Flux melting in BSCCO: Incorporating both electromagnetic and Josephson couplings

Abstract

Multilevel Monte Carlo simulations of a BSCCO system are carried out including both Josephson as well as electromagnetic couplings for a range of anisotropies. A first order melting transition of the flux lattice is seen on increasing the temperature and/or the magnetic field. The phase diagram for BSCCO is obtained for different values of the anisotropy parameter γ. The best fit to the experimental results of D. Majer et al. [Phys. Rev. Lett. 75, 1166 (1995)] is obtained for γ≈ 250 provided one assumes a temperature dependence λ2(0)/λ2(T)=1-t of the penetration depth with t=T/Tc. Assuming a dependence λ2(0)/λ2(T)=1-t2 the best fit is obtained for γ≈ 450. For finite anisotropy the data is shown to collapse on a straight line when plotted in dimensionless units which shows that the melting transition can be satisfied with a single Lindemann parameter whose value is about 0.3. A different scaling applies to the γ=∞ case. The energy jump is measured across the transition and for large values of γ it is found to increase with increasing anisotropy and to decrease with increasing magnetic field. For infinite anisotropy we see a 2D behavior of flux droplets with a transition taking place at a temperature independent of the magnetic field. We also show that for smaller values of anisotropy it is reasonable to replace the electromagnetic coupling with an in-plane interaction represented by a Bessel function of the second kind (K0), thus justifying our claim in a previous paper.

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