Your search keyword '"Complementarity (physics)"' showing total 37 results

1. On the Character of Quantum Law: Complementarity, Entanglement, and Information.

Author

Plotnitsky, Arkady

Subjects

*QUANTUM theory, *COMPLEMENTARITY (Physics), *PHYSICAL laws, *QUANTUM information theory, *QUANTUM mechanics

Abstract

This article considers the relationships between the character of physical law in quantum theory and Bohr's concept of complementarity, under the assumption of the unrepresentable and possibly inconceivable nature of quantum objects and processes, an assumption that may be seen as the most radical departure from realism currently available. Complementarity, the article argues, is a reflection of the fact that, as against classical physics or relativity, the behavior of quantum objects of the same type, say, all electrons, is not governed by the same physical law in all contexts, specifically in complementary contexts. On the other hand, the mathematical formalism of quantum mechanics offers correct probabilistic or statistical predictions (no other predictions are possible on experimental grounds) in all contexts, here, again, under the assumption that quantum objects themselves and their behavior are beyond representation or even conception. Bohr, in this connection, spoke of 'an entirely new situation as regards the description of physical phenomena that, the notion of complementarity aims at characterizing.' The article also considers the relationships among complementarity, entanglement, and quantum information, by basing these relationships on this understanding of complementarity. [ABSTRACT FROM AUTHOR]

Published

2017

2. 'The Unavoidable Interaction Between the Object and the Measuring Instruments': Reality, Probability, and Nonlocality in Quantum Physics

Author

Arkady Plotnitsky

Subjects

Philosophy of science, 010308 nuclear & particles physics, Computer science, Probabilistic logic, General Physics and Astronomy, Macroscopic quantum phenomena, Quantum entanglement, 01 natural sciences, Complementarity (physics), Bohr model, Quantum nonlocality, symbols.namesake, Quantum mechanics, 0103 physical sciences, symbols, 010306 general physics, Quantum

Abstract

This article aims to contribute to the ongoing task of clarifying the relationships between reality, probability, and nonlocality in quantum physics. It is in part stimulated by Khrennikov’s argument, in several communications, for “eliminating the issue of quantum nonlocality” from the analysis of quantum entanglement. I argue, however, that the question may not be that of eliminating but instead that of further illuminating this issue, a task that can be pursued by relating quantum nonlocality to other key features of quantum phenomena. I suggest that the following features of quantum phenomena and quantum mechanics, distinguishing them from classical phenomena and classical physics—(1) the irreducible role of measuring instruments in defining quantum phenomena, (2) discreteness, (3) complementarity, (4) entanglement, (5) quantum nonlocality, and (6) the irreducibly probabilistic nature of quantum predictions—are all interconnected, so that it is difficult to give an unconditional priority to any one of them. To argue this case, I shall consider quantum phenomena and quantum mechanics from a nonrealist or, in terms adopted here, “reality-without-realism” (RWR) perspective. This perspective extends Bohr’s view, grounded in his analysis of the irreducible role of measuring instruments in the constitution of quantum phenomena.

Published

2020

3. Critique of Quantum Optical Experimental Refutations of Bohr's Principle of Complementarity, of the Wootters-Zurek Principle of Complementarity, and of the Particle-Wave Duality Relation.

Author

Kaloyerou, P.

Subjects

*COMPLEMENTARITY (Physics), *WAVE-particle duality, *WAVE-particle interactions, *QUANTUM mechanics, *QUANTUM theory

Abstract

I argue that quantum optical experiments that purport to refute Bohr's principle of complementarity (BPC) fail in their aim. Some of these experiments try to refute complementarity by refuting the so called particle-wave duality relations, which evolved from the Wootters-Zurek reformulation of BPC (WZPC). I therefore consider it important for my forgoing arguments to first recall the essential tenets of BPC, and to clearly separate BPC from WZPC, which I will argue is a direct contradiction of BPC. This leads to a need to consider the meaning of particle-wave duality relations and to question their fundamental status. I further argue (albeit, in opposition to BPC) that particle and wave complementary concepts are on a different footing than other pairs of complementary concepts. [ABSTRACT FROM AUTHOR]

Published

2016

4. Wave-Particle Duality: An Information-Based Approach.

Author

Angelo, R. and Ribeiro, A.

Subjects

*WAVE-particle duality, *WAVE-particle interactions, *COMPLEMENTARITY (Physics), *WAVE mechanics, *QUANTUM principles

Abstract

Recently, Bohr's complementarity principle was assessed in setups involving delayed choices. These works argued in favor of a reformulation of the aforementioned principle so as to account for situations in which a quantum system would simultaneously behave as wave and particle. Here we defend a framework that, supported by well-known experimental results and consistent with the decoherence paradigm, allows us to interpret complementarity in terms of correlations between the system and an informer. Our proposal offers formal definition and operational interpretation for the dual behavior in terms of both nonlocal resources and the couple work-information. Most importantly, our results provide a generalized information-based trade-off for the wave-particle duality and a causal interpretation for delayed-choice experiments. [ABSTRACT FROM AUTHOR]

