We implement a thermal-fluctuation-driven logical bit reset on a superconducting flux logic cell. We show that the logical state of the system can be continuously monitored with only a small perturbation to the thermally activated dynamics at 500 mK. We use the trajectory information to derive a single-shot estimate of the work performed on the system per logical cycle. We acquire a sample of 105 erasure trajectories per protocol and show that the work histograms agree with both microscopic theory and global fluctuation theorems. The results demonstrate how to design and diagnose complex, high-speed, and thermodynamically efficient computing using superconducting technology
Landauer's principle states that it costs at least kBTln2 of work to reset one bit in the presence o...
Here we use superconducting circuits as components for quantum computing and as model systems for no...
Reversible computing has been studied since Rolf Landauer advanced the argument that has come to be ...
We implement a thermal-fluctuation-driven logical bit reset on a superconducting flux logic cell. We...
We experimentally demonstrate that highly structured distributions of work emerge during even the si...
We experimentally demonstrate that highly structured distributions of work emerge during even the si...
We propose a superconducting thermal memory device that exploits the thermal hysteresis in a flux-co...
Landauer's principle states that information erasure requires heat dissipation. While Landauer's ori...
International audienceUsing a double-well potential as a physical memory, we study with experiments ...
Funding Information: The work is supported by the Foundation for Polish Science project “Stochastic ...
The amplitude-damping time T_{1} has long stood as the major factor limiting quantum fidelity in sup...
Landauer's Principle states that the energy cost of information processing must exceed the product o...
Boolean algebra, the branch of mathematics in which variables can assume only true or false values, ...
Superconducting quantum circuits (SQCs) are being explored as model systems for scalable quantum com...
Time-dependent protocols that perform irreversible logical operations, such as memory erasure, cost ...
Landauer's principle states that it costs at least kBTln2 of work to reset one bit in the presence o...
Here we use superconducting circuits as components for quantum computing and as model systems for no...
Reversible computing has been studied since Rolf Landauer advanced the argument that has come to be ...
We implement a thermal-fluctuation-driven logical bit reset on a superconducting flux logic cell. We...
We experimentally demonstrate that highly structured distributions of work emerge during even the si...
We experimentally demonstrate that highly structured distributions of work emerge during even the si...
We propose a superconducting thermal memory device that exploits the thermal hysteresis in a flux-co...
Landauer's principle states that information erasure requires heat dissipation. While Landauer's ori...
International audienceUsing a double-well potential as a physical memory, we study with experiments ...
Funding Information: The work is supported by the Foundation for Polish Science project “Stochastic ...
The amplitude-damping time T_{1} has long stood as the major factor limiting quantum fidelity in sup...
Landauer's Principle states that the energy cost of information processing must exceed the product o...
Boolean algebra, the branch of mathematics in which variables can assume only true or false values, ...
Superconducting quantum circuits (SQCs) are being explored as model systems for scalable quantum com...
Time-dependent protocols that perform irreversible logical operations, such as memory erasure, cost ...
Landauer's principle states that it costs at least kBTln2 of work to reset one bit in the presence o...
Here we use superconducting circuits as components for quantum computing and as model systems for no...
Reversible computing has been studied since Rolf Landauer advanced the argument that has come to be ...