Interference-based universal decoupling and swapping for multimode bosonic systems.

A key requirement for bosonic quantum information processing is the ability to control interactions between desired modes of the system. In practical devices, however, this is often difficult to realize due to the presence of undesired coupling to additional modes. In this work, we develop interference-based protocols for decoupling and swapping selected modes of a multimode bosonic system. Specifically, for a generic coupler characterized by Gaussian unitary process, we show how to decouple a single mode or swap any pair of modes with a constant depth sequence of operations, while maintaining the coupling for the remaining system. These protocols require only multiple uses of the same coupler interleaved with single-mode Gaussian unitary operations, and thus enable efficient construction of operations crucial to quantum information science, such as high-fidelity quantum transduction. Our results are directly derived from fundamental physical properties of bosonic systems and are therefore broadly applicable to various existing platforms.