New considerations on the separability of very noisy mixed states and implications for NMR quantum computing
Abstract
We revise the problem first addressed by Braunstein and co-workers (Phys. Rev. Lett. 83 (5) (1999) 1054) concerning the separability of very noisy mixed states represented by general density matrices with the form ε = (1-ε)Md+ε1. From a detailed numerical analysis, it is shown that: (1) there exist infinite values in the interval taken for the density matrix expansion coefficients, -1 cα1,...,αN 1, which give rise to non-physical density matrices, with trace equal to 1, but at least one negative eigenvalue; (2) there exist entangled matrices outside the predicted entanglement region, and (3) there exist separable matrices inside the same region. It is also shown that the lower and upper bounds of ε depend on the coefficients of the expansion of 1 in the Pauli basis. If 1 is hermitian with trace equal to 1, but is allowed to have negative eigenvalues, it is shown that ε can be entangled, even for two qubits.
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