https://www.sciencedaily.com/releases/2023/07/230713141937.htm

Devices that allow to route signals, for example carried by light or sound waves, are essential in many practical situations. This is, for instance, the case in quantum information processing, where the states of the quantum computer have to be amplified to read them out -- without noise from the amplification process corrupting them. That is why devices that allow signals to travel in a one-way channel e.g. isolators or circulators are much sought-after. However, at present such devices are lossy, bulky, and require large magnetic fields that break time-reversal symmetry to achieve unidirectional behaviour. These limitations have prompted strong efforts to find alternatives that take less space and that do not rely on magnetic fields.

The new study published in Nature Physics introduces a new class of systems characterized by a phenomenon the authors call "quadrature nonreciprocity." Quadrature nonreciprocity exploits interference between two distinct physical processes. Each of the processes produces a wave that contributes to the transmitted signal. Like water waves produced by two thrown pebbles, the two waves can either cancel or amplify each other, in a phenomenon known as interference.