Quantum physics is no longer confined to cryogenic chips and vacuum chambers. It is starting to seep into the machinery of ...

Scientists are learning how to temporarily reshape materials by nudging their internal quantum rhythms instead of blasting them with extreme lasers. By harnessing excitons, short-lived energy pairs ...

In a world first, a research team led by the University of Oxford’s Department of Engineering Science has shown it is ...

A research team led by the University of Oxford's Department of Engineering Science has shown it is possible to engineer a ...

A new presidential initiative called QMIT will advance the development of quantum technologies—and help ensure that they are used for good.

Quantum engineering systems represent the convergence of quantum mechanics and engineering principles to design devices that exploit superposition, entanglement, and tunnelling for advanced ...

Quantum computing promises extraordinary power, but that same power may expose new security weaknesses. Quantum computers are expected to deliver dramatic gains in processing speed and capability, ...

Quantum computing holds the promise to revolutionize how we solve complex problems, but today’s devices still face steep challenges. At the heart of the issue lies reliability: current quantum bits—or ...

Building large-scale quantum technologies requires reliable ways to connect individual quantum bits (qubits) without ...

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 ...

Quantum computers promise unprecedented computing speed and power that will advance both business and science. These same ...