Absorption capacity of separable noise: Bell-mixing thresholds on separability and teleportation

Abstract

We study Bell-mixing lines ρλ=λΦ+ +(1-λ)σ, where Φ+ is a fixed Bell reference and σ is a separable two-qubit noise state. Along this line there are two operational crossings: the state becomes entangled, and it reaches quantum teleportation advantage over classical strategies. We package these crossings as capacities of the noise state. The entanglement absorption capacity C abs(σ) is the largest amount of Bell reference that σ can absorb while the partial transpose remains positive. The fidelity absorption capacity CF(σ) is the largest amount of Bell reference that σ can absorb while keeping the maximal teleportation fidelity at or below the classical bound 2/3. The thresholds corresponding to the two crossing points are obtained from the same Möbius map, λ* = C abs/(1+C abs) and λF = CF/(1+CF). We derive closed-form capacities and thresholds for product noise states and separable complex X noise states. For product noise, C abs depends only on local marginal purities, while CF also depends on orientation relative to the maximally entangled reference. For X noise states, both capacities are explicit in all four Bell frames. We also study three extensions: arbitrary pure-state references, the evolution of X noise states and their capacities under local amplitude-damping and dephasing channels, and decomposition certificates that give lower bounds on the capacities, hence on the thresholds, for general separable noise.

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