8 research outputs found
Mixed superconducting state without applied magnetic field
A superconducting (SC) mixed state occurs in type-II superconductors where
the upper critical field Hc2 is higher than the thermodynamic critical field
Hc. When an applied field is in between these fields, the free energy depends
weakly on the order parameter which therefore can be small (SC state) or zero
(normal state) at different parts of the sample. In this paper we demonstrate
how a normal state along a line traversing a superconductor can be turned on
and off externally in zero field. The concept is based on a long,
current-carrying excitation coil, piercing a ringshaped superconductor. The
ring experiences zero field, but the vector potential produced by the coil
generates a circular current that destroys superconductivity along a radial
line starting at preexisting nucleation points in the sample. Unlike the
destruction of superconductivity with magnetic field, the vector potential
method is reversible and reproducible; full superconductivity is recovered upon
removing the current from the coil, and different cooldowns yield the same
normal lines. We suggest potential applications of this magnetic-field-free
mixed state.Comment: 5 pages, 7 figure
Mechanical Control of Individual Superconducting Vortices
Manipulating
individual vortices in a deterministic way
is challenging; ideally, manipulation should be effective, local,
and tunable in strength and location. Here, we show that vortices
respond to local mechanical stress applied in the vicinity of the
vortex. We utilized this interaction to move individual vortices in
thin superconducting films via local mechanical contact without magnetic
field or current. We used a scanning superconducting quantum interference
device to image vortices and to apply local vertical stress with the
tip of our sensor. Vortices were attracted to the contact point, relocated,
and were stable at their new location. We show that vortices move
only after contact and that more effective manipulation is achieved
with stronger force and longer contact time. Mechanical manipulation
of vortices provides a local view of the interaction between strain
and nanomagnetic objects as well as controllable, effective, and reproducible
manipulation technique