Published

2015

5. Quantum postulate vs. quantum nonlocality: on the role of the Planck constant in Bell’s argument

Author

Andrei Khrennikov

Subjects

Physics, Quantum nonlocality, symbols.namesake, Theoretical physics, Bell's theorem, Hidden variable theory, symbols, General Physics and Astronomy, Planck, Planck constant, Complementarity (physics), Quantum, Bohr model

Abstract

We present a quantum mechanical (QM) analysis of Bell’s approach to quantum foundations based on his hidden-variable model. We claim and try to justify that the Bell model contradicts to the Heinsenberg’s uncertainty and Bohr’s complementarity principles. The aim of this note is to point to the physical seed of the aforementioned principles. This is the Bohr’squantum postulate: the existence of indivisible quantum of action given by the Planck constanth. By contradicting these basic principles of QM, Bell’s model implies rejection of this postulate as well. Thus, this hidden-variable model contradicts not only the QM-formalism, but also the fundamental feature of the quantum world discovered by Planck.

Published

2021

6. Indivisibility, Complementarity and Ontology: A Bohrian Interpretation of Quantum Mechanics.

Author

Roldán-Charria, Jairo

Subjects

*QUANTUM mechanics, *COMPLEMENTARITY (Physics), *ONTOLOGY, *QUANTUM field theory, *QUANTUM logic

Abstract

The interpretation of quantum mechanics presented in this paper is inspired by two ideas that are fundamental in Bohr's writings: indivisibility and complementarity. Further basic assumptions of the proposed interpretation are completeness, universality and conceptual economy. In the interpretation, decoherence plays a fundamental role for the understanding of measurement. A general and precise conception of complementarity is proposed. It is fundamental in this interpretation to make a distinction between ontological reality, constituted by everything that does not depend at all on the collectivity of human beings, nor on their decisions or limitations, nor on their existence, and empirical reality constituted by everything that not being ontological is, however, intersubjective. According to the proposed interpretation, neither the dynamical properties, nor the constitutive properties of microsystems like mass, charge and spin, are ontological. The properties of macroscopic systems and space-time are also considered to belong to empirical reality. The acceptance of the above mentioned conclusion does not imply a total rejection of the notion of ontological reality. In the paper, utilizing the Aristotelian ideas of general cause and potentiality, a relation between ontological reality and empirical reality is proposed. Some glimpses of ontological reality, in the form of what can be said about it, are finally presented. [ABSTRACT FROM AUTHOR]

Published

2014

7. Complementarity Paradox Solved: Surprising Consequences.

Author

Flores, E. V. and De Tata, J. M.

Subjects

*COMPLEMENTARITY (Physics), *PARADOX, *QUANTUM theory, *TRAJECTORIES (Mechanics), *EXTRAPOLATION

Abstract

fshar et al. claim that their experiment shows a violation of the complementarity inequality. In this work, we study their claim using a modified Mach-Zehnder setup that represents a simpler version of the Afshar experiment. We find that our results are consistent with Afshar et al. experimental findings. However, we show that within standard quantum mechanics the results of the Afshar experiment do not lead to a violation of the complementarity inequality. We show that their claim originates from a particular technique they use to analyze their results. In their analysis, they assume a classical concept, that particles have a definite trajectory before detection, thus, they obtain which-way information by particle detection plus path extrapolation by applying momentum conservation. This analysis technique is standard in experimental particle physics. Important discoveries such as the detection of vector bosons have been made through the application of this technique. We note that particle detection plus path extrapolation is a suitable technique within de Broglie-Bohm theory of quantum mechanics. [ABSTRACT FROM AUTHOR]

Published

2010

8. On the Complementarity of the Quadrature Observables.

Author

Lahti, Pekka and Pellonpää, Juha-Pekka

Subjects

*COMPLEMENTARITY (Physics), *QUADRATURE domains, *TOMOGRAPHY, *RADON transforms, *PHASE space

Abstract

In this paper we investigate the coupling properties of pairs of quadrature observables, showing that, apart from the Weyl relation, they share the same coupling properties as the position-momentum pair. In particular, they are complementary. We determine the marginal observables of a covariant phase space observable with respect to an arbitrary rotated reference frame, and observe that these marginal observables are unsharp quadrature observables. The related distributions constitute the Radon transform of a phase space distribution of the covariant phase space observable. Since the quadrature distributions are the Radon transform of the Wigner function of a state, we also exhibit the relation between the quadrature observables and the tomography observable, and show how to construct the phase space observable from the quadrature observables. Finally, we give a method to measure together with a single measurement scheme any complementary pair of quadrature observables. [ABSTRACT FROM AUTHOR]

Published

2010

9. On Visibility in the Afshar Two-Slit Experiment.

Author

Kastner, R. E.

