Scientists Compare Throughput for Quantum vs. Conventional Networks
A comparison of throughput measurements and analytical capacity estimates for quantum networks finds surprising patterns.
A comparison of throughput measurements and analytical capacity estimates for quantum networks finds surprising patterns.
New theoretical approach to quantum computing hardware design via an algorithm avoids some of the complex difficulties in modern quantum computers.
Researchers extend findable, accessible, interoperable, and reusable principles for datasets to scientific datasets and software.
Classical and quantum chips combine to simulate the collision of two neutrons on a present-day quantum computer.
Fluxonium qubits can build cutting-edge quantum devices that will harness the potential of quantum computing.
FAIR (findable, accessible, interoperable, reusable) principles facilitate the use of large data sets by human and machine researchers.
Machine learning and artificial intelligence accelerate nanomaterials investigations.
New computational methods “fingerprint” polymer motions under flow.
Scientists successfully measure high-dimensional qudits, cousins to quantum computing qubits.
Researchers demonstrate a real-world large-scale application of deep neural network models for discovering novel protein-protein interactions.
Researchers develop the first 2D telecommunication-compatible quantum light source, smoothing the path toward a quantum internet.
Long predicted by theory with support from supercomputers, this combination of neutrons advances nuclear physics