Quantum noise and spatiotemporal pattern formation in nonlinear optics  Morten Bache
 Abstract  This work concerns analytical and numerical investigations of cavity enhanced x2 frequency conversion processes, specifically secondharmonic generation (SHG). We focus on how the transverse degrees of freedom affect the dynamics, where the interaction between nonlinearity and diffraction gives rise to spatially modulated structures, patterns.
The two main parts of the thesis are the classical model and the quantum mechanical model, the latter being an extension of the former by including the inherent quantum fluctuations of light. From a theoretical point of view the classical dynamics are investigated with an experimental implementation in mind. Thus, we study the internally
pumped optical parametric oscillator (IPOPO) as an experimentally more realistic model than the usual SHG model. In the IPOPO a competing process to SHG is taken into account, where the generated second harmonic drives a nondegenerate parametric oscillation. We find that this model may completely stabilize the instabilities normally
expected in SHG, but it may also give rise to entirely new phenomena, such as oscillating cavity solitons, intensity spirals and selfpulsing solutions. Especially the selfpulsing is important in the singly resonant cavity setup, where the first experimental observation of the fast oscillating selfpulsing solutions is shown. The IPOPO model confirms very well the oscillation frequencies as well as the regions of stability observed in the experiment.
The quantum mechanical investigations concern two different setups. Using a quantum mechanical model of SHG we investigate the effect of the quantum fluctuations on pattern formation in the system. Strong spatial correlations are observed between symmetrical points in the farfield, including crosscorrelations between the fundamental and
secondharmonic field, and the distinct peaks at the critical wave numbers reveal a quantum image. A microscopical model is suggested as a guide to understanding the processes involved in producing a classical pattern. Finally, the quantum nature of the correlations leads to spatial multimode nonclassical light, which is revealed by
twinbeam correlations between symmetrical points in the farfield, and the correlations are shown to survive above the pattern formation threshold. The presence of quantum noise is also investigated in a model consisting of two SHG waveguides in a cavity. Due to interaction of evanescent waves the waveguides are spatially coupled, and this gives rise to strong violations of the standard quantum limit in the twinbeam correlations. Particularly strong quantum correlations are observed when several instabilities are competing, and complete suppression of the noise is found near bistable transition points.  Keywords  Nonlinear optics, Pattern formation, Optical cavities, Quadratic optical nonlinearities, Quantum optics, Squeezing and subPoissonian statistics, Quantum imaging and spatial behaviour of nonclassical light  Type  Ph.D. thesis [Academic thesis]  Year  2002  Publisher  Informatics and Mathematical Modelling, Technical University of Denmark, DTU  Address  Richard Petersens Plads, Building 321, DK2800 Kgs. Lyngby  Series  IMMPHD2002101  BibTeX data  [bibtex]  IMM Group(s)  Mathematical Physics 
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