Your search keyword '"Gühne O"' showing total 13 results

1. Characterizing quantum states via sector lengths.

Author

Wyderka, N and Gühne, O

Subjects

QUANTUM states, QUANTUM correlations, QUANTUM mechanics, QUANTUM theory, ENTROPY (Information theory)

Abstract

Correlations in multiparticle systems are constrained by restrictions from quantum mechanics. A prominent example for these restrictions are monogamy relations, limiting the amount of entanglement between pairs of particles in a three-particle system. A powerful tool to study correlation constraints is the notion of sector lengths. These quantify, for different k, the amount of k-partite correlations in a quantum state in a basis-independent manner. We derive tight bounds on the sector lengths in multi-qubit states and highlight applications of these bounds to entanglement detection, monogamy relations and the n-representability problem. For the case of two- and three qubits we characterize the possible sector lengths completely and prove a symmetrized version of strong subadditivity for the linear entropy. [ABSTRACT FROM AUTHOR]

Published

2020

2. Covariance matrix criterion for separability.

Author

Gittsovich, O., Gühne, O., Hyllus, P., and Eisert, J.

Subjects

ANALYSIS of variance, MATRICES (Mathematics), CRITERION (Theory of knowledge), QUANTUM theory, PHYSICAL sciences

Abstract

We review an approach to the separability problem using covariance matrices of locally measurable observables. This approach leads to a strong entanglement criterion which we call covariance matrix criterion (CMC). We consider some corollaries of the CMC that in general allow to detect many bound entangled states. In particular we give a new example which sheds some light on the connections between different entanglement criteria derived from the general CMC. [ABSTRACT FROM AUTHOR]

Published

2009

3. QUANTUM COMPUTATION WITH TRAPPED IONS.

Author

HÄFFNER, H., HÄNSEL, W., ROOS, C. F., SCHMIDT, P. O., RIEBE, M., CHWALLA, M., CHEK–AL–KAR, D., BENHELM, J., RAPOL, U. D., KÖRBER, T., BECHER, C., GÜHNE, O., DÜR, W., and BLATT, R.

Subjects

QUANTUM computing, QUANTUM Hall effect, QUANTUM entanglement, ELASTIC hysteresis, QUANTUM interference, QUANTUM theory

Published

2008

4. Quantum Correlations for Quantum Key Distribution Protocols.

Author

Curty, M., Gühne, O., Lewenstein, M., and Lütkenhaus, N.

Subjects

QUANTUM statistics, WAVE mechanics, NUMERICAL analysis, MATHEMATICAL analysis, COMPUTER network protocols, PHYSICAL sciences

Abstract

A necessary precondition for secure quantum key distribution (QKD) is that sender and receiver can prove the presence of entanglement in a quantum state that is effectively distributed between them. In order to deliver this entanglement proof one can use the class of entanglement witness operators that can be constructed from the available measurements results. This criterion provides a necessary and sufficient condition for the existence of quantum correlations even when a quantum state cannot be completely reconstructed. We apply such analysis to three well-known qubit-based QKD protocols, namely the 6-state, the 4-state and the 2-state protocols. © 2004 American Institute of Physics [ABSTRACT FROM AUTHOR]

Published

2004

5. Separability criteria and entanglement witnesses for symmetric quantum states.

Author

Tóth, G. and Gühne, O.

Subjects

QUANTUM theory, BIPARTITE graphs, MECHANICS (Physics), SYMMETRIC functions

Abstract

We study the separability of symmetric bipartite quantum states and show that a single correlation measurement is sufficient to detect the entanglement of any bipartite symmetric state with a non-positive partial transpose. We also discuss entanglement conditions and entanglement witnesses for states with a positive partial transpose. [ABSTRACT FROM AUTHOR]

Published

2010

6. Modeling the decay of entanglement for electron spin qubits in quantum dots.

Author

Bodoky, F, Gühne, O, and Blaauboer, M

Published

2009

7. State-independent experimental test of quantum contextuality.

Author

Kirchmair, G., Zähringer, F., Gerritsma, R., Kleinmann, M., Gühne, O., Cabello, A., Blatt, R., and Roos, C. F.

Subjects

QUANTUM theory, PARTICLES (Nuclear physics), PHOTONS, NEUTRONS, ION traps, NUCLEAR physics

Abstract

The question of whether quantum phenomena can be explained by classical models with hidden variables is the subject of a long-lasting debate. In 1964, Bell showed that certain types of classical models cannot explain the quantum mechanical predictions for specific states of distant particles, and some types of hidden variable models have been experimentally ruled out. An intuitive feature of classical models is non-contextuality: the property that any measurement has a value independent of other compatible measurements being carried out at the same time. However, a theorem derived by Kochen, Specker and Bell shows that non-contextuality is in conflict with quantum mechanics. The conflict resides in the structure of the theory and is independent of the properties of special states. It has been debated whether the Kochen–Specker theorem could be experimentally tested at all. First tests of quantum contextuality have been proposed only recently, and undertaken with photons and neutrons. But these tests required the generation of special quantum states and left various loopholes open. Here we perform an experiment with trapped ions that demonstrates a state-independent conflict with non-contextuality. The experiment is not subject to the detection loophole and we show that, despite imperfections and possible measurement disturbances, our results cannot be explained in non-contextual terms. [ABSTRACT FROM AUTHOR]

Published

2009

8. Nonlocality for graph states.

Author

Cabello, A., Gühne, O., Moreno, P., and Rodríguez, D.