Subjects

*ELECTROMAGNETIC interference, *ELECTRIC interference, *MAGNETIC fields, *COMPLEMENTARITY (Physics)

Abstract

A modified version of Young’s experiment by Shahriar Afshar indirectly reveals the presence of a fully articulated interference pattern prior to the post-selection of a particle in a “which-slit” basis. While this experiment does not constitute a violation of Bohr’s Complementarity Principle as claimed by Afshar, both he and many of his critics incorrectly assume that a commonly used relationship between visibility parameter V and “which-way” parameter K has crucial relevance to his experiment. It is argued here that this relationship does not apply to this experimental situation and that it is wrong to make any use of it in support of claims for or against the bearing of this experiment on Complementarity. [ABSTRACT FROM AUTHOR]

Published

2009

10. Coordinates with Non-Singular Curvature for a Time Dependent Black Hole Horizon.

Author

Lindesay, James

Subjects

*SUPERMASSIVE black holes, *MATHEMATICAL singularities, *COMPLEMENTARITY (Physics), *QUANTUM theory, *SPACETIME, *HYPERSPACE

Abstract

A naive introduction of a dependency of the mass of a black hole on the Schwarzschild time coordinate results in singular behavior of curvature invariants at the horizon, violating expectations from complementarity. If instead a temporal dependence is introduced in terms of a coordinate akin to the river time representation, the Ricci scalar is nowhere singular away from the origin. It is found that for a shrinking mass scale due to evaporation, the null radial geodesics that generate the horizon are slightly displaced from the coordinate singularity. In addition, a changing horizon scale significantly alters the form of the coordinate singularity in diagonal (orthogonal) metric coordinates representing the space-time. A Penrose diagram describing the growth and evaporation of an example black hole is constructed to examine the evolution of the coordinate singularity. [ABSTRACT FROM AUTHOR]

Published

2007

11. Paradox in Wave-Particle Duality.

Author

Afshar, Shahriar, Flores, Eduardo, McDonald, Keith, and Knoesel, Ernst

Subjects

*LIGHT, *HEISENBERG uncertainty principle, *ELECTROMAGNETIC waves, *COMPLEMENTARITY (Physics), *PARTICLES

Abstract

We report on the simultaneous determination of complementary wave and particle aspects of light in a double-slit type “welcher-weg” experiment beyond the limitations set by Bohr’s Principle of Complementarity. Applying classical logic, we verify the presence of sharp interference in the single photon regime, while reliably maintaining the information about the particular pinhole through which each individual photon had passed. This experiment poses interesting questions on the validity of Complementarity in cases where measurements techniques that avoid Heisenberg’s uncertainty principle and quantum entanglement are employed. We further argue that the application of classical concepts of waves and particles as embodied in Complementarity leads to a logical inconsistency in the interpretation of this experiment. [ABSTRACT FROM AUTHOR]

Published

2007

12. On the Character of Quantum Law: Complementarity, Entanglement, and Information

Author

Arkady Plotnitsky

Subjects

010308 nuclear & particles physics, General Physics and Astronomy, Quantum entanglement, 01 natural sciences, Complementarity (physics), Classical physics, Physics::History of Physics, Bohr model, symbols.namesake, Theoretical physics, 0103 physical sciences, symbols, Quantum information, 010306 general physics, Quantum information science, Quantum, Physical law, Mathematics

Abstract

This article considers the relationships between the character of physical law in quantum theory and Bohr’s concept of complementarity, under the assumption of the unrepresentable and possibly inconceivable nature of quantum objects and processes, an assumption that may be seen as the most radical departure from realism currently available. Complementarity, the article argues, is a reflection of the fact that, as against classical physics or relativity, the behavior of quantum objects of the same type, say, all electrons, is not governed by the same physical law in all contexts, specifically in complementary contexts. On the other hand, the mathematical formalism of quantum mechanics offers correct probabilistic or statistical predictions (no other predictions are possible on experimental grounds) in all contexts, here, again, under the assumption that quantum objects themselves and their behavior are beyond representation or even conception. Bohr, in this connection, spoke of “an entirely new situation as regards the description of physical phenomena that, the notion of complementarity aims at characterizing.” The article also considers the relationships among complementarity, entanglement, and quantum information, by basing these relationships on this understanding of complementarity.

Published

2017

13. Complementarity in Classical Dynamical Systems.

Author

beim Graben, Peter and Atmanspacher, Harald

Subjects

*COMPLEMENTARITY (Physics), *QUANTUM theory, *RANDOM dynamical systems, *PHASE space, *EPISTEMICS, *DISPERSION (Chemistry), *SYSTEMS theory

Abstract

The concept of complementarity, originally defined for non-commuting observables of quantum systems with states of non-vanishing dispersion, is extended to classical dynamical systems with a partitioned phase space. Interpreting partitions in terms of ensembles of epistemic states (symbols) with corresponding classical observables, it is shown that such observables are complementary to each other with respect to particular partitions unless those partitions are generating. This explains why symbolic descriptions based on an ad hoc partition of an underlying phase space description should generally be expected to be incompatible. Related approaches with different background and different objectives are discussed. [ABSTRACT FROM AUTHOR]

Published

2006

14. The Principle of Supplementarity: A Contextual Probabilistic Viewpoint to Complementarity, the Interference of Probabilities and Incompatibility of Variables in Quantum Mechanics.

