Presentation is loading. Please wait.

Presentation is loading. Please wait.

1 Entanglement between Collective Operators in a Linear Harmonic Chain Johannes Kofler 1, Vlatko Vedral 2, Myungshik S. Kim 3, Časlav Brukner 1,4 1 University.

Published byAlaina Lee Modified over 9 years ago

Similar presentations

Presentation on theme: "1 Entanglement between Collective Operators in a Linear Harmonic Chain Johannes Kofler 1, Vlatko Vedral 2, Myungshik S. Kim 3, Časlav Brukner 1,4 1 University."— Presentation transcript:

1 1 Entanglement between Collective Operators in a Linear Harmonic Chain Johannes Kofler 1, Vlatko Vedral 2, Myungshik S. Kim 3, Časlav Brukner 1,4 1 University of Vienna, Austria 2 University of Leeds, United Kingdom 3 Queen’s University Belfast, United Kingdom 4 Austrian Academy of Sciences, Austria Quantum Information Theory & Technology Summer School Belfast, United Kingdom September 2, 2005

2 2 Motivation Aim: Detect entanglement between macroscopic parts of a system by looking at collective operators (macroscopic observables) for different regions Collective operators: Sum over (average of) individual operators Why: (i) Experimentally approachable (ii) Fundamentally interesting: “Can collective operators be entangled?” Up to now: entanglement between single particles or between “mathematical” blocks Here: Entanglement between two “physical” blocks

3 3 The Linear Harmonic Chain Coupling: Hamiltonian

4 4  Upgrading position and momentum to operators and expansion into modes Pseudo-momentum Dispersion relation Ground state

5 5 Two-point Vacuum Correlation Functions A. Botero, B. Reznik, Phys. Rev. A 70, 052329 (2004)

6 6 Collective Blocks of Oscillators Collective Operators same block different blocks

7 7 Notation Usual: “Mathematical” Block -Every measurement in the block is allowed in principle Here: “Physical” Block -Characterized by collective operators -Measurement couples only to the block as a whole -Information loss

8 8 Microscopic Mesoscopic Macroscopic

9 9 Entanglement between two blocks of equal size Matrix of second moments

10 10 Degree of Entanglement between Blocks Peres–Horodecki–Simon–Kim Negativity

11 11 Trade-off Microscopic case: p = 0 -Measurement apparatus has to be accurate to resolve individual oscillators -Absolute error in the measured numbers can be large (  1) Macroscopic case: p = 1 -Measurement apparatus can be coarse -Absolute accuracy has to scale with n –2

12 12 Neighbouring Blocks (of equal size n) Entanglement for all coupling parameters  and block sizes n (macroscopic parts) Strength of entanglement decreases with decreasing coupling and increasing block size

13 13 Separated Blocks (of equal size n) No entanglement between separated individual oscillators (n = 1) Genuine multi-particle entanglement for n = 2, 3 and 4

14 14 Entanglement Detection by Uncertainty Relations then the two blocks are entangled (Duan et al)if For n A or n B > 1 this witness is weaker than the entanglement degree  Entanglement not for all neighbouring blocks No multi-particle entanglement detected

15 15 Scalar Quantum Field Theory Collective operators etc.

16 16 Conclusions Entanglement between collective operators (macroscopic parts) of a system is demonstrated and quantified Neighbouring blocks in the harmonic chain are entangled for all block sizes and coupling constants Genuine multi-particle entanglement between (small) separated blocks where no individual pair is entangled arXiv:quant-ph/0506236

Download ppt "1 Entanglement between Collective Operators in a Linear Harmonic Chain Johannes Kofler 1, Vlatko Vedral 2, Myungshik S. Kim 3, Časlav Brukner 1,4 1 University."

Similar presentations

Strong Monogamy and Genuine Multipartite Entanglement Gerardo Adesso Informal Quantum Information Gathering 2007 The Gaussian Case Quantum Theory group.

