Theory Advances in High-Precision Two-Photon Spectroscopy

Haas, Martin

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Theory Advances in High-Precision Two-Photon Spectroscopy

Haas, M. (2006). Theory Advances in High-Precision Two-Photon Spectroscopy. PhD Thesis, Ruprecht-Karls-Universität Heidelberg, Heidelberg.

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Item Permalink: https://hdl.handle.net/11858/00-001M-0000-0011-870E-C Version Permalink: https://hdl.handle.net/11858/00-001M-0000-0011-870F-A

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Creators:
Haas, Martin¹, Author

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1Division Prof. Dr. Christoph H. Keitel, MPI for Nuclear Physics, Max Planck Society, ou_904546

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Abstract: ¨ High-precision two-photon spectroscopy of hydrogen and hydrogenlike systems constitutes an exceptional tool for experimental tests of fundamental theories. In the analysis of these experiments, theory also plays a vital role in the modeling of time-resolved spectra, the calculation of precise transition matrix elements, and the correction of a number of systematic e ects. This thesis gives a detailed analysis of the relevant two-photon excitation dynamics, starting from the single-atom response and leading to a Monte Carlo model which can be used for the analysis of atomic beam experiments. Dynamic polarizabilities of relevant S and D states, quantifying the dynamic Stark shift, and transition matrix elements among these states are calculated, taking into account leading-order relativistic, radiative and non-dipole laser-field e ects. An important broadening e ect of the experimentally observed spectra in the hydrogen 1S 2S spectroscopy experiment at the Max Planck Institut f¨ur Quantenoptik (MPQ) is identified and quantitatively described, as well as systematic frequency shifts. Corresponding possible improvements to the experimental setup are proposed. By combining the results of repeated MPQ hydrogen 1S 2S measurements and other experiments, in collaboration with the MPQ group, separate stringent limits on the possible drift of the magnetic moment of the cesium nucleus and the finestructure constant are deduced.

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Language(s): eng - English

Dates: Accepted: 2006

Publication Status: Accepted / In Press

Pages: 160

Publishing info: Heidelberg : Ruprecht-Karls-Universität Heidelberg

Table of Contents: 1 Introduction
2 Two-Photon Excitation Dynamics
2.1 Introduction
2.2 Basic quantum dynamics
2.2.1 Analytic solution for constant intensity
2.2.2 Quantum dynamics including spontaneous decay
2.3 Generalizations of the equations of motion
2.3.1 Motion in a standing wave and time-dependent intensity 2.3.2 Further generalizations
2.4 Analytic solution including ionization and spontaneous decay
3 Transition Matrix Elements and Dynamic Polarizability
3.1 Introduction
3.2 Overview of the interactions of atom, laser mode and vacuum
3.2.1 Second-order perturbation
3.2.2 Fourth order perturbation
3.2.3 Transition matrix elements
3.3 Calculation of two-photon transition matrix elements
3.3.1 Calculational method
3.3.2 Results for two-photon transitions
3.4 Dynamic Stark e ect
3.4.1 Classical field approach
3.4.2 Second-quantized approach
3.5 Calculation of the AC Stark shift
3.5.1 Matrix elements
3.5.2 Results for two-photon transitions
3.6 Calculation of the photoionization cross section
3.7 Combined induced-spontaneous two-photon decay
3.8 Conclusion
4 Relativistic and Radiative Corrections to Dynamic Processes
4.1 Perturbation to the dynamic polarizability
4.2 Perturbation to the transition matrix element
4.3 Potential for relativistic corrections
4.4 Potential for radiative corrections
4.5 Calculation of relativistic and radiative corrections
4.5.1 Wavefunction contributions
4.5.2 Eigenenergy contributions
4.5.3 Hamiltonian contributions
4.5.4 Results for S S transitions
4.6 Beyond the dipole approximation
4.6.1 Field-configuration dependent corrections
4.6.2 Results for two-photon transitions
4.7 Lamb shift of laser dressed states
5 Monte Carlo Investigations and Lineshape
5.1 Introduction
5.2 Experimental setup
5.3 Implementation of the simulation
5.4 Photoionization broadening of the 1S 2S transition line shape
5.4.1 Introduction
5.4.2 Experimentally observed broadening and shift coe cients
5.4.3 Simulated broadening and shift coe cients
5.4.4 Comparison .
5.4.5 Laser line width
5.5 E ects of nozzle freezing
5.6 E ect of laser beam misalignment
5.6.1 The αθ-term
5.6.2 The α²-term
5.7 Conclusion
6 1S-2S Spectroscopy and Possible Drift of Fundamental Constants
6.1 Data analysis and systematic effects
6.1.1 MPQ data analysis procedure
6.1.2 Models for the velocity distribution
6.1.3 Full line shape model and Lorentz data analysis
6.1.4 Weighting and Χ²r in the data regression
6.1.5 Effect of unsteady power calibration
6.1.6 Freezing nozzle
6.1.7 Power-dependent line shape model
6.2 Test of the drift of fundamental constants
6.2.1 Introduction
6.2.2 Analysis of the laboratory measurements
6.2.3 Results
7 Conclusion 133 7.1 General conclusion
7.2 Proposals for future experiments
A Some comparisons with the literature
A.1 The 1S-2S transition
A.2 The 1S-3S transition
A.3 Light shifts
B Explicit Polarizabilities and Transition Matrix Elements Bibliography

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Identifiers: eDoc: 284650

Degree: PhD

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