Quantum mechanics theory predicts that, in addition to exhibiting particle-like behavior, particles of all sizes can also ...

You've probably seen videos showing characters walking through walls like ghosts. Upon closer inspection, atoms consist of a ...

Experimental device harnesses quantum properties for efficient processing at room temperature. Engineers are working to ...

Amid the chaos of revolutionary France, one man’s mathematical obsession gave way to a calculation that now underpins much of ...

A survey of Scientific American’s century of quantum coverage helps explain the enduring popularity of strange physics ...

This paper presents and studies the expected bit error rate (BER) of a prepare-and-measure quantum key distribution (QKD) protocol utilizing two wavelengths, te ...

Most quantum computing companies point toward 2030 as the key year for quantum computing becoming a widely used technology, and both D-Wave and Rigetti are racing toward that goal.

A detailed understanding of the energetic and spatial properties of acceptor wave functions in silicon is essential for engineering large-scale acceptor-based quantum devices.

Scientists from Sweden and Finland have discovered a way to use magnetism to protect fragile qubits, potentially solving quantum computing’s greatest weakness. By engineering a new exotic material ...

Quantum-as-a-Service is making the revolutionary power of quantum computing accessible without the need for million-dollar hardware investments or specialized facilities.