Author

Khrennikov, Andrei

Subjects

*MATHEMATICAL models, *COMPLEMENTARITY (Physics), *QUANTUM theory, *WAVE-particle duality, *COMPACTIFICATION (Mathematics), *BOHR compactification, *PHYSICS

Abstract

We presented a contextual statistical model of the probabilistic description of physical reality. Here contexts (complexes of physical conditions) are considered as basic elements of reality. There is discussed the relation with QM. We propose a realistic analogue of Bohr’s principle of complementarity. In the opposite to the Bohr’s principle, our principle has no direct relation with mutual exclusivity for observables. To distinguish our principle from the Bohr’s principle and to give better characterization, we change the terminology and speak about supplementarity, instead of complementarity. Supplementarity is based on the interference of probabilities. It has quantitative expression trough a coefficient which can be easily calculated from experimental statistical data. We need not appeal to the Hilbert space formalism and noncommutativity of operators representing observables. Moreover, in our model there exists pairs of supplementary observables which cannot be represented in the complex Hilbert space. There are discussed applications of the principle of supplementarity outside quantum physics. [ABSTRACT FROM AUTHOR]

Published

2005

15. Complementarity and Scientific Rationality.

Author

Saunders, Simon

Subjects

*QUANTUM theory, *INCONSISTENCY (Logic), *MECHANICS (Physics), *COMPLEMENTARITY (Physics), *WAVE-particle duality, *PHYSICS

Abstract

Bohr’s interpretation of quantum mechanics has been criticized as incoherent and opportunistic, and based on doubtful philosophical premises. If so Bohr’s influence, in the pre-war period of 1927-1939, is the harder to explain, and the acceptance of his approach to quantum mechanics over de Broglie’s had no reasonable foundation. But Bohr’s interpretation changed little from the time of its first appearance, and stood independent of any philosophical presuppositions. The principle of complementarity is itself best read as a conjecture of unusually wide scope, on the nature and future course of explanations in the sciences (and not only the physical sciences). If it must be judged a failure today, it is not because of any internal inconsistency. [ABSTRACT FROM AUTHOR]

Published

2005

16. The EPR Paper and Bohr’s Response: A Re-Assessment.

Author

Whitaker, M. A. B.

Subjects

*QUANTUM theory, *COMPLEMENTARITY (Physics), *EINSTEIN-Podolsky-Rosen experiment, *INFORMATION theory, *PHYSICS

Abstract

For many years after Bohr's response to the EPR argument, Bohr was considered to have provided an authoritative rebuttal of the ideas of the paper, and more generally of Einstein's stance on quantum theory. More recently, however, there has been great difficulty even in achieving general agreement on Bohr's meaning. Two recent papers, by Dickson, and by Clifton and Halvorson, have sought to establish the structure of Bohr's argument. In the present paper, the papers of EPR and Bohr are re-assessed in the light of these recent papers, and also in light of the development and presentation of quantum information theory. [ABSTRACT FROM AUTHOR]

Published

2004

17. Indivisibility, Complementarity and Ontology: A Bohrian Interpretation of Quantum Mechanics

Author

Jairo Roldán-Charria

Subjects

Philosophy of science, Quantum decoherence, General Physics and Astronomy, Interpretations of quantum mechanics, Complementarity (physics), Epistemology, Universality (dynamical systems), Bohr model, Theoretical physics, symbols.namesake, Conceptual economy, Ontology, symbols, Mathematics

Abstract

The interpretation of quantum mechanics presented in this paper is inspired by two ideas that are fundamental in Bohr’s writings: indivisibility and complementarity. Further basic assumptions of the proposed interpretation are completeness, universality and conceptual economy. In the interpretation, decoherence plays a fundamental role for the understanding of measurement. A general and precise conception of complementarity is proposed. It is fundamental in this interpretation to make a distinction between ontological reality, constituted by everything that does not depend at all on the collectivity of human beings, nor on their decisions or limitations, nor on their existence, and empirical reality constituted by everything that not being ontological is, however, intersubjective. According to the proposed interpretation, neither the dynamical properties, nor the constitutive properties of microsystems like mass, charge and spin, are ontological. The properties of macroscopic systems and space-time are also considered to belong to empirical reality. The acceptance of the above mentioned conclusion does not imply a total rejection of the notion of ontological reality. In the paper, utilizing the Aristotelian ideas of general cause and potentiality, a relation between ontological reality and empirical reality is proposed. Some glimpses of ontological reality, in the form of what can be said about it, are finally presented.

