Laser self-Raman dobrado intracavidade de alta potência CW operante na região amarela do espectro eletromagnético de aplicações oftalmológicas / High power intracavity doubled CW self-Raman laser operating in the yellow range of electromagnetic spectra of ophthalmological applications

Ortega, Tiago Almeida

18 August 2011

Este trabalho tem por objetivo o desenvolvimento e otimização de uma cavidade laser self-Raman de aplicações oftalmológicas. A cavidade laser é do tipo estado sólido bombeada longitudinalmente por um diodo laser infravermelho. A cavidade é dita self-Raman pois um cristal Raman intracavidade faz o papel de meio ativo e deslocador Raman. Esse tipo de configuração é extremamente vantajoso uma vez que promove uma redução dimensional, de custos e de perdas intracavidade. Outro elemento não linear intracavidade é responsável pela geração do segundo harmônico da primeira linha Stokes gerada pelo cristal Raman. Dessa maneira obtém-se radiação em 586.5 nm da cavidade laser, o que corresponde a porção amarela do espectro eletromagnético. Essa região amarelo-alaranjada do espectro é de muita importância e aplicabilidade na indústria, ciências e na medicina. Na oftalmologia, em particular, é de enorme interesse que se construa um laser amarelo para fotocoagulação da retina uma vez que há muito tempo sabe-se que essa porção do espectro possui uma absorção desprezível pela Xantofila, cromóforo abundantemente presente na mácula. A mácula é a porção da retina responsável pela visão central e não deve absorver radiação laser pois isso seria desastroso para o paciente. / The objective of this work is the development and optimization of a self-Raman laser cavity with ophthalmological applications. The laser cavity is a longitudinally diode pumped solid state laser. The laser cavity is so-called self-Raman because an intracavity Raman crystal plays a role as an active media and Raman shifter. This type of configuration is extremely advantageous because it promotes a reduction in costs, dimensions and intracavity losses. Another non linear intracavity element is responsible for the second harmonic generation of the first Stokes line generated by the Raman crystal. Thereby one obtains 586.5 nm radiation coming out of the laser cavity, a wavelength in the yellow portion of the electromagnetic spectra. This yellow-orange range of the spectra is of great importance because and has many and increasingly applications in science, industry and medicine. Particularly in ophthalmology, a yellow laser for retina photocoagulation is of great interest once it is well known that this portion of the spectra is negligibly absorbed by the Xanthophylls, pigment strongly present at the macula. The macula is the portion of the retina responsible for the central vision and because of this laser absorption would be disastrous for the patients eye.

Efeito Raman

Fotocoagulação

Laser

Laser

Laser de estado sólido

Photocoagulation

Raman Effect

Solid state laser

Silicon planar lightwave circuits: raman amplification and polarization processing. / CUHK electronic theses & dissertations collection

January 2004

Liang Tak-keung. / "June 2004." / Thesis (Ph.D.)--Chinese University of Hong Kong, 2004. / Includes bibliographical references. / Electronic reproduction. Hong Kong : Chinese University of Hong Kong, [2012] System requirements: Adobe Acrobat Reader. Available via World Wide Web. / Mode of access: World Wide Web. / Abstracts in English and Chinese.

Microwave integrated circuits

Raman effect

Polarization (Light)

Optical wave guides

Optical amplifiers

Silicon-on-insulator technology

Development of new polymer-supported reagents for organic synthesis, solvent effects in samarium promoted allylic alcohol cyclopropanation reactions and time resolved resonance studies of the photodeprotection of p-hydroxyphenacyl caged phototrigger compounds

Kan, Tze-wai, Jovi.

January 2006

Thesis (Ph. D.)--University of Hong Kong, 2007. / Title proper from title frame. Also available in printed format.

Multifrequency Raman Generation in the Transient Regime

Turner, Fraser

January 2006

Two colour pumping was used to investigate the short-pulse technique of Multifrequency Raman Generation (MRG) in the transient regime of Raman scattering. In the course of this study we have demonstrated the ability to generate over thirty Raman orders spanning from the infrared to the ultraviolet, investigated the dependence of this generation on the pump intensities and the dispersion characteristics of the hollow-fibre system in which the experiment was conducted, and developed a simple computer model to help understand the exhibited behaviours. These dependence studies have revealed some characteristics that have been previously mentioned in the literature, such as the competition between MRG and self-phase modulation, but have also demonstrated behaviours that are dramatically different than anything reported on the subject. Furthermore, through a simple modification of the experimental apparatus we have demonstrated the ability to scatter a probe pulse into many Raman orders, generating bandwidth comparable to the best pump-probe experiments of MRG. By using a numeric fast Fourier transform, we predict that our spectra can generate pulses as short as 3. 3fs, with energies an order of magnitude larger than pulses of comparable duration that are made using current techniques.

