Scientists used antimony atoms to improve quantum computing by making qubits more stable, like a quantum cat, and ...

"A superposition of the antimony spin pointing in opposite directions is not just a superposition of 'up' and 'down,' because there are multiple quantum states separating the two branches of the ...

A superposition of the antimony spin pointing in opposite directions is not just a superposition of 'up' and 'down', because there are multiple quantum states separating the two branches of the ...

Engineers at the University of New South Wales (UNSW) achieved a milestone in quantum computing by demonstrating Schrödinger's famous thought experiment using an antimony atom.

The Swiss startup has found a way to allow qubits to move in all spatial directions like an aeroplane, instead of like cars ...

Quantum computers rely on a quirk of physics ... This is the sense in which the superposition of antimony spin states in opposite directions is 'macroscopic'—because it's happening on a larger ...

A quantum bit, the smallest unit of a quantum computer, uses a 'superposition of different states' of the quantum spin direction to simultaneously take on the values '0' and '1.' While a normal ...

The current could flow in either direction (called the spin), and as it is a quantum particle, it could be in a superposition of the two directions. D-Wave applies magnetic fields to the qubit ...

Scientists trapped ultra-cold molecules, improving quantum computing with better stability, accuracy, and computational ...

Related: Quantum ... superposition of states, simultaneously dead and alive. In the case of a qubit, quantum information relating to the 0 or 1 states of a classical computer can be encoded on the ...