Giant acoustic atom: A single quantum system with a deterministic time delay

This paper is aimed to dissociate nonlocality from quantum theory. We demonstrate that the tests on violation of the Bell type inequalities are simply statistical tests of local incompatibility of observables. In fact, these are tests on violation of the Bohr complementarity principle. Thus, the attempts to couple experimental violations of the Bell type inequalities with “quantum nonlocality” is really misleading. These violations are explained in the quantum theory as exhibitions of incompatibility of observables for a single quantum system, e.g., the spin projections for a single electron or the polarization projections for a single photon. Of course, one can go beyond quantum theory with the hidden variables models (as was suggested by Bell) and then discuss their possible nonlocal features. However, conventional quantum theory is local.

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Nonlinear Spectroscopy on a Single Quantum System: Two-Photon Absorption of a Single Molecule

Science ◽

10.1126/science.271.5256.1703 ◽

1996 ◽

Vol 271 (5256) ◽

pp. 1703-1705 ◽

Cited By ~ 57

Author(s):

T. Plakhotnik ◽

D. Walser ◽

M. Pirotta ◽

A. Renn ◽

U. P. Wild

Keyword(s):

Quantum System ◽

Single Molecule ◽

Nonlinear Spectroscopy ◽

Photon Absorption ◽

Single Quantum ◽

Two Photon Absorption ◽

Two Photon

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Entanglement dynamics for Unruh-DeWitt detectors interacting with massive scalar fields: the Unruh and anti-Unruh effects

Journal of High Energy Physics ◽

10.1007/jhep09(2021)088 ◽

2021 ◽

Vol 2021 (9) ◽

Author(s):

Yuebing Zhou ◽

Jiawei Hu ◽

Hongwei Yu

Keyword(s):

Time Delay ◽

Quantum System ◽

Open Quantum Systems ◽

Scalar Fields ◽

Thermal Bath ◽

Unruh Effect ◽

Massive Scalar ◽

Entanglement Dynamics ◽

The One ◽

Time Delay Effect

Abstract We study, in the framework of open quantum systems, the entanglement dynamics for a quantum system composed of two uniformly accelerated Unruh-Dewitt detectors interacting with a bath of massive scalar fields in the Minkowski vacuum. We find that the entanglement evolution for the quantum system coupled with massive fields is always slower compared with that of the one coupled with massless fields, and this time-delay effect brought about by the field being massive can however be counteracted by a large enough acceleration, in contrast to the case of a static quantum system in a thermal bath, where this time delay is not affected by the temperature. Remarkably, the maximal concurrence of the quantum system generated during evolution may increase with acceleration for any inter-detector separation while that for static ones in a thermal bath decreases monotonically with temperature, and this can be considered as an anti-Unruh effect in terms of the entanglement generated.

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Variation of power-law dynamics caused by dark state recovery of fluorescence intermittency of a single quantum system

10.1117/12.677043 ◽

2006 ◽

Cited By ~ 1

Author(s):

Jörg Schuster ◽

Frank Cichos ◽

Christian von Borczyskowski

Keyword(s):

Quantum System ◽

Power Law ◽

Single Quantum ◽

Dark State ◽

State Recovery ◽

Fluorescence Intermittency

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Wigner Time Delay Induced by a Single Quantum Dot

Physical Review Letters ◽

10.1103/physrevlett.122.107401 ◽

2019 ◽

Vol 122 (10) ◽

Cited By ~ 6

Author(s):

Max Strauß ◽

Alexander Carmele ◽

Julian Schleibner ◽

Marcel Hohn ◽

Christian Schneider ◽

...

Keyword(s):

Time Delay ◽

Quantum Dot ◽

Single Quantum ◽

Single Quantum Dot

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Impossibility of Measuring the Wave Function of a Single Quantum System

Physical Review Letters ◽

10.1103/physrevlett.76.2832 ◽

1996 ◽

Vol 76 (16) ◽

pp. 2832-2835 ◽

Cited By ~ 127

Author(s):

G. M. D'Ariano ◽

H. P. Yuen

Keyword(s):

Wave Function ◽

Quantum System ◽

Single Quantum

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Process tomography via sequential measurements on a single quantum system

Physical Review A ◽

10.1103/physreva.92.032102 ◽

2015 ◽

Vol 92 (3) ◽

Cited By ~ 9

Author(s):

Humairah Bassa ◽

Sandeep K. Goyal ◽

Sujit K. Choudhary ◽

Hermann Uys ◽

Lajos Diósi ◽

...