Published

2014

18. On Visibility in the Afshar Two-Slit Experiment

Author

R. E. Kastner

Subjects

Quantum Physics, symbols.namesake, symbols, FOS: Physical sciences, General Physics and Astronomy, Double-slit experiment, Quantum Physics (quant-ph), Complementarity (physics), Mathematical economics, Mathematics, Bohr model

Abstract

A modified version of Young's experiment by Shahriar Afshar indirectly reveals the presence of a fully articulated interference pattern prior to the post-selection of a particle in a "which-slit" basis. While this experiment does not constitute a violation of Bohr's Complementarity Principle as claimed by Afshar, both he and many of his critics incorrectly assume that a commonly used relationship between visibility parameter V and "which-way" parameter K has crucial relevance to his experiment. It is argued here that this relationship does not apply to this experimental situation and that it is wrong to make any use of it in support of claims for or against the bearing of this experiment on Complementarity., Comment: Final version; to appear in Foundations of Physics

Published

2009

19. Reply to Comments of Steuernagel on the Afshar’s Experiment

Author

Eduardo V. Flores

Subjects

Wire grid, Maxima and minima, Quantum Physics, Theoretical physics, FOS: Physical sciences, General Physics and Astronomy, Quantum Physics (quant-ph), Maxima, Complementarity (physics), Afshar experiment, Mathematics

Abstract

We respond to criticism of our paper "Paradox in Wave-Paricle Duality for Non-Perturbative Measurements". We disagree with Steuernagel's derivation of the visibility of the Afshar experiment. To calculate the fringe visibility, Steuernagel utilizes two different experimental situations, i.e. the wire grid in the pattern minima and in the pattern maxima. In our assessment, this proceduere cannot lead to the correct result for the complementarity properties of wave-particle in one particular experimental set-up.

Published

2008

20. Paradox in Wave-Particle Duality

Author

Ernst Knoesel, Shahriar S. Afshar, Keith F. McDonald, and Eduardo V. Flores

Subjects

Physics, Quantum Physics, Photon, Uncertainty principle, Classical logic, FOS: Physical sciences, General Physics and Astronomy, Quantum entanglement, Complementarity (physics), Logical inconsistency, Bohr model, Theoretical physics, symbols.namesake, Wave–particle duality, symbols, Quantum Physics (quant-ph)

Abstract

We report on the simultaneous determination of complementary wave and particle aspects of light in a double-slit type "welcher-weg" experiment beyond the limitations set by Bohr's Principle of Complementarity. Applying classical logic, we verify the presence of sharp interference in the single photon regime, while reliably maintaining the information about the particular pinhole through which each individual photon had passed. This experiment poses interesting questions on the validity of Complementarity in cases where measurements techniques that avoid Heisenberg's uncertainty principle and quantum entanglement are employed. We further argue that the application of classical concepts of waves and particles as embodied in Complementarity leads to a logical inconsistency in the interpretation of this experiment., Comment: 18 pages, 1 figure

Published

2007

21. The Principle of Supplementarity: A Contextual Probabilistic Viewpoint to Complementarity, the Interference of Probabilities and Incompatibility of Variables in Quantum Mechanics

Author

Andrei Khrennikov

Subjects

Existential quantification, Probabilistic logic, Hilbert space, General Physics and Astronomy, Observable, Statistical model, Supplementarity, Complementarity (physics), Bohr model, symbols.namesake, Theoretical physics, Quantum mechanics, symbols, Mathematics

Abstract

We presented a contextual statistical model of the probabilistic description of physical reality. Here contexts (complexes of physical conditions) are considered as basic elements of reality. There is discussed the relation with QM. We propose a realistic analogue of Bohr’s principle of complementarity. In the opposite to the Bohr’s principle, our principle has no direct relation with mutual exclusivity for observables. To distinguish our principle from the Bohr’s principle and to give better characterization, we change the terminology and speak about supplementarity, instead of complementarity. Supplementarity is based on the interference of probabilities. It has quantitative expression trough a coefficient which can be easily calculated from experimental statistical data. We need not appeal to the Hilbert space formalism and noncommutativity of operators representing observables. Moreover, in our model there exists pairs of supplementary observables which cannot be represented in the complex Hilbert space. There are discussed applications of the principle of supplementarity outside quantum physics.

Published

2005

22. Appreciating a Hiley Respected Colleague

Author

Harald Atmanspacher, University of Zurich, and Atmanspacher, Harald

Subjects

Philosophy of science, Quantum potential, General Physics and Astronomy, 142-005 142-005, Complementarity (physics), Implicate and explicate order, 3100 General Physics and Astronomy, Epistemology, Schrödinger equation, Quantum nonlocality, symbols.namesake, Hidden variable theory, symbols, Holism

Abstract

Foundations of Physics, 43 (4), ISSN:1572-9516

Published

2013

23. On the Physical Reality of Quantum Waves

Author

Gennaro Auletta and Gino Tarozzi

Subjects

Physics, Philosophy of science, Physical reality, complementarity, ghostfield, virtual field, potentiality, empty wave, General Physics and Astronomy, Virtual field, Complementarity (physics), ghostfield, Classical mechanics, empty wave, Wave function, complementarity, ghost field, virtual field, potentiality, Quantum

Abstract

The main interpretations of the quantum-mechanical wave function are presented emphasizing how they can be divided into two ensembles: The ones that deny and the other ones that attribute a form of reality to quantum waves. It is also shown why these waves cannot be classical and must be submitted to the restriction of the complementarity principle. Applying the concept of smooth complementarity, it is shown that there can be no reason to attribute reality only to the events and not to the wave or to the initial state of a given system. Thereafter, an experiment proposed by the authors is presented, where it is shown that the wave-like behaviour allows predictions that are not allowed on the grounds of a particle-like behaviour. In conclusion, we upheld that quantum waves must be real even if they do not belong to the same ontological level of events, which connected with particle detections.

