Velocity-force characteristics of a driven interface in a disordered medium

Müller, Markus; Gorokhov, D. A.; Blatter, G.

doi:10.1103/physrevb.63.184305

Cited by 36 publications

(40 citation statements)

References 31 publications

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“…Figure 3(a) shows several v(H) curves measured at different temperatures in the range 100 K to 300K. The typical collective pinning behavior of a 1D wall propagating in a 2D disordered medium [21] is given by the creep law…”

Section: T(k)mentioning

confidence: 99%

Interplay between collective pinning and artificial defects on domain wall propagation in Co/Pt multilayers

Rodríguez-Rodríguez¹,

Menéndez²,

Hierro-Rodríguez³

et al. 2010

J. Phys. D: Appl. Phys.

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Abstract.The interplay between collective pinning on intrinsic structural defects and artificial pinning at a patterned hole is studied in magnetic multilayers with perpendicular anisotropy. The pinning strength of a patterned hole is measured through its efficiency to stop domain wall propagation into a consecutive unpatterned nanowire section (using antisymmetric magnetoresistance to detect the direction of domain wall propagation) whereas collective pinning is characterized by the field dependence of domain wall velocity. Close to room temperature, collective pinning becomes weaker than artificial pinning so that pinning at the hole compensates nucleation-pad geometry, blocking domain wall propagation across the nanowire.

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Section: T(k)mentioning

confidence: 99%

Interplay between collective pinning and artificial defects on domain wall propagation in Co/Pt multilayers

Rodríguez-Rodríguez¹,

Menéndez²,

Hierro-Rodríguez³

et al. 2010

J. Phys. D: Appl. Phys.

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“…Also, the typical barriers separating adjacent valleys are reduced by thermal fluctuations leading to a peculiar form of the creep-type dynamics under a small external force. 11 Below we first discuss some general properties of vortex pinning in disordered type-II superconductors and derive the asymptotic form ͑3͒ of the correlator. Second, we calculate the pinning length L c (T) using the functional renormalization-group ͑FRG͒ approach.…”

Section: ͑2͒mentioning

confidence: 99%

“…Furthermore, since we want to study high temperatures, we choose the roughness exponent to take the thermal value ϭ th ϭ1/2 which is convenient since the physics appears more transparently in the sequel, in particular, the temperature does not renormalize when ϭ th and T l ϭT ͑however, note that from a mathematical point of view the physical results below are independent of this particular choice of ). The linearized flow equation can be solved explicitly 11 with the result…”

Section: ͑2͒mentioning

confidence: 99%

Marginal pinning of vortices at high temperature

2001

Self Cite

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We analyze the competition between thermal fluctuations and pinning of vortices in bulk type II superconductors subject to point-like disorder and derive an expression for the temperature dependence of the pinning length L_c(T) which separates different types of single vortex wandering. Given a disorder potential with a basic scale \xi and a correlator K_0(u) \sim K_0 (u/xi)^{-\beta} ln^alpha (u/xi) we determine the dependence of L_c(T) on the correlator range: correlators with \beta > 2 (short-range) and \beta <2 (long-range) lead to the known results L_c(T) \sim L_c(0) exp[C T^3] and L_c(T) \sim L_c(0) (C T)^{(4+beta)/(2-beta)}, respectively. Using functional renormalization group we show that for \beta =2 the result takes the interpolating form L_c(T) \sim L_c(0) exp[C T^{3/(2+alpha)}]. Pinning of vortices in bulk type II superconductors involves a long-range correlator with \beta=2, \alpha=1 on intermediate scales \xi

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“…It is observed in our simulations that the system with weak bare pinning strength experiences smaller energy barriers compared with that of strong bare pinning strength, even at the same relative force-deviation from the critical values; an analytic derivation of the effective energy barrier, however, is not an easy task [12]. While a full picture remains to be developed, we notice that, first, vortex motions mimic nucleation processes in first-order phase transitions: the weak (strong) pinning case corresponds to system located at the spinodal (coexistence) curve [31]; second, under weak and strong pinning, vortices behave similarly to CDW [22] and domain wall [27] respectively, due to the different ranges of correlation.…”

mentioning

confidence: 97%

Depinning and Creep Motion in Glass States of Flux Lines

Luo

2007

Phys. Rev. Lett.

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Using dynamical computer simulation, we investigate vortex matter in glass states. A genuine continuous depinning transition is observed at zero temperature, which also governs the low-temperature creep motion. With the notion of scaling, we evaluate in high accuracy critical exponents and scaling functions; we observe a non-Arrhenius creep motion for weak collective pinning where the Bragg glass is stabilized at equilibrium, while for strong pinning, the well-known Arrhenius law is recovered. In both cases, a sharp crossover takes place between depinning and creep at low temperatures.

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Velocity-force characteristics of a driven interface in a disordered medium

Cited by 36 publications

References 31 publications

Interplay between collective pinning and artificial defects on domain wall propagation in Co/Pt multilayers

Interplay between collective pinning and artificial defects on domain wall propagation in Co/Pt multilayers

Marginal pinning of vortices at high temperature

Depinning and Creep Motion in Glass States of Flux Lines

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