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Quantum Synchronization in Nonconservative Electrical Circuits with Kirchhoff-Heisenberg Equations

Published 15 Mar 2024 in quant-ph and cond-mat.other | (2403.10474v1)

Abstract: We investigate quantum synchronization phenomena in electrical circuits that incorporate specifically designed nonconservative elements. A dissipative theory of classical and quantized electrical circuits is developed based on the Rayleigh dissipation function. The introduction of this framework enables the formulation of a generalized version of classical Poisson brackets, which are termed Poisson-Rayleigh brackets. By using these brackets, we are able to derive the equations of motion for a given circuit. Remarkably, these equations are found to correspond to Kirchhoff's current laws when Kirchhoff's voltage laws are employed to impose topological constraints, and vice versa. In the quantum setting, the equations of motion are referred to as the Kirchhoff-Heisenberg equations, as they represent Kirchhoff's laws within the Heisenberg picture. These Kirchhoff-Heisenberg equations, serving as the native equations for an electrical circuit, can be used in place of the more abstract master equations in Lindblad form. To validate our theoretical framework, we examine three distinct circuits. The first circuit consists of two resonators coupled via a nonconservative element. The second circuit extends the first to incorporate weakly nonlinear resonators, such as transmons. Lastly, we investigate a circuit involving two resonators connected through an inductor in series with a resistor. This last circuit, which incidentally represents a realistic implementation, allows for the study of a singular system, where the absence of a coordinate leads to an ill-defined system of Hamilton's equations. To analyze such a pathological circuit, we introduce the concept of auxiliary circuit element. After resolving the singularity, we demonstrate that this element can be effectively eliminated at the conclusion of the analysis, recuperating the original circuit.

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  8. For this simple circuit’s topology, N−1𝑁1N-1italic_N - 1 is equal to the circuit’s degrees of freedom.
  9. If we were to use KCL constraints (in which case the EOMs would be KVL equations), then the capacitance matrix would be diagonal and trivially solvable.
  10. The amount of spacing can be adjusted by introducing meanders in the strip.
  11. This is especially noticeable when L23≫L1,L3much-greater-thansubscript𝐿23subscript𝐿1subscript𝐿3L_{23}\gg L_{1},L_{3}italic_L start_POSTSUBSCRIPT 23 end_POSTSUBSCRIPT ≫ italic_L start_POSTSUBSCRIPT 1 end_POSTSUBSCRIPT , italic_L start_POSTSUBSCRIPT 3 end_POSTSUBSCRIPT.
  12. It should be noted that the chosen quality factor is intentionally lower than the state-of-the-art value of approximately a million [20], allowing for experimental flexibility.
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