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Quantum chaos
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== Correlating statistical descriptions of quantum mechanics with classical behaviour == [[File:Qdfels.jpg|400px|right|thumb|Nearest neighbour distribution for [[Rydberg atom]] energy level spectra in an electric field as quantum defect is increased from 0.04 (a) to 0.32 (h). The system becomes more chaotic as dynamical symmetries are broken by increasing the quantum defect; consequently, the distribution evolves from nearly a Poisson distribution (a) to that of [[Random matrix#Gaussian ensembles|Wigner's surmise]] (h).]] Statistical measures of quantum chaos were born out of a desire to quantify spectral features of complex systems. [[Random matrix]] theory was developed in an attempt to characterize spectra of complex nuclei. The remarkable result is that the statistical properties of many systems with unknown Hamiltonians can be predicted using random matrices of the proper symmetry class. Furthermore, random matrix theory also correctly predicts statistical properties of the eigenvalues of many chaotic systems with known Hamiltonians. This makes it useful as a tool for characterizing spectra which require large numerical efforts to compute. A number of statistical measures are available for quantifying spectral features in a simple way. It is of great interest whether or not there are universal statistical behaviors of classically chaotic systems. The statistical tests mentioned here are universal, at least to systems with few degrees of freedom ([[Michael Berry (physicist)|Berry]] and Tabor<ref>{{Cite journal |date=1977-09-15 |title=Level clustering in the regular spectrum |journal=Proceedings of the Royal Society of London. A. Mathematical and Physical Sciences |language=en |volume=356 |issue=1686 |pages=375–394 |doi=10.1098/rspa.1977.0140 |bibcode=1977RSPSA.356..375B |issn=0080-4630 |last1=Berry |first1=M. V. |last2=Tabor |first2=M. }}</ref> have put forward strong arguments for a Poisson distribution in the case of regular motion and Heusler et al.<ref>{{Cite journal |last1=Heusler |first1=Stefan |last2=Müller |first2=Sebastian |last3=Altland |first3=Alexander |last4=Braun |first4=Petr |last5=Haake |first5=Fritz |date=January 2007 |title=Periodic-Orbit Theory of Level Correlations |journal=Physical Review Letters |language=en |volume=98 |issue=4 |page=044103 |doi=10.1103/PhysRevLett.98.044103 |pmid=17358777 |arxiv=nlin/0610053 |bibcode=2007PhRvL..98d4103H |issn=0031-9007}}</ref> present a semiclassical explanation of the so-called Bohigas–Giannoni–Schmit conjecture which asserts universality of spectral fluctuations in chaotic dynamics). The nearest-neighbor distribution (NND) of energy levels is relatively simple to interpret and it has been widely used to describe quantum chaos. Qualitative observations of level repulsions can be quantified and related to the classical dynamics using the NND, which is believed to be an important signature of classical dynamics in quantum systems. It is thought that regular classical dynamics is manifested by a [[Poisson distribution]] of energy levels: : <math>P(s) = e^{-s}.\ </math> In addition, systems which display chaotic classical motion are expected to be characterized by the statistics of random matrix eigenvalue ensembles. For systems invariant under time reversal, the energy-level statistics of a number of chaotic systems have been shown to be in good agreement with the predictions of the Gaussian orthogonal ensemble (GOE) of random matrices, and it has been suggested that this phenomenon is generic for all chaotic systems with this symmetry. If the normalized spacing between two energy levels is <math>s</math>, the normalized distribution of spacings is well approximated by : <math>P(s) = \frac{\pi}{2}se^{-\pi s^2/4}.</math> Many Hamiltonian systems which are classically integrable (non-chaotic) have been found to have quantum solutions that yield nearest neighbor distributions which follow the Poisson distributions. Similarly, many systems which exhibit classical chaos have been found with quantum solutions yielding a [[Wigner surmise|Wigner-Dyson distribution]], thus supporting the ideas above. One notable exception is diamagnetic lithium which, though exhibiting classical chaos, demonstrates Wigner (chaotic) statistics for the even-parity energy levels and nearly Poisson (regular) statistics for the odd-parity energy level distribution.<ref>{{Cite journal |last1=Courtney |first1=Michael |last2=Kleppner |first2=Daniel |date=January 1996 |title=Core-induced chaos in diamagnetic lithium |journal=Physical Review A |language=en |volume=53 |issue=1 |pages=178–191 |doi=10.1103/PhysRevA.53.178 |pmid=9912872 |bibcode=1996PhRvA..53..178C |issn=1050-2947}}</ref>
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