Keyword(s):

Quantum System ◽

Single Quantum ◽

Process Tomography ◽

Sequential Measurements

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Group Theoretical Description of the Periodic System

Symmetry ◽

10.3390/sym14010137 ◽

2022 ◽

Vol 14 (1) ◽

pp. 137

Author(s):

Vadim V. Varlamov ◽

Larisa D. Pavlova ◽

Olga S. Babushkina

Keyword(s):

Quantum System ◽

Periodic System ◽

Energy Operator ◽

Mass Splitting ◽

Theoretical Description ◽

Conformal Group ◽

Theoretic Approach ◽

Single Quantum ◽

Fundamental Symmetry ◽

Basic Representation

The group theoretical description of the periodic system of elements in the framework of the Rumer–Fet model is considered. We introduce the concept of a single quantum system, the generating core of which is an abstract C*-algebra. It is shown that various concrete implementations of the operator algebra depend on the structure of the generators of the fundamental symmetry group attached to the energy operator. In the case of the generators of the complex shell of a group algebra of a conformal group, the spectrum of states of a single quantum system is given in the framework of the basic representation of the Rumer–Fet group, which leads to a group-theoretic interpretation of the Mendeleev’s periodic system of elements. A mass formula is introduced that allows giving the termwise mass splitting for the main multiplet of the Rumer–Fet group. The masses of elements of the Seaborg table (eight-periodic extension of the Mendeleev table) are calculated starting from the atomic number Z=3 and going to Z=220. The continuation of the Seaborg homology between lanthanides and actinides is established with the group of superactinides. A 10-periodic extension of the periodic table is introduced in the framework of the group-theoretic approach. The multiplet structure of the extended table’s periods is considered in detail. It is shown that the period lengths of the system of elements are determined by the structure of the basic representation of the Rumer–Fet group. The theoretical masses of the elements of 10th and 11th periods are calculated starting from Z=221 and going to to Z=364. The concept of hypertwistor is introduced.

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Mass at rest after quantum information

10.31235/osf.io/dkf58 ◽

2020 ◽

Author(s):

Vasil Dinev Penchev

Keyword(s):

General Relativity ◽

Quantum Information ◽

Standard Model ◽

Quantum System ◽

Reference Frame ◽

Big Bang ◽

Single Quantum ◽

The Standard Model ◽

The Axiom Of Choice ◽

The Big Bang

The way, in which quantum information can unify quantum mechanics (and therefore the Standard model) and general relativity, is investigated. Quantum information is defined as the generalization of the concept of information as to the choice among infinite sets of alternatives. Relevantly, the axiom of choice is necessary in general. The unit of quantum information, a qubit is interpreted as a relevant elementary choice among an infinite set of alternatives generalizing that of a bit. The invariance to the axiom of choice shared by quantum mechanics is introduced: It constitutes quantum information as the relation of any state unorderable in principle (e.g. any coherent quantum state before measurement) and the same state already well-ordered (e.g. the well-ordered statistical ensemble of the measurement of the quantum system at issue). This allows of equating the classical and quantum time correspondingly as the well-ordering of any physical quantity or quantities and their coherent superposition. That equating is interpretable as the isomorphism of Minkowski space and Hilbert space. Quantum information is the structure interpretable in both ways and thus underlying their unification. Its deformation is representable correspondingly as gravitation in the deformed pseudo-Riemannian space of general relativity and the entanglement of two or more quantum systems. The Standard model studies a single quantum system and thus privileges a single reference frame turning out to be inertial for the generalized symmetry U(1)XSU(2)XSU(3) “gauging” the Standard model. As the Standard model refers to a single quantum system, it is necessarily linear and thus the corresponding privileged reference frame is necessary inertial. The Higgs mechanism U(1) → U(1)XSU(2) confirmed enough already experimentally describes exactly the choice of the initial position of a privileged reference frame as the corresponding breaking of the symmetry. The Standard model defines ‘mass at rest’ linearly and absolutely, but general relativity non-linearly and relatively. The “Big Bang” hypothesis is additional interpreting that position as that of the “Big Bang”. It serves also in order to reconcile the linear Standard model in the singularity of the “Big Bang” with the observed nonlinearity of the further expansion of the universe described very well by general relativity. Quantum information links the Standard model and general relativity in another way by mediation of entanglement. The linearity and absoluteness of the former and the nonlinearity and relativeness of the latter can be considered as the relation of a whole and the same whole divided into parts entangled in general

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