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

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

The Landauer principle states that at least k_{B}Tln2 of energy is required to erase a 1-bit memory, with k_{B}T 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 creat...

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Veröffentlicht in:Physical review letters 2021-04, Vol.126 (17), p.170601-170601, Article 170601
Hauptverfasser: Dago, Salambô, Pereda, Jorge, Barros, Nicolas, Ciliberto, Sergio, Bellon, Ludovic
Format: Artikel
Sprache:eng
Schlagworte:
Feedback loops
Potential barriers
Thermal energy
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Zusammenfassung:The Landauer principle states that at least k_{B}Tln2 of energy is required to erase a 1-bit memory, with k_{B}T 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 k_{B}T 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.
ISSN:0031-9007
1079-7114
DOI:10.1103/physrevlett.126.170601