperature T c due to a finite exchange anisotropy is rather substantial even when the anisotropy parameter γ is small, e.g., ∆T c ≈ 10% of T c in H= 6 T and for γ ≈ 4µeV.

show abstract

Microscopic model for Bose-Einstein condensation and quasiparticle decay

Cited by 20 publications

References 57 publications

Low-temperature spin dynamics in the TmFeO3 orthoferrite with a non-Kramers ion

Low-temperature spin dynamics in the TmFeO3 orthoferrite with a non-Kramers ion

Symmetric and asymmetric excitations of a strong-leg quantum spin ladder

Bose–Einstein condensation of triplons with a weakly broken U(1) symmetry

Contact Info

Product

Resources

About