Electrical transport, magnetic, and structural properties of the vortex lattice of V 3 Si in the vicinity of the peak effect

The peak effect in critical current density ${J}_{c}$ is investigated by studying the flux dynamics in ${\mathrm{V}}_{3}\mathrm{Si}$ using bulk magnetometry, small-angle neutron scattering, and transport measurements on clean single-crystal samples from the same ingot. For a field-cooled history, well-defined structure in the vortex lattice was found for fields and temperatures (H,T) below the peak-effect line ${H}_{P}(T);$ above this line, the structure disappeared. History-dependent, metastable disorder is found only for (H,T) below ${H}_{P}(T)$ but the vortex system is reproducibly re-ordered either by field cooling or a low-frequency, pulsed ``shaking'' transport current. The latter is shown to attain Bardeen-Stephen flux flow. In addition, flux flow is observed at ${H}_{P}(T)$ at high current levels. The results support the traditional picture of ${H}_{P}(T)$ as an order-disorder transition due to the competition between elasticity and pinning.