Published

2004

24. The EPR Paper and Bohr’s Response: A Re-Assessment

Author

M.A.B. Whitaker

Subjects

Physics, symbols.namesake, Philosophy of science, Theoretical physics, Rebuttal, symbols, General Physics and Astronomy, EPR paradox, Einstein, Quantum information, Complementarity (physics), Physics::History of Physics, Bohr model

Abstract

For many years after Bohr's response to the EPR argument, Bohr was considered to have provided an authoritative rebuttal of the ideas of the paper, and more generally of Einstein's stance on quantum theory. More recently, however, there has been great difficulty even in achieving general agreement on Bohr's meaning. Two recent papers, by Dickson, and by Clifton and Halvorson, have sought to establish the structure of Bohr's argument. In the present paper, the papers of EPR and Bohr are re-assessed in the light of these recent papers, and also in light of the development and presentation of quantum information theory.

Published

2004

25. [Untitled]

Author

Arkady Plotnitsky

Subjects

Philosophy of science, Stochastic interpretation, General Physics and Astronomy, Interpretations of quantum mechanics, Complementarity (physics), Physics::History of Physics, Bohr model, Minority interpretations of quantum mechanics, symbols.namesake, Theoretical physics, symbols, Copenhagen interpretation, Quantum, Mathematics

Abstract

Following Niels Bohr's interpretation of quantum mechanics as complementarity, this article argues that quantum mechanics may be seen as a theory of, in N. David Mermin's words, “correlations without correlata,” understood here as the correlations between certain physical events in the classical macro world that at the same time disallow us to ascertain their quantum-level correlata.

Published

2003

26. [Untitled]

Author

Willem M. de Muynck

Subjects

Formalism (philosophy of mathematics), Philosophy of science, Inequality, Quantum mechanics, media_common.quotation_subject, General Physics and Astronomy, Observable, Copenhagen interpretation, Complementarity (physics), Mathematics, media_common

Abstract

In the Copenhagen interpretation the Heisenberg inequality ΔQΔP≥ℏ/2 is interpreted as the mathematical expression of the concept of complementarity, quantifying the mutual disturbance necessarily taking place in a simultaneous or joint measurement of incompatible observables. This interpretation was criticized a long time ago and has recently been challenged in an experimental way. These criticisms can be substantiated by using the generalized formalism of positive operator-valued measures, from which an inequality, different from the Heisenberg inequality, can be derived, precisely illustrating the Copenhagen concept of complementarity. The different roles of preparation and measurement in creating uncertainty in quantum mechanics are discussed.

Published

2000

27. [Untitled]

Author

Janneke van Lith and Jos Uffink

Subjects

Physics, Canonical ensemble, symbols.namesake, Thermal isolation, Thermally isolated system, Quantum mechanics, Boltzmann constant, symbols, General Physics and Astronomy, Mandelbrot set, Quantum, Complementarity (physics), Bohr model

Abstract

Bohr and Heisenberg suggested that the thermodynamical quantities of temperature and energy are complementary in the same way as position and momentum in quantum mechanics. Roughly speaking their idea was that a definite temperature can be attributed to a system only if it is submerged in a heat bath, in which case energy fluctuations are unavoidable. On the other hand, a definite energy can be assigned only to systems in thermal isolation, thus excluding the simultaneous determination of its temperature. Rosenfeld extended this analogy with quantum mechanics and obtained a quantitative uncertainty relation in the form ΔU Δ(1/T) ≥ k, where k is Boltzmann's constant. The two “extreme” cases of this relation would then characterize this complementarity between isolation (U definite) and contact with a heat bath (T definite). Other formulations of the thermodynamical uncertainty relations were proposed by Mandelbrot (1956, 1989), Lindhard (1986), and Lavenda (1987, 1991). This work, however, has not led to a consensus in the literature. It is shown here that the uncertainty relation for temperature and energy in the version of Mandelbrot is indeed exactly analogous to modern formulations of the quantum mechanical uncertainty relations. However, his relation holds only for the canonical distribution, describing a system in contact with a heat bath. There is, therefore, no complementarily between this situation and a thermally isolated system.

