Monitoring the Decoherence of Mesoscopic Quantum Superpositions in a Cavity

Raimond, Jean‐Michel; Haroche, S.

doi:10.1007/978-3-7643-7808-0_2

Cited by 3 publications

(4 citation statements)

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“…A description of the Cavity Quantum Electrodynamic (CQED) experimental system upon which the SEA-QT theoretical model is based is given in [73,[106][107][108][109][110][111]. A very brief description is provided here beginning with the experimental configuration depicted in In this manner, an entanglement between the states of the constituents is created.…”

Section: Sea-qt: Composite Atom-field System Resultsmentioning

confidence: 99%

“…Their efforts are attempts at building thermodynamics and irreversibility directly into the quantum dynamical level of description under the assumption that entropy and irreversibility have a microscopic foundation. Although there is no conclusive empirical evidence to prove these theories right or wrong, there is some empirical evidence, as seen, for example, in Sections 3.2 and 3.3 above, to at least suggest that one of these approaches, i.e., IQT, may indeed be a reasonable physical explanation for the phenomena of decoherence and decorrelation recently experimentally reported at a microscopic level [106][107][108][109][110][111][112][113]116]. Furthermore, although the validity of the ansatz of a fundamental nonlinearity at the quantum level of description has often been criticized as incompatible with the so-called "no-signaling condition", recent work by Ferreo, Salgado, and Sánchez-Gómez [132] suggests that nonlinear quantum evolution is in principle perfectly compatible with the impossibility of supraluminal communication, thus, reopening the discussion of fundamental non-linearity from this standpoint as well.…”

Section: Emergent Versus Fundamental Non-linearitymentioning

confidence: 99%

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Some Trends in Quantum Thermodynamics

Spakovsky

Gemmer

2014

Entropy

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Abstract:Traditional answers to what the 2nd Law is are well known. Some are based on the microstate of a system wandering rapidly through all accessible phase space, while others are based on the idea of a system occupying an initial multitude of states due to the inevitable imperfections of measurements that then effectively, in a coarse grained manner, grow in time (mixing). What has emerged are two somewhat less traditional approaches from which it is said that the 2nd Law emerges, namely, that of the theory of quantum open systems and that of the theory of typicality. These are the two principal approaches, which form the basis of what today has come to be called quantum thermodynamics. However, their dynamics remains strictly linear and unitary, and, as a number of recent publications have emphasized, "testing the unitary propagation of pure states alone cannot rule out a nonlinear propagation of mixtures". Thus, a non-traditional approach to capturing such a propagation would be one which complements the postulates of QM by the 2nd Law of thermodynamics, resulting in a possibly meaningful, nonlinear dynamics. An unorthodox approach, which does just that, is intrinsic quantum thermodynamics and its mathematical framework, steepest-entropy-ascent quantum thermodynamics. The latter has evolved into an effective tool for modeling the dynamics of reactive and non-reactive systems at atomistic scales. It is the usefulness of this framework in the context of quantum thermodynamics as well as the theory of typicality which are discussed here in some detail. A brief discussion of some other trends such as those related to work, work extraction, and fluctuation theorems is also presented. OPEN ACCESSEntropy 2014, 16 3435

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Section: Sea-qt: Composite Atom-field System Resultsmentioning

confidence: 99%

Section: Emergent Versus Fundamental Non-linearitymentioning

confidence: 99%

Some Trends in Quantum Thermodynamics

Spakovsky

Gemmer

2014

Entropy

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“…(Haroche, 2012, pp. 90-91) Similar experiments are reported in Bernu et al (2008), Bertet et al (2002), Davidovich et al (1996), Deléglise et al (2008), Raimond et al (2001) and Raimond and Haroche (2005). Let us consider more carefully a study of this type titled "Scheme to probe the decoherence of a macroscopic object" (Bose et al, 1999).…”

Section: Schrödinger's Catmentioning

confidence: 60%

Yes, More Decoherence: A Reply to Critics

Crull

2017

Found Phys

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“… Such experiments notably include the creation of Schrödinger ‘kittens’ (a gentle introduction to this sort of experimental work is given in the work of Raimond and Haroche ) and the experiments in molecular interferometry referenced above in Section 2.4.…”

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confidence: 99%

Exploring Philosophical Implications of Quantum Decoherence

Crull

2013

Philosophy Compass

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Quantum decoherence is receiving a great deal of attention today not only in theoretical and experimental physics but also in branches of science as diverse as molecular biology, biochemistry, and even neuropsychology. It is no surprise that it is also beginning to appear in various philosophical debates concerning the fundamental structure of the world. The purpose of this article is primarily to acquaint non‐specialists with quantum decoherence and clarify related concepts, and secondly to sketch its possible implications – independent of particular interpretations of quantum mechanics – for broader philosophical debates. For example, decoherence shows that any method of parsing nature into levels or parts cannot be in principle but instead derives from our perception of the world as classical, a perception that is itself sustained by the process of decoherence.

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Monitoring the Decoherence of Mesoscopic Quantum Superpositions in a Cavity

Cited by 3 publications

References 48 publications

Some Trends in Quantum Thermodynamics

Some Trends in Quantum Thermodynamics

Yes, More Decoherence: A Reply to Critics

Exploring Philosophical Implications of Quantum Decoherence

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