Stabilization of in-phase fluxon state by geometrical confinement in small Bi-2212 mesa structures

TL;DR

This study demonstrates that geometrical confinement in small Bi-2212 mesa structures stabilizes the in-phase fluxon state, which is essential for coherent THz emission, by experimentally showing changes in fluxon lattice periodicity.

Contribution

The paper provides experimental evidence that reducing the size of Bi-2212 mesas stabilizes the in-phase fluxon lattice, overcoming its natural instability in larger structures.

Findings

In-phase fluxon state is stabilized in small mesas.

Periodic fluxon lattice changes with size and magnetic field.

Geometrical confinement effectively stabilizes the in-phase fluxon lattice.

Abstract

The in-phase (rectangular) fluxon lattice is required for achieving coherent THz emission from stacked Josephson junctions. Unfortunately, it is usually unstable due to mutual repulsion of fluxons in neighbor junctions, which favors the out-of-phase (triangular) lattice. Here we experimentally study magnetic field modulation of the critical current in small Bi-2212 mesa structures with different sizes. A clear Fraunhofer-like modulation is observed when the field is aligned strictly parallel to superconducting CuO planes. For long mesas the periodicity of modulation is equal to half the flux quantum per intrinsic Josephson junction, corresponding to the triangular fluxon lattice. However, the periodicity is changed to one flux quantum, characteristic to the rectangular fluxon lattice, both by decreasing the length of the mesas and by increasing magnetic field. Thus, we demonstrate that the stationary in-phase fluxon state can be effectively stabilized by geometrical confinement in small Bi-2212 mesa structures.