Spin-glass and non–spin-glass features of a geometrically frustrated magnet

Lee, S.H.; Broholm, C.; Aeppli, G.; Ramirez, A. P.; Perring, T. G.; Carlile, C.J.; Adams, Mark A.; Jones, T. J.; Hessen, Bart

doi:10.1209/epl/i1996-00543-x

Cited by 74 publications

(59 citation statements)

References 27 publications

(35 reference statements)

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“…1e) for h ac < h A than for h ac > h A . Indeed, the imaginary part of the bulk response should be rigorously zero [20] for h ac → 0 for a clean Heisenberg magnet (with h A = 0) consisting of AFM triangles.…”

mentioning

confidence: 99%

Macroscopic Signature of Protected Spins in a Dense Frustrated Magnet

2008

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The inability of systems of interacting objects to satisfy all constraints simultaneously leads to frustration. A particularly important consequence of frustration is the ability to access certain protected parts of a system without disturbing the others. For magnets such "protectorates" have been inferred from theory and from neutron scattering, but their practical consequences have been unclear. We show that a magnetic analogue of optical hole-burning can address these protected spin clusters in a well-known, geometrically-frustrated Heisenberg system, Gadolinium Gallium Garnet. Our measurements additionally provide a resolution of a famous discrepancy between the bulk magnetometry and neutron diffraction results for this magnetic compound.

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confidence: 99%

Macroscopic Signature of Protected Spins in a Dense Frustrated Magnet

2008

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“…The magnetic susceptibility measurements (macroscopic, χ macro , in contrast to local measurements by NMR technique [10]) suggest the occurrence of spin glass state with spin freezing temperature T g ≈ 2-5 K [11][12][13][14][15]. All other experimental data confirms existence of a spin-liquid-like ground state [12,16,17]. In particular, neutron diffraction experiments indicate the existence of subgroups of spins (singlets, triangles, etc.)…”

Section: Kagome Antiferromagnet Srgamentioning

confidence: 81%

“…In particular, neutron diffraction experiments indicate the existence of subgroups of spins (singlets, triangles, etc.) [17] and lead to the conclusion that only a fraction of the Cr 3+ moments is frozen. The magnetic lattice of SrGa 12−x Cr x O 19 is specific because it consists of kagome bilayers of Cr 3+ ions separated by Cr-Cr isolated spin pairs.…”

Section: Kagome Antiferromagnet Srgamentioning

confidence: 99%

Effect of Chemical Disorder on Geometrically Frustrated Kagome Lattice

Szymczak

Баран

et al. 2008

Acta Phys. Pol. A

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This paper reviews recent progress in the studies of magnetic dilutions on magnetic properties of two frustrated systems: magnetoplumbite-like SrGa 12−x Cr x O 19 and kagome staircase Co 3 V 2 O 8 doped with Mg ions. In the first group of compounds magnetic properties are determined by magnetic defects arising due to doping. In the case of kagome staircase compounds magnetic dilution suppresses effects of crystal field acting on magnetic ions. In particular, the dilution decreases magnetocrystalline anisotropy and anisotropy of magnetization.

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“…One can increase the complexity of this problem by considering the case of the even less constrained system of corner sharing triangles, the kagome lattice. [4,8,9,10,11] There have been many theoretical questions about the nature of the ground state [12,13,14,15] even for classical spins on this lattice. [5,6,7] Experimentally, good experimental realizations of this system have been hard to obtain.…”

Section: Introductionmentioning

confidence: 99%

Néel to spin-glass-like phase transition versus dilution in geometrically frustratedZnCr2−2xGa2x
Lee
¹
,
Ratcliff
²
,
Huang
³

et al. 2008
Phys. Rev. B

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ZnCr2O4 undergoes a first order spin-Peierls-like phase transition at 12.5 K from a cubic spin liquid phase to a tetragonal Neél state.[1] Using powder diffraction and single crystal polarized neutron scattering, we determined the complex spin structure of the Neél phase. This phase consisted of several magnetic domains with different characteristic wave vectors. This indicates that the tetragonal phase of ZnCr2−2xGa2xO4 is very close to a critical point surrounded by many different Neél states. We have also studied, using elastic and inelastic neutron scattering techniques, the effect of nonmagnetic dilution on magnetic correlations in ZnCr2−2xGa2xO4 (x=0.05 and 0.3). For x=0.05, the magnetic correlations do not change qualitatively from those in the pure material, except that the phase transition becomes second order. For x= 0.3, the spin-spin correlations become short range. Interestingly, the spatial correlations of the frozen spins in the x=0.3 material are the same as those of the fluctuating moments in the pure and the weakly diluted materials.

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Spin-glass and non–spin-glass features of a geometrically frustrated magnet

Cited by 74 publications

References 27 publications

Macroscopic Signature of Protected Spins in a Dense Frustrated Magnet

Macroscopic Signature of Protected Spins in a Dense Frustrated Magnet

Effect of Chemical Disorder on Geometrically Frustrated Kagome Lattice

Néel to spin-glass-like phase transition versus dilution in geometrically frustratedZnCr2−2xGa2x
Lee
¹
,
Ratcliff
²
,
Huang
³

et al. 2008
Phys. Rev. B

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Spin-glass and non–spin-glass features of a geometrically frustrated magnet

Cited by 74 publications

References 27 publications

Macroscopic Signature of Protected Spins in a Dense Frustrated Magnet

Macroscopic Signature of Protected Spins in a Dense Frustrated Magnet

Effect of Chemical Disorder on Geometrically Frustrated Kagome Lattice

Néel to spin-glass-like phase transition versus dilution in geometrically frustratedZnCr2−2xGa2xLee1, Ratcliff2, Huang3 et al. 2008Phys. Rev. B

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Néel to spin-glass-like phase transition versus dilution in geometrically frustratedZnCr2−2xGa2x
Lee
¹
,
Ratcliff
²
,
Huang
³

et al. 2008
Phys. Rev. B