Magnetic Structure and Phase Diagram of TmB<sub>4</sub>

Gabáni, S.; Maťaš, S.; Priputen, P.; Flachbart, К.; Siemensmeyer, Konrad; Wulf, E.; Evdokimova, A.; Shitsevalova, N. Yu.

doi:10.12693/aphyspola.113.227

Cited by 30 publications

(51 citation statements)

References 6 publications

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“…3(a) as a function of magnetic flux density B = µ 0 H + M [12], displays the previously reported plateau structure [13][14][15]. ρ xx at 2K (Fig.…”

supporting

confidence: 73%

“…[16]. Frustration in TmB 4 is reflected in the moderately large frustration parameter [15,19] and in the appearence of a diffuse peak in neutron scattering above T N 2 [16], indicative of shortrange order. In the temperature range T N 1 > T > T N 2 , the diffuse peak coexists with the sharp peaks from MP1 and MP2 [16].…”

mentioning

confidence: 97%

“…1(b)). While other frustrated Archimedean lattices such as the triangular and Kagomé lattices are well studied [10,11], the RB 4 family is the only known realization of the Archimedean Shastry-Sutherland lattice.In this article, we use magnetization and transport experiments to study TmB 4 , a member of the RB 4 family that has attracted attention for its rich phase diagram [13][14][15][16] (Fig. 1(c)).…”

mentioning

confidence: 99%

“…We suggest that subtle changes occur in the magnetic structure of TmB 4 that strongly influence the MR but not the bulk magnetization. Neutron scattering experiments have shown that the magnetic structure in the modulated and the plateau phases consists of stripes or domains [14][15][16]. However, the microscopic structure at the domain walls is unknown.…”

mentioning

confidence: 99%

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Hysteretic magnetoresistance and unconventional anomalous Hall effect in the frustrated magnetTmB4

et al. 2016

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We study TmB 4 , a frustrated magnet on the Archimedean Shastry-Sutherland lattice, through magnetization and transport experiments. The lack of anisotropy in resistivity shows that TmB 4 is an electronically three-dimensional system. The magnetoresistance (MR) is hysteretic at lowtemperature even though a corresponding hysteresis in magnetization is absent. The Hall resistivity shows unconventional anomalous Hall effect (AHE) and is linear above saturation despite a large MR. We propose that complex structures at magnetic domain walls may be responsible for the hysteretic MR and may also lead to the AHE.Geometric frustration in magnetic systems arises from competing magnetic interactions that cannot be satisfied simultaneously and leads to a variety of exotic ground states [1]. While insulating frustrated materials are well studied, metallic systems have received less attention [2]. In metallic materials, the conduction electrons mediate interactions between the magnetic moments. Additionally, the transport properties in such systems can be strongly influenced by the magnetic structure [1]. This interplay between magnetism and charge can be exploited in two ways: to engineer a highly field tunable response of the transport properties [3] or to use transport experiments as an indirect probe of the complex magnetic structures that arise in such systems [4,5].The rare earth tetraboride family (RB 4 , R is a rare earth) is a series of metallic frustrated magnets. RB 4 crystallizes in a tetragonal structure (space group P4/mbm, 127) [6], consisting of alternating layers of R and B ions (Fig 1(a)). The R ions form a frustrated Shastry-Sutherland lattice (SSL) with competing interactions J 1 and J 2 [7]. Quite remarkably, high resolution structural refinement of LaB 4 [8] and HoB 4 [9] show that the R-R bonds corresponding to J 1 and J 2 are equal in length, making the R-sublattice a rare physical realization of one of the eleven Archimedean lattices [10] (Fig. 1(b)). While other frustrated Archimedean lattices such as the triangular and Kagomé lattices are well studied [10,11], the RB 4 family is the only known realization of the Archimedean Shastry-Sutherland lattice.In this article, we use magnetization and transport experiments to study TmB 4 , a member of the RB 4 family that has attracted attention for its rich phase diagram [13][14][15][16] (Fig. 1(c)). Crystal field effects at the Tm

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“…3(a) as a function of magnetic flux density B = µ 0 H + M [12], displays the previously reported plateau structure [13][14][15]. ρ xx at 2K (Fig.…”

supporting

confidence: 73%

mentioning

confidence: 97%

mentioning

confidence: 99%

mentioning

confidence: 99%

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Hysteretic magnetoresistance and unconventional anomalous Hall effect in the frustrated magnetTmB4

et al. 2016

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“…This sublattice is again topologically equivalent to the SSL (see Fig. 1 18,19,20,21 In this paper we investigate classical Heisenberg spins on the SSL under a magnetic field. Note that we are not aware of any previous study of the classical limit in the presence of a magnetic field, although some of the first studies of the zero-field properties of the SSL did start from this limit.…”

Section: Miyahara and Uedamentioning

confidence: 99%

Magnetization process in the classical Heisenberg model on the Shastry-Sutherland lattice

et al. 2009

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We investigate classical Heisenberg spins on the Shastry-Sutherland lattice and under an external magnetic field. A detailed study is carried out both analytically and numerically by means of classical Monte-Carlo simulations. Magnetization pseudo-plateaux are observed around 1/3 of the saturation magnetization for a range of values of the magnetic couplings. We show that the existence of the pseudo-plateau is due to an entropic selection of a particular collinear state. A phase diagram that shows the domains of existence of those pseudo-plateaux in the (h, T ) plane is obtained.

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Magnetization Plateaus

Takigawa¹,

Mila²

2010

Springer Series in Solid-State Sciences

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This chapter is devoted to a review of the phenomenon of magnetization plateaus in frustrated quantum magnets. We explain why frustration can introduce 'accidents' in the magnetization process of quantum antiferromagnets, in the form of plateaus occurring at rational values of the magnetization. These are driven by two mechanisms: the stabilization of a commensurate, classical state by quantum fluctuations or the occurrence of a superfluid-insulator transition in effective hardcore-boson models. The first mechanism always leads to a 'classical' plateau, i.e. a plateau with a simple classical analog, while the second often drives the system into a 'quantum' plateau which has no classical analog. Experimental examples of such plateaus are discussed in detail, with special emphasis on the compound SrCu 2 (BO 3 ) 2 , in which a remarkable series of plateaus has been discovered and is currently under intensive investigation. Related topics including magnetization jumps, supersolid phases, and lattice distortions are discussed briefly.

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Magnetic Structure and Phase Diagram of TmB₄

Cited by 30 publications

References 6 publications

Hysteretic magnetoresistance and unconventional anomalous Hall effect in the frustrated magnetTmB4

Hysteretic magnetoresistance and unconventional anomalous Hall effect in the frustrated magnetTmB4

Magnetization process in the classical Heisenberg model on the Shastry-Sutherland lattice

Magnetization Plateaus

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Magnetic Structure and Phase Diagram of TmB4

Cited by 30 publications

References 6 publications

Hysteretic magnetoresistance and unconventional anomalous Hall effect in the frustrated magnetTmB4

Hysteretic magnetoresistance and unconventional anomalous Hall effect in the frustrated magnetTmB4

Magnetization process in the classical Heisenberg model on the Shastry-Sutherland lattice

Magnetization Plateaus

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Magnetic Structure and Phase Diagram of TmB₄