Temperature fluctuations of a finite system follow the Landau bound δT 2 = T 2/C(T ) where C(T ) is the heat capacity of the system. In turn, the same bound sets a limit to the precision of temperature estimation when the system itself is used as a thermometer. In this paper, we employ graph theory and the concept of Fisher information to assess the role of topology on the thermometric performance of a given system. We find that low connectivity is a resource to build precise thermometers working at low temperatures, whereas highly connected systems are suitable for higher temperatures. Upon modeling the thermometer as a set of vertices for the quantum walk of an excitation, we compare the precision achievable by position measurement to the optimal one, which itself corresponds to energy measurement.
Role of topology in determining the precision of a finite thermometer / Candeloro, Alessandro; Razzoli, Luca; Bordone, Paolo; Paris, Matteo G. A.. - In: PHYSICAL REVIEW. E. - ISSN 2470-0045. - 104:1(2021), pp. 014136-1-014136-14. [10.1103/PhysRevE.104.014136]
Role of topology in determining the precision of a finite thermometer
Luca Razzoli;Paolo Bordone;
2021
Abstract
Temperature fluctuations of a finite system follow the Landau bound δT 2 = T 2/C(T ) where C(T ) is the heat capacity of the system. In turn, the same bound sets a limit to the precision of temperature estimation when the system itself is used as a thermometer. In this paper, we employ graph theory and the concept of Fisher information to assess the role of topology on the thermometric performance of a given system. We find that low connectivity is a resource to build precise thermometers working at low temperatures, whereas highly connected systems are suitable for higher temperatures. Upon modeling the thermometer as a set of vertices for the quantum walk of an excitation, we compare the precision achievable by position measurement to the optimal one, which itself corresponds to energy measurement.
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