Physics & Astronomy

short pulses

nonlinear optics

ultrafast lasers

Raman effect

parametric process

Multifrequency Raman Generation in the Transient Regime

Turner, Fraser

January 2006

Two colour pumping was used to investigate the short-pulse technique of Multifrequency Raman Generation (MRG) in the transient regime of Raman scattering. In the course of this study we have demonstrated the ability to generate over thirty Raman orders spanning from the infrared to the ultraviolet, investigated the dependence of this generation on the pump intensities and the dispersion characteristics of the hollow-fibre system in which the experiment was conducted, and developed a simple computer model to help understand the exhibited behaviours. These dependence studies have revealed some characteristics that have been previously mentioned in the literature, such as the competition between MRG and self-phase modulation, but have also demonstrated behaviours that are dramatically different than anything reported on the subject. Furthermore, through a simple modification of the experimental apparatus we have demonstrated the ability to scatter a probe pulse into many Raman orders, generating bandwidth comparable to the best pump-probe experiments of MRG. By using a numeric fast Fourier transform, we predict that our spectra can generate pulses as short as 3. 3fs, with energies an order of magnitude larger than pulses of comparable duration that are made using current techniques.

Physics & Astronomy

short pulses

nonlinear optics

ultrafast lasers

Raman effect

parametric process

Some optical and catalytic properties of metal nanoparticles

Tabor, Christopher Eugene

20 August 2009

The strong electromagnetic field that is induced at the surface of a plasmonic nanoparticle can be utilized for many important applications, including spectroscopic enhancement and electromagnetic waveguides. The focus of this thesis is to study some of the properties of induced plasmonic fields around metal nanoparticles. Current methodologies for fabricating nanoparticles are discussed, including lithography and colloidal synthesis. This dissertation includes studies on plasmonic driven nanoparticle motion of surface supported gold nanoprisms from a substrate into solution via a femtosecond pulse. The mechanism of particle motion is discussed and the stability of the unprotected nanoprisms in solution is studied. Fundamental plasmonic near-field coupling between two plasmonic nanoparticles is also examined. Experimental results using electron beam lithography fabricated samples are used to explicitly describe the plasmonic coupling between dimers as a function of the nanoparticle size, shape, and orientation. These variables are systematically studied and the dependence is compared to mathematically derived functional dependencies in order to model and predict the effects of plasmonic coupling. As an extension, the coupling between plasmonic nanoparticles is shown in a common application, surface enhanced Raman scattering. The final chapter is devoted to an investigation of the nature of nanocatalysis, homogeneous and heterogeneous, for several reactions using metal nanoparticles.

Nanoparticle

Plasmon

Metal

Dimer

Coupled nanoparticles

Lithography

Lithography, Electron beam

Nanoparticles

Dimers

Raman effect

Temperature and pressure raman studies of Hg1201 superconductors and oligo (para-phenylene) materials /

Cai, Qingrui,

January 2001

Thesis (Ph. D.)--University of Missouri-Columbia, 2001. / Typescript. Vita. Includes bibliographical references (leaves 123-128). Also available on the Internet.

Resonance raman investigation of metal to ligand charge transfer transitions in selected inorganic complexes

Cheng, Yung-fong, Yvonne.

January 2001

Thesis (M. Phil.)--University of Hong Kong, 2001. / Includes bibliographical references (leaves 80-85).

Temperature and pressure raman studies of Hg1201 superconductors and oligo (para-phenylene) materials

Cai, Qingrui,

January 2001

Thesis (Ph. D.)--University of Missouri-Columbia, 2001. / Typescript. Vita. Includes bibliographical references (leaves 123-128). Also available on the Internet.

Resonance Raman intensity analysis of chlorine dioxide, nitrosyl chloride, and isopropyl nitrate in solution /

Nyholm, Bethany Paige.

January 2003

Thesis (Ph. D.)--University of Washington, 2003. / Vita. Includes bibliographical references (leaves 154-161).