Spin-glass-like behavior of Ge:Mn

Jaeger, Carsten; Bihler, C.; Vallaitis, T.; Goennenwein, Sebastian T. B.; Opel, Matthias; Gross, Rudolf; Brandt, Martin S.

doi:10.1103/physrevb.74.045330

Cited by 83 publications

(78 citation statements)

References 42 publications

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“…In the case of superparamagnets, below the blocking temperature T b of independent superparamagnetic entitles (either single ions or clusters) the FC magnetization continues to increase with decreasing temperature, while for LSCNO we observe relatively flat magnetization below the bifurcation temperature of χ(T ) curve. However, when the interaction between single entities occurs in the superparamagnetic system, it can be difficult to distinguish between such an interacting superparamagnet and a real spin glass exhibiting a thermodynamic phase transition [5]. Let us note that the temperature of maximum in the ZFC χ(T ) curve, T g , is slightly below T irr (in Fig.…”

Section: Resultsmentioning

confidence: 99%

Magnetic Nature of a Ni Dopant in La_1.85Sr_0.15CuO₄: Spin-Glass Behavior

et al. 2010

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The magnetic properties of La1.85Sr0.15CuO4 doped with Ni was investigated in the field up to 5 T and in the temperature range from 2 K to 400 K using both dc and ac techniques. For Ni content larger than 0.05 the system exhibits irreversibility of low-field susceptibility χ(T ) below a certain temperature depending on y and a cusp at T g in χ(T ) measured after zero-field cooling. The decay of remnant magnetization below T g with time is described by a stretched-exponential function. In accordance with scaling theory, all the χ(T ) data for y = 0.50 sample taken in the vicinity of T g at different fields collapse onto two separate curves when plotted as q|t| −β vs. B 2 |t| −β−γ , where q is the spin-glass order parameter, t = (T − T g )/T g , and β and γ are the critical exponents. All these features taken together reveal existence of spin-glass phase below T g . Variation of T g with y is linear below y = 0.25 and T g extrapolates to 0 K for y → 0 what strongly suggests that spin-glass phase extends into superconducting region of the phase diagram.

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Section: Resultsmentioning

confidence: 99%

Magnetic Nature of a Ni Dopant in La_1.85Sr_0.15CuO₄: Spin-Glass Behavior

et al. 2010

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“…Among these systems GeMn is most probably the so far best investigated [2][3][4][5][6][7][8][9][10][11][12][13] providing local ferromagnetic transition temperatures well above 100 K 7,9 and above roomtemperature global ferromagnetic transition temperatures. 8,10 A common approach to fabricate Ge 1−x Mn x layers on Ge substrates is the codeposition of Ge and Mn in low substrate temperature, solid source molecular-beam epitaxy ͑LT-MBE͒.…”

Section: Introductionmentioning

confidence: 99%

Diffuse x-ray scattering from inclusions in ferromagneticGe1−xMnxlayers

et al. 2008

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“…x Mn x [49] or the La(Fe 1-x Mn x ) 11.4 Si 1.6 compounds [50]. In view of this, quantifying the frequency shift of the T f , measured as the relative variation of χ'(T) peak-temperature position per frequency (ω= 2πf) decade…”

Section: E Dynamic Magnetic Susceptibilitymentioning

confidence: 99%

Hydration-induced spin-glass state in a frustrated Na-Mn-O triangular lattice

et al. 2016

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Birnessite compounds are stable across a wide range of compositions that produces a remarkable diversity in their physical, electrochemical and functional properties. These are hydrated analogues of the magnetically frustrated, mixed-valent manganese oxide structures, with general formula, Na x MnO 2 . Here we demonstrate that the direct hydration of layered rock-salt type α-NaMnO 2 , with the geometrically frustrated triangular lattice topology, yields the birnessite type oxide, Na 0.36 MnO 2 ·0.2H 2 O, transforming its magnetic properties. This compound has a muchexpanded interlayer spacing compared to its parent α-NaMnO 2 compound. We show that while the parent α-NaMnO 2 possesses a Néel temperature of 45 K as a result of broken symmetry in the Mn 3+ sub-lattice, the hydrated derivative undergoes collective spin-freezing at 29 K within the Mn 3+ /Mn 4+ sub-lattice. Scaling-law analysis of the frequency dispersion of the AC susceptibility, as well as the temperature-dependent, low-field DC magnetization confirm a cooperative spin-glass state of strongly interacting spins. This is supported by complementary 2 spectroscopic analysis (HAADF-STEM, EDS, EELS) as well as by a structural investigation (high-resolution TEM, X-ray and neutron powder diffraction) that yield insights into the chemical and atomic structure modifications. We conclude that the spin-glass state in birnessite is driven by the spin-frustration imposed by the underlying triangular lattice topology that is further enhanced by the in-plane bond-disorder generated by the mixed-valent character of manganese in the layers.

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Spin-glass-like behavior of Ge:Mn

Cited by 83 publications

References 42 publications

Magnetic Nature of a Ni Dopant in La_1.85Sr_0.15CuO₄: Spin-Glass Behavior

Magnetic Nature of a Ni Dopant in La_1.85Sr_0.15CuO₄: Spin-Glass Behavior

Diffuse x-ray scattering from inclusions in ferromagneticGe1−xMnxlayers

Hydration-induced spin-glass state in a frustrated Na-Mn-O triangular lattice

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Spin-glass-like behavior of Ge:Mn

Cited by 83 publications

References 42 publications

Magnetic Nature of a Ni Dopant in La1.85Sr0.15CuO4: Spin-Glass Behavior

Magnetic Nature of a Ni Dopant in La1.85Sr0.15CuO4: Spin-Glass Behavior

Diffuse x-ray scattering from inclusions in ferromagneticGe1−xMnxlayers

Hydration-induced spin-glass state in a frustrated Na-Mn-O triangular lattice

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Magnetic Nature of a Ni Dopant in La_1.85Sr_0.15CuO₄: Spin-Glass Behavior

Magnetic Nature of a Ni Dopant in La_1.85Sr_0.15CuO₄: Spin-Glass Behavior