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Realizing tight-binding Hamiltonians using site-controlled coupled cavity arrays

arXiv
Authors: Abhi Saxena, Arnab Manna, Rahul Trivedi, Arka Majumdar

Year

2022

Paper ID

58528

Status

Preprint

Abstract Read

~2 min

Abstract Words

103

Citations

N/A

Abstract

Analog quantum simulators rely on programmable quantum devices to emulate Hamiltonians describing various physical phenomenon. Photonic coupled cavity arrays are a promising platform for realizing such devices. Using a silicon photonic coupled cavity array made up of 8 high quality-factor resonators and equipped with specially designed thermo-optic island heaters for independent control of cavities, we demonstrate a programmable device implementing tight-binding Hamiltonians with access to the full eigen-energy spectrum. We report a 50% reduction in the thermal crosstalk between neighboring sites of the cavity array compared to traditional heaters, and then present a control scheme to program the cavity array to a given tight-binding Hamiltonian.

Why This Paper Matters

  • It adds a 2022 reference point for readers tracking recent quantum research.
  • Analog quantum simulators rely on programmable quantum devices to emulate Hamiltonians describing various physical phenomenon.

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