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T he Separability Problem and its Variants in Quantum Entanglement Theory

T he Separability Problem and its Variants in Quantum Entanglement Theory. Nathaniel Johnston Institute for Quantum Computing University of Waterloo. Overview. What is Quantum Entanglement? The Separability Problem The Bound Entanglement Problem The Separability from Spectrum Problem.

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T he Separability Problem and its Variants in Quantum Entanglement Theory

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  1. The Separability Problem and its Variants in Quantum Entanglement Theory Nathaniel Johnston Institute for Quantum Computing University of Waterloo

  2. Overview • What is Quantum Entanglement? • The Separability Problem • The Bound Entanglement Problem • The Separability from Spectrum Problem

  3. Overview • What is Quantum Entanglement? • Weird physical phenomenon • Linear algebra works! • The Separability Problem • The Bound Entanglement Problem • The Separability from Spectrum Problem

  4. What is Quantum Entanglement? Physicist Mathematician • Particles can be “linked” • Always get correlated measurement results • That’s weird! • Tensor product of finite-dimensional vector spaces • Tensors of rank > 1 exist • That’s obvious!

  5. What is Quantum Entanglement? Pure quantum state: with i.e., with Dual (row) vector: Inner product:

  6. What is Quantum Entanglement? Tensor product: = = =

  7. What is Quantum Entanglement? Outer product tensor product: Obtained via “stacking columns”:

  8. What is Quantum Entanglement? Definition A pure state is separable if it can be written as Otherwise, it is entangled. rank 1 rank 2 (thus entangled)

  9. What is Quantum Entanglement? • Mixed quantum state: • Trace 1 • Positive semidefinite equivalent • Pure state (again): • Rank 1 • Trace 1 • Positive semidefinite equivalent

  10. What is Quantum Entanglement? Definition A mixed state is separable if it can be written as with each separable. Otherwise, it is entangled. for some Equivalent: separable convex combination positive semidefinite is the “maximally mixed” state.

  11. Overview • What is Quantum Entanglement? • The Separability Problem • How to determine separability? • Positive matrix-valued maps • Funky matrix norms • The Bound Entanglement Problem • The Separability from Spectrum Problem

  12. The Separability Problem Recall: is separable if we can write for some Definition Given the separability problem is the problem of determining whether ρ is separable or entangled. This is an NP-hard problem! (Gurvits, 2003) This is a hard problem!

  13. The Separability Problem Separable states All states ρ

  14. The Separability Problem Method 1: “Partial” transpose Define a linear map Γ on by In matrices:

  15. The Separability Problem Apply Γ to a separable state: is positive semidefinite We say that ρ has positive partial transpose (PPT). Not true for some entangled states: which has eigenvalues 1, 1, 1, and -1.

  16. The Separability Problem Separable states PPT states All states ρ

  17. The Separability Problem Theorem (Størmer, 1963; Woronowicz, 1976; Peres, 1996) Let be a quantum state. If ρ is separable then Furthermore, the converse holds if and only if mn≤ 6. • Separability problem is completely solved when mn ≤ 6 • Higher dimensions?

  18. The Separability Problem Method 1.1: Positive maps Given , define a linear map on by In matrices:

  19. The Separability Problem Definition is positive if whenever Transpose map: positive semidefinite Theorem (Horodecki3, 1996) A quantum state is separable if and only if for all positive maps

  20. The Separability Problem Separable states Transpose map All states ρ

  21. The Separability Problem • The problem: • Coming up with positive maps is hard! • Proving that a map is positive is NP-hard • Current status: • Dozens of papers • Only a handful of known positive maps

  22. The Separability Problem Method 2: Norms Definition The operator norm and trace norm of a matrix are defined by: where are the singular values of X.

