Failure of the geometric approach prediction of excess work scaling for open and isolated quantum systems

Abstract: The task of finding optimal protocols that minimize the energetic cost of thermodynamic processes of long yet finite duration $\tau$ is a pressing one. We approach this problem here in a rigorous and systematic fashion by means of the adiabatic perturbation theory of closed Hamiltonian quantum systems. Our main finding is a $1/\tau^2$ scaling of the excess work for large $\tau$ in gapped systems. This result is at odds with the asymptotic $1/\tau$ prediction of the geometric approach to optimization, which is … Show more

“…Other energy differences can be taken into account when building FQA protocols (see Ref. [63]), but the associated differential equation is not exactly solvable and hardly numerically solvable when traversing the QCP. Thus, to circumvent this issue, we apply a similar strategy known as uniform quasi-adiabatic (UQA) [64] to the lowest sub-level of the TI chain.…”

Shortcuts to Thermodynamic Quasistaticity

“…Other energy differences can be taken into account when building FQA protocols (see Ref. [63]), but the associated differential equation is not exactly solvable and hardly numerically solvable when traversing the QCP. Thus, to circumvent this issue, we apply a similar strategy known as uniform quasi-adiabatic (UQA) [64] to the lowest sub-level of the TI chain.…”

Shortcuts to Thermodynamic Quasistaticity

Nanowelding of quantum spin- 12 chains at minimal dissipation

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