Abstract

The possibility of preparing two-photon entangled states encoding three or more qubits in each photon leads to the following problem: If n quabits were distributed between two parties, which quantum pure states and qubit distributions would allow all-versus-nothing (or Greenberger-Horne-Zeilinger-like) proofs of Bell’s theorem using only single-qubit measurements? We show a necessary and sufficient condition for the existence of these proofs and provide all existing proofs up to n = 7 qubits. On the other hand, the possibility of preparing n-photon n-qubit graph states leads to the following problem: If n qubits were distributed between n parties, which would be the optimal Bell inequalities? We show all optimal n-party Bell inequalities for the perfect correlations of any graph state of n < 6 qubits. Optimal means that the ratio between the quantum violation and the bound for local hidden-variable theories is the maximum over all possible combinations of perfect correlations. This implies that the required detection efficiencies for loophole-free Bell tests are minimal. [ABSTRACT FROM AUTHOR]

Published

2008

9. Tomografie eines Quantenzustands – Verschränkung und Reinheit.

Author

Gühne, O. and Häffner, H.

Published

2007

10. Detection of multipartite entanglement with two-body correlations.

Author

Tóth, G. and Gühne, O.

Subjects

HAMILTONIAN systems, THERMODYNAMIC equilibrium, QUANTUM theory, ROTATIONAL motion, GAUSSIAN processes, PAIRING correlations (Nuclear physics)

Abstract

We show how to detect entanglement with criteria built from simple two-body correlation terms. Since many natural Hamiltonians are sums of such correlation terms, our ideas can be used to detect entanglement by energy measurement. Our criteria can straightforwardly be applied for detecting different forms of multipartite entanglement in familiar spin models in thermal equilibrium. [ABSTRACT FROM AUTHOR]

Published

2006

11. Scalable multiparticle entanglement of trapped ions.

Author

Häffner, H., Hänsel, W., Roos, C. F., Benhelm, J., Chek-al-kar, D., Chwalla, M., Körber, T., Rapol, U. D., Riebe, M., Schmidt, P. O., Becher, C., Gühne, O., Dür, W., and Blatt, R.

Subjects

ION traps, IONS, QUANTUM theory, MECHANICS (Physics), PARTICLES (Nuclear physics), PHYSICS

Abstract

The generation, manipulation and fundamental understanding of entanglement lies at the very heart of quantum mechanics. Entangled particles are non-interacting but are described by a common wavefunction; consequently, individual particles are not independent of each other and their quantum properties are inextricably interwoven. The intriguing features of entanglement become particularly evident if the particles can be individually controlled and physically separated. However, both the experimental realization and characterization of entanglement become exceedingly difficult for systems with many particles. The main difficulty is to manipulate and detect the quantum state of individual particles as well as to control the interaction between them. So far, entanglement of four ions or five photons has been demonstrated experimentally. The creation of scalable multiparticle entanglement demands a non-exponential scaling of resources with particle number. Among the various kinds of entangled states, the ‘W state’ plays an important role as its entanglement is maximally persistent and robust even under particle loss. Such states are central as a resource in quantum information processing and multiparty quantum communication. Here we report the scalable and deterministic generation of four-, five-, six-, seven- and eight-particle entangled states of the W type with trapped ions. We obtain the maximum possible information on these states by performing full characterization via state tomography, using individual control and detection of the ions. A detailed analysis proves that the entanglement is genuine. The availability of such multiparticle entangled states, together with full information in the form of their density matrices, creates a test-bed for theoretical studies of multiparticle entanglement. Independently, ‘Greenberger–Horne–Zeilinger’ entangled states with up to six ions have been created and analysed in Boulder. [ABSTRACT FROM AUTHOR]

Published

2005

12. FOUR PHOTON POLARIZATION ENTANGLEMENT TESTS AND APPLICATIONS.

Author

BOURENNANE, M., EIBL, M., GAERTNER, S., KURTSIEFER, C., WEINFURTER, H., CABELLO, A., GÜHNE, O., HYLLUS, PH., BRUß, D., LEWENSTEIN, M., and SANPERA, A.

Published

2004

13. Experimental detection of entanglement via witness operators and local measurements.

Author

Gühne, O., Hyllus, P., Bruss, D., Ekert, A., Lewenstein, M., Macchiavello, C., and Sanpera, A.

Subjects

OPTICS, QUANTUM theory

Abstract

In this paper we address the problem of detection of entanglement using only few local measurements when some knowledge about the state is given. The idea is based on an optimized decomposition of witness operators into local operators. We discuss two possible ways of optimizing this local decomposition. We present several analytical results and estimates for optimized detection strategies for NPT states of 2 × 2 and N × M systems, entangled states in 3 qubit systems, and bound entangled states in 3 × 3 and 2 × 4 systems. [ABSTRACT FROM AUTHOR]

Published

2003