Coherent excitation transport through ring-shaped networks
- URL: http://arxiv.org/abs/2310.17967v2
- Date: Thu, 18 Jan 2024 06:00:24 GMT
- Title: Coherent excitation transport through ring-shaped networks
- Authors: Francesco Perciavalle, Oliver Morsch, Davide Rossini, Luigi Amico
- Abstract summary: coherent quantum transport of matter wave through a ring-shaped circuit attached to leads defines an iconic system in mesoscopic physics.
We study the source-to-drain transport of excitations going through a ring-network, without propagation of matter waves.
- Score: 0.0
- License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
- Abstract: The coherent quantum transport of matter wave through a ring-shaped circuit
attached to leads defines an iconic system in mesoscopic physics that has
allowed both to explore fundamental questions in quantum science and to draw
important avenues for conceiving devices of practical use.
Here we study the source-to-drain transport of excitations going through a
ring-network, without propagation of matter waves. We model the circuit in
terms of a spin system with specific long-range interactions that are relevant
for quantum technology, such as Rydberg atoms trapped in optical tweezers or
ion traps. Inspired by the logic of rf- and dc-SQUIDs, we consider rings with
one and two local energy offsets, or detunings. As a combination of specific
phase shifts in going though the localized detunings and as a result of
coherent tunneling, we demonstrate how the transport of excitations can be
controlled, with a distinctive dependence on the range of interactions.
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