Non-Gaussian operations on bosonic modes of light: Photon-added Gaussian channels

TL;DR

This paper introduces a framework for photon-added Gaussian channels in continuous-variable quantum systems, demonstrating their experimental viability and potential for advancing quantum communication and computation beyond Gaussian limitations.

Contribution

It develops a new class of non-Gaussian channels via photon addition, derives their operator-sum representation, and explores their applications in quantum information processing.

Findings

Channels are Fock preserving and coherence nongenerating

Photon addition can activate nonclassicality and enhance communication capacities

Noisy Gaussian channels can be represented as mixtures of these non-Gaussian channels

Abstract

We present a framework for studying bosonic non-Gaussian channels of continuous-variable systems. Our emphasis is on a class of channels that we call photon-added Gaussian channels, which are experimentally viable with current quantum-optical technologies. A strong motivation for considering these channels is the fact that it is compulsory to go beyond the Gaussian domain for numerous tasks in continuous-variable quantum information processing such as entanglement distillation from Gaussian states and universal quantum computation. The single-mode photon-added channels we consider are obtained by using two-mode beam splitters and squeezing operators with photon addition applied to the ancilla ports giving rise to families of non-Gaussian channels. For each such channel, we derive its operator-sum representation, indispensable in the present context. We observe that these channels are Fock preserving (coherence nongenerating). We then report two examples of activation using our scheme of photon addition, that of quantum-optical nonclassicality at outputs of channels that would otherwise output only classical states and of both the quantum and private communication capacities, hinting at far-reaching applications for quantum-optical communication. Further, we see that noisy Gaussian channels can be expressed as a convex mixture of these non-Gaussian channels. We also present other physical and information-theoretic properties of these channels.