Abstract:

We consider a family of vector and operator norms which we refer to as Schmidt norms. We show that these norms have several uses in quantum information theory — they can be used to help classify k-positive linear maps (and hence entanglement witnesses), they are useful for approaching the problem of finding non-positive partial transpose bound entangled Werner states, they are related to the quantum fidelity and trace distance measures, and they are connected to the recently-defined local numerical range. We show that the vector norms can be explicitly calculated, and we derive several inequalities in order to bound the operator norms and compute them in special cases. We show that one particular entangled Werner state is bound entangled if and only if a certain norm inequality holds on a given family of projections, and we use our inequalities to study that family of projections. We also develop a family of semidefinite programs that can be used to further bound the operator norms. We extend these norms to arbitrary convex mapping cones and explore their implications with positive partial transpose states.

Authors:

• Nathaniel Johnston
• David Kribs

Download:

• Preprint from arXiv:0909.3907 [quant-ph]
• Local preprint [pdf]
• Slideshow presentation (short version) [pdf]
• Slideshow presentation (long version) [pdf]

Status:

• Submitted to Communications in Mathematical Physics in September 2009.

Cite as:

• Johnston, N. and Kribs, D. W., Schmidt Norms for Quantum States. Preprint (2009).

Supplementary Material:

• An Introduction to Schmidt Norms (blog post)
• Approximating the Distribution of Schmidt Vector Norms (blog post)