Published

1999

28. The nature of Einstein's objections to the Copenhagen interpretation of quantum mechanics

Author

Michel Paty, Recherches Epistémologiques et Historiques sur les Sciences Exactes et les Institutions Scientifiques (REHSEIS (UMR_7596)), Université Paris Diderot - Paris 7 (UPD7)-Centre National de la Recherche Scientifique (CNRS), and Roux, Marie

Subjects

Copenhagen, General Physics and Astronomy, Bohm, 01 natural sciences, Dialectica, [SHS.HISPHILSO]Humanities and Social Sciences/History, Philosophy and Sociology of Sciences, Minority interpretations of quantum mechanics, symbols.namesake, Rosen, [SHS.HISPHILSO] Humanities and Social Sciences/History, Philosophy and Sociology of Sciences, Quantum mechanics, 0103 physical sciences, Einstein, 010306 general physics, Copenhagen interpretation, Bell, Max Born, Mathematics, Consistent histories, 010308 nuclear & particles physics, quantum mechanics, Interpretations of quantum mechanics, quantum theory, 16. Peace & justice, Complementarity (physics), Physics::History of Physics, Heisenberg, symbols, quantum physics, EPR, Relational approach to quantum physics, Podolsky, Schrödinger's cat

Abstract

In what follows, I examine three main points which may help us to understand the deep nature of Einstein's objections to quantum mechanics. After having played a fundamental pioneer role in the birth of quantum physics, Einstein was, as it is well known, far less enthusiastic about its constitution as a quantum mechanics and, since 1927, he constantly argued against the pretention of its founders and proponents to have settled a definitive and complete theory. I emphasize first the importance of the philosophical climate, which was dominated by the Copenhagen orthodoxy and Bohr's idea of complementarity : what Einstein was primarily reluctant to was to accept the fundamental character of quantum mechanics as such, and to modify for it the basic principles of knowledge. I thus stress the main lines of Einstein's own programme in respect to quantum physics, which is to be considered in relation with his other contemporary attempts and achievements. Finally, I show how Einstein's arguments, when dealing with his objections, have been fruitful and some of them still worthy, with regard to recent developments concerning local non-separability as well as concerning the problems of completeness and accomplishment of quantum theory.

Published

1995

29. On the Wootters-Zurek development of Einstein's two-slit experiment

Author

P. N. Kaloyerou

Subjects

Condensed Matter::Quantum Gases, Theoretical physics, symbols.namesake, Classical mechanics, symbols, General Physics and Astronomy, Double-slit experiment, Quantum Physics, Einstein, Information theory, Wave function, Complementarity (physics), Mathematics

Abstract

We consider the compatibility of the Wootters and Zurek development of information theory as applied to the two-slit experiment with the principle of complementarity. We also consider the limitations of aspects of Wootters and Zurek's analysis, and, independently of complementarity, the extent to which Wootters and Zurek's information theory can be considered a fundamental interpretation of the quantum theory (as applied to particle-wave duality). The question of particle-wave uncertainty relations will also be taken up.

Published

1992

30. The problem of the imperfection of a world, itself created by a perfect god

Author

André Mercier

Subjects

symbols.namesake, Philosophy of science, Theoretical physics, symbols, General Physics and Astronomy, Complementarity (physics), Bohr model, Mathematics

Abstract

The two main arguments concern(1) the presence of an “enlightened complementarity” between philosophic (including scientific) and religious (not including mystic) thought, and(2) the necessity to postulate a “threefold relationship” whenever one is to gain knowledge of any kind. They are both inspired by physics (from Bohr's “strict complementarity”, resp. from Newton's fundamental postulate).

Published

1992

31. On Bohr's response to EPR: II

Author

Jeffrey Bub

Subjects

symbols.namesake, Pure mathematics, Subalgebra, symbols, General Physics and Astronomy, Observable, Complementarity (physics), Physics::History of Physics, Mathematics, Bohr model

Abstract

In my reconstruction of Bohr's reply to the Einstein-Podolsky-Rosen argument, I pointed out that Bohr showed explicitly, within the framework of the complementarity interpretation, how a locally maximal measurement on a subsystem S2 of a composite system S1+S2, consisting of two spatially separated subsystems, can make determinate both a locally maximal Boolean subalgebra for S2 and a locally maximal Boolean subalgebra for S1. As it stands, this response is open to an objection. In this note, I show that meeting the objection requires a modification of the complementarity thesis concerning what propositions can be taken as determinate, or what observables can be raken to have values, in a given measurement context.

Published

1990

32. On the energy-time uncertainty relation. Part I: Dynamical time and time indeterminacy

Author

Paul Busch

Subjects

Thought experiment, Theoretical physics, General Physics and Astronomy, Observable, Complementarity (physics), Quantum, Physics::History of Physics, Quantum indeterminacy, Mathematics

Abstract

The problem of the validity and interpretation of the energy-time uncertainty relation is briefly reviewed and reformulated in a systematic way. The Bohr-Einsteinphoton-box gedanken experiment is seen to illustrate the complementarity of energy andevent time. A more recent experiment with amplitude-modulated Mosbauer quanta yields evidence for the genuine quantum indeterminacy of event time. In this way, event time arises as a quantum observable.