Strong Monogamy and Genuine Multipartite Entanglement Gerardo Adesso Informal Quantum Information Gathering 2007 The Gaussian Case Quantum Theory group.
Kondo Physics from a Quantum Information Perspective

Kondo Physics from a Quantum Information Perspective
Interplay Between Electronic and Nuclear Motion in the Photodouble Ionization of H 2 T J Reddish, J Colgan, P Bolognesi, L Avaldi, M Gisselbrecht, M Lavollée,

Interplay Between Electronic and Nuclear Motion in the Photodouble Ionization of H 2 T J Reddish, J Colgan, P Bolognesi, L Avaldi, M Gisselbrecht, M Lavollée,
Frustration of Decoherence and Entanglement-sharing in the Spin-bath Andrew Hines Christopher Dawson Ross McKenzie Gerard Milburn.

Frustration of Decoherence and Entanglement-sharing in the Spin-bath Andrew Hines Christopher Dawson Ross McKenzie Gerard Milburn.
Detecting Genuine Multi-qubit Entanglement with Two Local Measurement Settings Géza Tóth (MPQ) Otfried Gühne (Innsbruck) Quantum Optics II, Cozumel, Dec.

Detecting Genuine Multi-qubit Entanglement with Two Local Measurement Settings Géza Tóth (MPQ) Otfried Gühne (Innsbruck) Quantum Optics II, Cozumel, Dec.
Integrals over Operators

Integrals over Operators
Entanglement of Movable Mirrors in a Correlated Emission Laser

Entanglement of Movable Mirrors in a Correlated Emission Laser
Durham University – Atomic & Molecular Physics group

Durham University – Atomic & Molecular Physics group
Macroscopic Realism Emerging from Quantum Physics Johannes Kofler and Časlav Brukner 15th UK and European Meeting on the Foundations of Physics University.

Macroscopic Realism Emerging from Quantum Physics Johannes Kofler and Časlav Brukner 15th UK and European Meeting on the Foundations of Physics University.
What is symmetry? Immunity (of aspects of a system) to a possible change.

What is symmetry? Immunity (of aspects of a system) to a possible change.
Subir Sachdev Science 286, 2479 (1999). Quantum phase transitions in atomic gases and condensed matter Transparencies online at

Subir Sachdev Science 286, 2479 (1999). Quantum phase transitions in atomic gases and condensed matter Transparencies online at
Holographic Dark Energy Preety Sidhu 5 May 2006. Black Holes and Entropy Black holes are “maximal entropy objects” Entropy of a black hole proportional.

Holographic Dark Energy Preety Sidhu 5 May Black Holes and Entropy Black holes are “maximal entropy objects” Entropy of a black hole proportional.
Niels Bohr Institute Copenhagen University Eugene PolzikLECTURE 5.

Niels Bohr Institute Copenhagen University Eugene PolzikLECTURE 5.
Probing Vacuum Entanglement Benni Reznik Tel-Aviv University In collaboration with: A. Botero, J. I. Cirac, A. Retzker, J. Silman.

Probing Vacuum Entanglement Benni Reznik Tel-Aviv University In collaboration with: A. Botero, J. I. Cirac, A. Retzker, J. Silman.
Fermions and non-commuting observables from classical probabilities.

Fermions and non-commuting observables from classical probabilities.
by Silke Weinfurtner Victoria University of Wellington, New Zealand Stefano Liberati SISSA/INFN Trieste, Italy Constraining quantum gravity phenomenology.

by Silke Weinfurtner Victoria University of Wellington, New Zealand Stefano Liberati SISSA/INFN Trieste, Italy Constraining quantum gravity phenomenology.
Physics 452 Quantum mechanics II Winter 2012 Karine Chesnel.

Physics 452 Quantum mechanics II Winter 2012 Karine Chesnel.
Equilibrium dynamics of entangled states near quantum critical points Talk online at Physical Review Letters 78, 843.

Equilibrium dynamics of entangled states near quantum critical points Talk online at Physical Review Letters 78, 843.
Coherence in Spontaneous Emission Creston Herold July 8, 2013 JQI Summer School (1 st annual!)

Coherence in Spontaneous Emission Creston Herold July 8, 2013 JQI Summer School (1 st annual!)
Quantum violation of macroscopic realism and the transition to classical physics Faculty of Physics University of Vienna, Austria Institute for Quantum.

Quantum violation of macroscopic realism and the transition to classical physics Faculty of Physics University of Vienna, Austria Institute for Quantum.

Similar presentations

Ads by Google