Physical consequences of gauge optimization in quantum open systems evolutions
- URL: http://arxiv.org/abs/2407.02590v1
- Date: Tue, 2 Jul 2024 18:22:11 GMT
- Title: Physical consequences of gauge optimization in quantum open systems evolutions
- Authors: Yohan Vianna de Almeida, Fernando Nicacio, Marcelo F. Santos,
- Abstract summary: We show that gauge transformations can be exploited, on their own, to optimize practical physical tasks.
First, we describe the inherent structure of the underlying symmetries in quantum Markovian dynamics.
We then analyze examples of optimization in quantum thermodynamics.
- Score: 44.99833362998488
- License: http://creativecommons.org/licenses/by-nc-nd/4.0/
- Abstract: On its own, the invariance by gauge transformations of Markovian master equations has mostly played a mathematical or computational role in the evaluation of quantum open system dynamics. So far, the fixation of a particular gauge has only gained physical meaning when correlated with additional information such as the results of measurements carried on over the system or the environment in so-called quantum trajectories. Here, we show that gauge transformations can be exploited, on their own, to optimize practical physical tasks. To do so, first, we describe the inherent structure of the underlying symmetries in quantum Markovian dynamics and present a general formulation showing how they can be used to change the measurable values of physical quantities. We then analyze examples of optimization in quantum thermodynamics and, finally, we discuss the practical implementation of the optimized protocols in terms of quantum trajectories.
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