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Outline

Title
Abstract
Experimental Tests
Background of the Study
Experimental Generation of W-And GHZ-Like States
Measurement and Data-Analysis
Results: Determination of Entanglement Witness
Conclusions and Outlook
References
All Topics
Physics
Nuclear Physics

Double and triple entanglement in a single neutron system

Profile image of Daniel ErdösiDaniel Erdösi

2015

https://doi.org/10.34726/HSS.2015.21423
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94 pages

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Abstract

Einzelneutroneninterferometrie wird gerne angewendet um die Grundlagen der Quantenmechanik zu studieren. Der Nachteil dieser Technik ist jedoch, dass der Kontrast der Neutroneninterferometer sehr anfällig auf Störungen ist, insbesondere auf Temperaturschwankungen. Um einen viel niedrigeren Kontrastverlust zu erreichen als bisher, entwickeln wir neue Apparate für die Spin- und Energiemanipulation von Neutronen im Interferometer. Diese Apparate ermöglichen die Erzeugung von Quantenzuständen mit deutlich höherer Treue (fidelity) als es bisher in der Neutroneninterferometrie möglich war. Spinrotatoren mit zeitabhängigem (Radiofrequenz (RF)) Feld ändern sowohl den Spin als auch die Energie. Wir verbessern unsere RF-Spinrotatoren für das Interferometer, indem wir sie mit Miniatur Helmholtzspulen ausstatten, sodass die Energieverschiebungen durch die RF-Spulen voneinander unabhängig eingestellt werden können. Dies ist für die Erzeugung von bestimmten Quantenzuständen unabdingbar. Diese Ver...

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  83. E-Mail: danielerdosi@gmail.com Date of birth: Dec. 28, 1977 in Nyíregyháza Nationality: Hungarian Marital status: unmarried, no children Education 2009 -2015
  84. PhD-Studies, Vienna University of Technology, Atominstitut PhD thesis: Double and Triple Entanglement in a Single Neutron System 1997 -2007 University studies of technical physics, Vienna University of Technology Main focus: methods and technologies Diploma thesis (Department of solid-state Electronics): Electrical and structural characterization of living cells on microstructured solid-state electrodes 1993 -1997 Realgymnasium Billroth, 1190 Wien Employment history 2014 -to date Scientist at the Austrian Excellence Center for Tribology 2009 -2013 Project assistant at the Atominstitut TU Vienna 2005 -2009 Project assistant at the Department of solid-state Electronics TU Vienna Scientific Publications Unaffiliated: D. Erdösi, Curvature of the Universe, Physics Essays 17(3), 390 (2004).
  85. D. Erdösi, Energy Transfer Between Arbitrarily Moving Point Particles, under peer review. In team: D. Erdösi, M. Huber, B.C. Hiesmayr, Y. Hasegawa, Proving the generation of genuine multipartite entanglement in a single-neutron interferometer experiment, New Journal of Physics 15, 023033 (2013).
  86. Y. Hasegawa and D. Erdösi, Spin-path entanglement in single-neutron interferometer experiments, AIP Conf. Proc. 1384, 213-222 (2011).
  87. H. Wanzenböck, K. Dominizi, D. Erdösi, E. Bertagnolli, Precision structured surfaces as functional carriers for in-vitro cultures of living cells, euspen Conf. Proc. Vol. II, 377 (2006). Language skills German and Hungarian: native English: good

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2014

We present experimental evidence of the generation of distinct types of genuine multipartite entanglement between the spin, energy, and path degrees of freedom within single-neutron quantum systems. This is achieved via the development of new spin manipulation apparatuses for neutron interferometry and the entanglement is detected via appropriately designed and optimized non-linear witnesses. We demonstrate the extraordinarily high controllability and fidelity of the generated entangled states.

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Proving the generation of genuine multipartite entanglement in a single-neutron interferometer experiment
Daniel Erdösi

New Journal of Physics, 2013

We present experimental evidence of the generation of distinct types of genuine multipartite entanglement between three degrees of freedom (spin, energy, and path) within single-neutron quantum systems. This is achieved via the development of new spin manipulation apparatuses for neutron interferometry and the entanglement is detected via appropriately designed and optimized nonlinear witnesses. Via the applied criteria we reveal even finer properties of the type of the genuine multipartite entanglement that is produced in the experiment. In a subsequent analysis we show the extraordinarily high fidelity of the generated entangled states, proving the outstanding level of controllability of these systems.

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3He neutron spin-filter
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We investigate quantum coherences in the presence of noise by entangling the spin and path degrees of freedom of the output neutron beam from a noisy three-blade perfect crystal neutron interferometer. We find that in the presence of dephasing noise on the path degree of freedom the entanglement of the output state reduces to 0, however the quantum discord remains nonzero for all noise values. Hence even in the presence of strong phase noise nonclassical correlations persist between the spin and the path of the neutron beam. This indicates that measurements performed on the spin of the neutron beam will induce a disturbance on the path state. We calculate the effect of the spin measurement by observing the changes in the observed contrast of the interferometer for an output beam postselected on a given spin state. In doing so we demonstrate that these measurements allow us to implement a quantum eraser and a which-way measurement of the path taken by the neutron through the interferometer. While strong phase noise removes the quantum eraser, the spin-filtered which-way measurement is robust to phase noise. We experimentally demonstrate this disturbance by comparing the contrasts of the output beam with and without spin measurements of three neutron interferometers with varying noise strengths. This demonstrates that even in the presence of noise that suppresses path coherence and spin-path entanglement, a neutron interferometer still exhibits uniquely quantum behavior.

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