  23. The Separability Problem Separable states ≈unit ball of All states ≈ unit ball of

  24. The Separability Problem Definition Given define the S(1)-norm via Separable version of dual dual Separable version of

  25. The Separability Problem Theorem (Rudolph, 2000) Let be the dual of the S(1)-norm, defined by A quantum state ρ is separable if and only if

  26. The Separability Problem Separable states ≈unit ball of All states ≈ unit ball of

  27. The Separability Problem The goal: derive bounds for • “Swap” operator: • “Realignment” map: because = 1 if ρ separable

  28. The Separability Problem Theorem (Chen–Wu, 2003) If then ρ is entangled. • The goal: • Come up with more bounds on • Lower bounds entanglement • Upper bounds separability ρ σ

  29. Overview • What is Quantum Entanglement? • The Separability Problem • The Bound Entanglement Problem • Not all entanglement is “useful” • Partial transpose is awesome • The Separability from Spectrum Problem

  30. Bound Entanglement Can we turn mixed entanglement into pure entanglement? ρ ρ ρ

  31. Bound Entanglement Not always! Theorem (Horodecki3, 1998) If the quantum state has positive partial transpose then it is bound entangled (i.e., many copies of ρcan not be locally converted into an entangled pure state). Question: Are there more? Or is this “iff”?

  32. Bound Entanglement Separable states PPT states = Bound entangled states Bound entangled states All states

  33. Bound Entanglement Let’s phrase the problem mathematically! • Recall: for we have • Similarly, • “Rank 1” and “full rank” versions of same norm

  34. Bound Entanglement We now want the “rank 2” version of this norm: Also need the “maximally entangled state”: standard basis of

  35. Bound Entanglement Theorem Define a family of projections P1, P2, … recursively as follows: Then there exists non-positive partial transpose bound entanglement (more or less) if and only if up to minor technical details (e.g., n ≥ 4 only)

  36. Bound Entanglement What do we know so far? n = 4, k = 2: Big gap! equality when k = 1

  37. Overview • What is Quantum Entanglement? • The Separability Problem • The Bound Entanglement Problem • The Separability from Spectrum Problem • We only know eigenvalues • Want to determine separable/entangled

  38. Separability from Spectrum • Only given eigenvalues of ρ • Can we prove ρis entangled/separable? Prove entangled? No:diagonal separable arbitrary eigenvalues, but always separable

  39. Separability from Spectrum • Only given eigenvalues of ρ • Can we prove ρis entangled/separable? Prove separable? Sometimes: If all eigenvalues are equal then a separable decomposition

  40. Separability from Spectrum Can also prove separability if ρ is close to Theorem (Gurvits–Barnum, 2002) Let be a mixed state. If then ρis separable, where is the Frobenius norm. Frobenius norm: eigenvalues of ρ

  41. Separability from Spectrum Separable states Gurvits–Barnum ball All states

  42. Separability from Spectrum Definition A quantum state is called separable from spectrum if all quantum states with the same eigenvalues as ρ are separable. States in the Gurvits–Barnum ball are separable from spectrum: But there are more! only depends on eigenvalues of ρ

  43. Separability from Spectrum Separable states Gurvits–Barnum ball Separable from spectrum All states

  44. Separability from Spectrum The case of two qubits (i.e., m = n = 2) was solved long ago: Theorem (Verstraete–Audenaert–Moor, 2001) A state is separable from spectrum if and only if What about higher-dimensional systems? eigenvalues, sorted so that λ1 ≥ λ2≥ λ3≥ λ4≥ 0

  45. Separability from Spectrum Replace “separable” by “positive partial transpose”. Definition A quantum state is called positive partial transpose (PPT) from spectrum if all quantum states with the same eigenvalues as ρ are PPT.

  46. Separability from Spectrum Separable states Gurvits–Barnum ball Separable from spectrum All states PPT from spectrum

  47. Separability from Spectrum • PPT from spectrum is completely solved (but complicated) Theorem (Hildebrand, 2007) A state is PPT from spectrum if and only if • Recall: separability = PPT when m = 2, n ≤ 3 • Thus is separable from spectrum if and only if

  48. Separability from Spectrum Can PPT from spectrum tell us more about separability from spectrum? Yes! weird when n ≥ 4 obvious when n ≤ 3 Theorem (J., 2013) A state is separable from spectrum if and only if it is PPT from spectrum.

  49. Separability from Spectrum Separable states Gurvits–Barnum ball = Separable from spectrum All states PPT from spectrum

  50. Separability from Spectrum Sketch of proof. Write as a block matrix: ρ becomes “more positive” as B becomes small compared to A and C Lemma If then ρ is separable.

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