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Semi-classics for non- integrable systems Lecture 8 of “Introduction to Quantum Chaos”
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Kicked oscillator: a model of Hamiltonian chaos 5/8 1/2 Poincare-Birkhoff fixed point theorem Homoclinic tangle: generic chaos Tori which survives the onset of chaos in phase space the longest has action given by the “golden mean”. Cantorous Homoclinic tangle
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Localization and resonance in quantum chaotic systems Previous lecture: A system that is classically diffusive can be dynamically localized in the analogous quantum case, e.g., kicked rotator, but also can show quantum resonances (Lecture 4) Quantum Classical
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Universal and non-universal features of quantum chaotic systems Universal features of eigenvalue spacing. Quantum scaring of the wavefunction.
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Classical phase space of non-integrable system is not motion on d-dimensional torus – whorls and tendrils of topologically mixing phase space. Usual semi-classical approach (as we will see) relies on motion on a torus. Semi-classics of quantum chaotic systems
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WKB approximation neglect in semi-classical limit Can now integrate to find S and A.
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Stationary phase approximation
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Semi-classics for integrable systems Position space Momentum space Fourier transform to obtain wavefunction in momentum space and then use stationary phase approximation.
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Semi-classics for integrable systems Solution valid at classical turning point But breaks down here! Hence, switch back to position space
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Semi-classics for integrable systems Phase has been accumulated from the turning point! Again, use stationary phase approximation Maslov index Bohr-Sommerfeld quantisation condition with Maslov index
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Feynmann path integral result for the propagator Useful (classical) relations Semiclassical propagator Semiclassical Green’s function Monodromy matrix Gutzwiller trace formula Semi-classics where the corresponding classical system is not integrable Road map for semi-classics for non-integrable systems:
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Feynmann path integral result for the propagator
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Feynman path integral; integral over all possible paths (not only classically allowed ones).
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Useful (classical) relations
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The semiclassical propagator Only classical trajectories allowed!
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The semiclassical propagator
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Caustic Focus Zero’s of D correspond to caustics or focus points.
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The semiclassical propagator Example: propagation of Gaussian wave packet Maslov index: equal to number of zero’s of inverse D
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The semiclassical propagator
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The semiclassical Green’s function
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Require in terms of action and not Hamilton’s principle function Evaluating the integral with stationary phase approximation leads to
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The semiclassical Green’s function
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Finally find
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Monodromy matrix
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For periodic system monodromy matrix coordinate independent
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Gutzwiller trace formula
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Only periodic orbits contribute to semi-classical spectrum!
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Gutzwiller trace formula
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Semiclassical quantum spectrum given by sum of periodic orbit contributions
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