Published

1990

33. Complementarity and scientific rationality

Author

Simon Saunders

Subjects

Quantum Physics, Conjecture, Philosophy, FOS: Physical sciences, General Physics and Astronomy, Interpretations of quantum mechanics, Complementarity (physics), Physics::History of Physics, Presupposition, Epistemology, Bohr model, symbols.namesake, symbols, Scientific rationality, Matter wave, Quantum Physics (quant-ph)

Abstract

Bohr's interpretation of quantum mechanics has been criticized as incoherent and opportunistic, and based on doubtful philosophical premises. If so Bohr's influence, in the pre-war period of 1927-1939, is the harder to explain, and the acceptance of his approach to quantum mechanics over de Broglie's had no reasonable foundation. But Bohr's interpretation changed little from the time of its first appearance, and stood independent of any philosophical presuppositions. The principle of complementarity is itself best read as a conjecture of unusually wide scope, on the nature and future course of explanations in the sciences (and not only the physical sciences). If it must be judged a failure today, it is not because of any internal inconsistency., 29 pages

Published

2005

34. On Bohr's response to EPR: A quantum logical analysis

Author

Jeffrey Bub

Subjects

symbols.namesake, Pure mathematics, Truth value, Subalgebra, Truth table, symbols, General Physics and Astronomy, Fuzzy subalgebra, Boolean algebras canonically defined, Quantum, Complementarity (physics), Bohr model, Mathematics

Abstract

Bohr's complementarity interpretation is represented as the relativization of the quantum mechanical description of a system to the maximal Boolean subalgebra (in the non-Boolean logical structure of the system) selected by a classically described experimental arrangement. Only propositions in this subalgebra have determinate truth values. The concept of a minimal revision of a Boolean subalgebra by a measurement is defined, and it is shown that the nonmaximal measurement of spin on one subsystem in the spin version of the Einstein—Podolsky—Rosen experiment actually selects an appropriate maximal Boolean subalgebra ℛ′ in the logical structure of the composite system, via a minimal revision of the maximal Boolean subalgebra & associated with the preparation of the singlet spin state. This provides an explanation for the determinate truth values of propositions in ℛ′ referring to the second subsystem within the framework of the complementarity interpretation.

Published

1989

35. Niels Bohr's discussions with Albert Einstein, Werner Heisenberg, and Erwin Schrödinger: The origins of the principles of uncertainty and complementarity

Author

Jagdish Mehra

Subjects

Uncertainty principle, General Physics and Astronomy, Complementarity (physics), Physics::History of Physics, Schrödinger equation, Bohr model, symbols.namesake, Theoretical physics, symbols, Einstein, Copenhagen interpretation, Wave function, Schrödinger's cat, Mathematics, Mathematical physics

Abstract

In this paper, the main outlines of the discussions between Niels Bohr with Albert Einstein, Werner Heisenberg, and Erwin Schrodinger during 1920–1927 are treated. From the formulation of quantum mechanics in 1925–1926 and wave mechanics in 1926, there emerged Born's statistical interpretation of the wave function in summer 1926, and on the basis of the quantum mechanical transformation theory—formulated in fall 1926 by Dirac, London, and Jordan—Heisenberg formulated the uncertainty principle in early 1927. At the Volta Conference in Como in September 1927 and at the fifth Solvay Conference in Brussels the following month, Bohr publicly enunciated his complementarity principle, which had been developing in his mind for several years. The Bohr-Einstein discussions about the consistency and completeness of qnautum mechanics and of physical theory as such—formally begun in October 1927 at the fifth Solvay Conference and carried on at the sixth Solvay Conference in October 1930—were continued during the next decades. All these aspects are briefly summarized.

Published

1987

36. Complementarity, context dependence, and quantum logic

Author

Patrick A. Heelan

Subjects

Pure mathematics, Theoretical physics, Quantum dynamics, Categorical quantum mechanics, Quantum process, Quantum operation, General Physics and Astronomy, Gleason's theorem, Quantum statistical mechanics, Complementarity (physics), Quantum logic, Mathematics

Abstract

Quantum-mechanical event descriptions are context-dependent descriptions. The role of quantum (nondistributive) logic is in the partial ordering of contexts rather than in the ordering of quantum-mechanical events. Moreover, the kind of quantum logic displayed by quantum mechanics can be easily inferred from the general notion of contextuality used in ordinary language. The formalizable core of Bohr's notion of complementarity is the type of context dependence discussed in this paper.

Published

1970

37. The mechanics of individuality in nature

Author

Stanford Goldman

Subjects

Physics, Theoretical physics, Philosophy of science, General Physics and Astronomy, Fermion, Complementarity (physics), Eigenvalues and eigenvectors, Boson

Abstract

Evidence is presented to support the hypothesis that there is a set of basically similar phenomena or characteristics of physics, biology, and sociology. Six of these are identified. Five of them are usually associated with quantum mechanics. They are the existence of eigenstates, transform domains, bosons and fermions, particles and antiparticles, and complementarity. The sixth, namely alternation of generation, is usually associated with biology. The hypothesis leads to some new points of view and interpretations in biology, sociology, and physics.

Published

1971