A novel phase of matter has been achieved by researchers, finally realizing a theoretical quantum prediction using nanoscale ...

Building useful quantum technologies—from sensors to computers—requires generating highly complex entangled states, in which ...

Quantum computers, systems that process information leveraging quantum mechanical effects, have the potential of ...

Accelerate the future of technology by studying one of the world’s most cutting-edge fields: quantum information science and engineering (QISE). This exciting discipline is at the forefront of today’s ...

Application discovery, algorithms, error correction, resource estimation, hardware execution, and classical components are ...

This Collection supports and amplifies research related to SDG 8 and SDG 9. This year marks the centennial celebration of the initial development of quantum mechanics, a milestone that has profoundly ...

The ability to send quantum information securely, known as quantum key distribution, is one of the most practical (if difficult) applications of quantum science. A new study demonstrates the ...

A team at the University of Chicago has discovered a surprisingly simple way to create powerful quantum states that are normally difficult to produce. By making small adjustments to the energy levels ...

This review examines how nanotechnology, topological materials, Majorana fermions, Weyl semimetals, and quantum simulation ...

Florida State University physicists are part of a team that has discovered unusual superconducting states in parts of graphene, with the potential to drive unexpected quantum technologies.

Quantum Science and Engineering is the study and application of the principles of quantum mechanics (such as superposition and entanglement) to develop new technologies that surpass the limits of ...