Abstract
Realistic models of quantum systems must include dissipative interactions with a thermal environment. For weakly-damped systems, while the Lindblad-form Markovian master equation is invaluable for this task, it applies only when the frequencies of any subset of the system’s transitions are degenerate, or their differences are much greater than the transitions’ linewidths. Outside of these regimes the only available efficient description has been the Bloch–Redfield master equation, the efficacy of which has long been controversial due to its failure to guarantee the positivity of the density matrix. The ability to efficiently simulate weakly-damped systems across all regimes is becoming increasingly important, especially in quantum technologies. Here we solve this long-standing problem by deriving a Lindblad-form master equation for weakly-damped systems that is accurate for all regimes. We further show that when this master equation breaks down, so do all time-independent Markovian equations, including the B-R equation. We thus obtain a replacement for the B-R equation for thermal damping that is no less accurate, simpler in structure, completely positive, allows simulation by efficient quantum trajectory methods, and unifies the previous Lindblad master equations. We also show via exact simulations that the new master equation can describe systems in which slowly-varying transition frequencies cross each other during the evolution. System identification tools, developed in systems engineering, play an important role in our analysis. We expect these tools to prove useful in other areas of physics involving complex systems.
Highlights
Damped open systems are important across a wide range of areas in both physics and chemistry, from quantum thermodynamics[1,2,3] to the control of chemical reactions[4], to quantum technologies[5,6,7,8,9,10,11,12]
Aided by the form obtained in step one, we show how to derive the new Lindblad master equation from the Bloch–Redfield equation valid for all regimes perform System identification (SID) on the V system depicted in Fig. 1a with bath cut-off frequency Ω 1⁄4 80πν~, fix the mean transition frequency ω ðω[1] þ ω2Þ=2 1⁄4 3πν~, and choose the coupling constants g1 and g2 (defined in Eq (10)) so as to give the decay rates γ1 1⁄4 0:1ν~ and γ2 1⁄4 0:05ν~
We have shown that when the spectral density is sufficiently flat the B–R equation for thermal damping can be replaced by a Lindblad equation, and that this is an excellent approximation for the Ohmic bath
Summary
Damped open systems are important across a wide range of areas in both physics and chemistry, from quantum thermodynamics[1,2,3] to the control of chemical reactions[4], to quantum technologies[5,6,7,8,9,10,11,12]. We use exact simulations of a V system coupled to an Ohmic bath, together with the method of system identification, developed in systems engineering, to show that weakly-damped quantum systems with an Ohmic spectrum are Markovian and time-independent across all three regimes This method allows us to directly back-out the Lindblad-form equation of motion for this V system. Aided by the form obtained in step one, we show how to derive the new Lindblad master equation from the Bloch–Redfield equation valid for all regimes perform SID on the V system depicted in Fig. 1a with bath cut-off frequency Ω 1⁄4 80πν~ (we give the details of the bath model when we derive the master equation below), fix the mean transition frequency ω ðω[1] þ ω2Þ=2 1⁄4 3πν~, and choose the coupling constants g1 and g2 (defined in Eq (10)) so as to give the decay rates γ1 1⁄4 0:1ν~ and γ2 1⁄4 0:05ν~. Because we have fixed ω while changing the detuning, and since γj ∝ ωj for the Ohmic spectral density, when the detuning npj Quantum Information (2020) 74
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