Information and Thermodynamics: Fast and Precise Approach to Landauer's Bound in an Underdamped Micromechanical Oscillator

Salambo Dago; Jorge Pereda; Nicolas Barros; Sergio Ciliberto; Ludovic Bellon

doi:10.1103/PhysRevLett.126.170601

Information and Thermodynamics: Fast and Precise Approach to Landauer's Bound in an Underdamped Micromechanical Oscillator

Salambo Dago
, Jorge Pereda
, Nicolas Barros
, Sergio Ciliberto
, Ludovic Bellon

Ecole Normale Supérieure de Lyon

Résultats de recherche: Contribution à un journal › Article › Revue par des pairs

Résumé

The Landauer principle states that at least kBTln2 of energy is required to erase a 1-bit memory, with kBT the thermal energy of the system. We study the effects of inertia on this bound using as one-bit memory an underdamped micromechanical oscillator confined in a double-well potential created by a feedback loop. The potential barrier is precisely tunable in the few kBT range. We measure, within the stochastic thermodynamic framework, the work and the heat of the erasure protocol. We demonstrate experimentally and theoretically that, in this underdamped system, the Landauer bound is reached with a 1% uncertainty, with protocols as short as 100 ms.

langue originale	Anglais
Numéro d'article	170601
journal	Physical Review Letters
Volume	126
Numéro de publication	17
Les DOIs	https://doi.org/10.1103/PhysRevLett.126.170601
état	Publié - 27 avr. 2021
Modification externe	Oui

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10.1103/PhysRevLett.126.170601

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abstract = "The Landauer principle states that at least kBTln2 of energy is required to erase a 1-bit memory, with kBT the thermal energy of the system. We study the effects of inertia on this bound using as one-bit memory an underdamped micromechanical oscillator confined in a double-well potential created by a feedback loop. The potential barrier is precisely tunable in the few kBT range. We measure, within the stochastic thermodynamic framework, the work and the heat of the erasure protocol. We demonstrate experimentally and theoretically that, in this underdamped system, the Landauer bound is reached with a 1\% uncertainty, with protocols as short as 100 ms.",

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AU - Ciliberto, Sergio

AU - Bellon, Ludovic

PY - 2021/4/27

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AB - The Landauer principle states that at least kBTln2 of energy is required to erase a 1-bit memory, with kBT the thermal energy of the system. We study the effects of inertia on this bound using as one-bit memory an underdamped micromechanical oscillator confined in a double-well potential created by a feedback loop. The potential barrier is precisely tunable in the few kBT range. We measure, within the stochastic thermodynamic framework, the work and the heat of the erasure protocol. We demonstrate experimentally and theoretically that, in this underdamped system, the Landauer bound is reached with a 1% uncertainty, with protocols as short as 100 ms.

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ER -

Information and Thermodynamics: Fast and Precise Approach to Landauer's Bound in an Underdamped Micromechanical Oscillator

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