Quantum dynamics of a single fluxon in Josephson-junction parallel arrays with large kinetic inductances

We present a theoretical study of coherent quantum dynamics of a single magnetic fluxon (MF) trapped in Josephson-junction parallel arrays (JJPAs) with large kinetic inductances. The MF is the topological excitation carrying one quantum of magnetic flux, Phi(0). The MF is quantitatively described as the 2 pi kink in the distribution of Josephson phases, and for JJPAs with high kinetic inductances the characteristic length of such distribution (the size of MF) is drastically reduced. Characterizing such MFs by the Josephson phases of three consecutive Josephson junctions we analyze the various coherent macroscopic quantum effects in the MF quantum dynamics. In particular, we obtain the MF energy band originating from the coherent quantum tunneling of a single MF between adjacent cells of JJPAs. The dependencies of the band width Delta on the Josephson coupling energy E-J, charging energy E-C and the inductive energy of a cell E-L, are studied in detail. In long linear JJPAs the coherent quantum dynamics of MF demonstrates decaying quantum oscillations with characteristic frequency f(qb) = Delta/h. In short annular JJPAs the coherent quantum dynamics of MF displays complex oscillations controlled by the Aharonov-Casher phase chi proportional to V-g, where V-g is an externally applied gate voltage. In the presence of externally applied dc bias, I, a weakly incoherent dynamics of quantum MF is realized in the form of macroscopic Bloch oscillations leading to a typical nose current-voltage characteristics of JJPAs. As ac current with frequency f is applied the current-voltage characteristics display a set of equidistant current steps at I-n = 2enf.

Automated summary

This theoretical study examines the coherent quantum dynamics of a single magnetic fluxon trapped in Josephson-junction parallel arrays with large kinetic inductances. The dynamics of the magnetic fluxon are analyzed in detail, including energy bands, quantum tunneling, and oscillations controlled by external factors like voltage and bias current. The study shows how these quantum effects manifest in the current-voltage characteristics of the arrays.