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.
New lattice simulations compute the spin and density correlations in neutron matter that affect neutrino heating during core-collapse supernovae.
New theory-based approach gives access to quarks’ tiny transverse motion within protons.
Copper catalysts play an unexpected oxidizing role during unassisted photocatalysis when coupled with plasmonic light absorbers.
Ultrafast electron scattering measurements reveal dynamic reconfiguration of polarization in relaxor ferroelectrics by light.
Researchers open a new avenue for future brain-inspired computer hardware.
Robotic stacking of 2D layers provides the atomically clean interfaces critical for high performance assembled materials.
Researchers leveraged advanced X-ray imaging for a nondestructive way to peer inside complex 3D nanomaterials with record resolution.
By examining tiny fragments from one of our nearest cosmic neighbors, scientists uncovered more about the history of our solar system.
Scientists find evidence of superfluidity in low-density neutron matter by using highly flexible neural-network representations of quantum wave functions.
The first measurement of ion temperature in magnetic islands identified a steep gradient, providing insights for improving plasma confinement in tokamaks.