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Macroscopic objects in quantum mechanics: A combinatorial approach

Quantum Physics 2009-11-10 v4 Statistical Mechanics

Abstract

Why we do not see large macroscopic objects in entangled states? There are two ways to approach this question. The first is dynamic: the coupling of a large object to its environment cause any entanglement to decrease considerably. The second approach, which is discussed in this paper, puts the stress on the difficulty to observe a large scale entanglement. As the number of particles n grows we need an ever more precise knowledge of the state, and an ever more carefully designed experiment, in order to recognize entanglement. To develop this point we consider a family of observables, called witnesses, which are designed to detect entanglement. A witness W distinguishes all the separable (unentangled) states from some entangled states. If we normalize the witness W to satisfy |tr(W\rho)| \leq 1 for all separable states \rho, then the efficiency of W depends on the size of its maximal eigenvalue in absolute value; that is, its operator norm ||W||. It is known that there are witnesses on the space of n qbits for which ||W|| is exponential in n. However, we conjecture that for a large majority of n-qbit witnesses ||W|| \leq O(\sqrt{n logn}). Thus, in a non ideal measurement, which includes errors, the largest eigenvalue of a typical witness lies below the threshold of detection. We prove this conjecture for the family of extremal witnesses introduced by Werner and Wolf (Phys. Rev. A 64, 032112 (2001)).

Keywords

Cite

@article{arxiv.quant-ph/0404051,
  title  = {Macroscopic objects in quantum mechanics: A combinatorial approach},
  author = {Itamar Pitowsky},
  journal= {arXiv preprint arXiv:quant-ph/0404051},
  year   = {2009}
}

Comments

RevTeX, 14 pages, some additions to the published version: A second conjecture added, discussion expanded, and references added