Low field vortex dynamics over seven time decades in a Bi2Sr2CaCu2O8+δ single crystal for temperatures 13 K < T < 83 K

Abstract

Using a custom made dc-SQUID magnetometer, we have measured the time relaxation of the remanent magnetization Mrem of a Bi2Sr2CaCu2O8+δ single crystal from the fully critical state for temperatures 13 K < T < 83 K. The measurements cover a time window of seven decades 10-2 s < t < 105 s, so that the current density j can be studied from values very close to jc down to values considerably smaller than jc. From the data we have obtained: (i) the flux creep activation barriers U as a function of current density j, (ii) the current-voltage characteristics E(j) in a typical range of 10-7 V/cm to 10-15 V/cm, and (iii) the critical current density jc(0) at T = 0. Three different regimes of vortex dynamics are observed: For temperatures T < 20 K the activation barrier U(j) is logarithmic, no unique functional dependence U(j) could be found for the intermediate temperature interval 20 K < T < 40 K, and finally for T > 40 K the activation barrier U(j) follows a power-law behavior with an exponent mu = 0.6. From the analysis of the data within the weak collective pinning theory for strongly layered superconductors, it is argued that for temperatures T < 20 K pancake-vortices are pinned individually, while for temperatures T > 40 K pinning involves large collectively pinned vortex bundles. A description of the vortex dynamics in the intermediate temperature interval 20 K < T < 40 K is given on the basis of a qualitative low field phase diagram of the vortex state in Bi2Sr2CaCu2O8+δ. Within this description a second peak in the magnetization loop should occur for temperatures between 20 K and 40 K, as it has been observed in several magnetization measurements in the literature.

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