Aharonov-Bohm Oscillations in a One-Dimensional Wigner Crystal-Ring
Abstract
We calculate the magnetic moment (`persistent current') in a strongly correlated electron system --- a Wigner crystal --- in a one-dimensional ballistic ring. The flux and temperature dependence of the persistent current in a perfect ring is shown to be essentially the same as for a system of non-interacting electrons. In contrast, by incorporating into the ring geometry a tunnel barrier that pins the Wigner crystal, the current is suppressed and its temperature dependence is drastically changed. The competition between two temperature effects --- the reduced barrier height for macroscopic tunneling and loss of quantum coherence --- may result in a sharp peak in the temperature dependence. The character of the macroscopic quantum tunneling of a Wigner crystal ring is dictated by the strength of pinning. At strong pinning the tunneling of a rigid Wigner crystal chain is highly inhomogeneous, and the persistent current has a well-defined peak at T 0.5\ s/L independent of the barrier height (s is the sound velocity of the Wigner crystal, L is the length of the ring). In the weak pinning regime, the Wigner crystal tunnels through the barrier as a whole and if Vp>T0 the effect of the barrier is to suppress the current amplitude and to shift the crossover temperature from T0 to T* VpT0. (Vp is the amplitude of the pinning potential, T0 = vF/L ,\; vF /ma is the drift velocity of a Wigner crystal ring with lattice spacing a). For very weak pinning, Vp T0, the influence of the barrier on the persistent current of a Wigner crystal ring is negligibly small.
Turn this paper into a full lesson
ArcXiv compiles a staged curriculum from this paper: 8-12 lessons across beginner → advanced, synthesised section guides, visuals, flashcards, a quiz, exercises, and on-demand deep dives per section. Grounded in the abstract, never invented.