Optical micromanipulation using dispersion-compensated and phase-shaped ultrashort pulsed lasers /

Shane, Janelle.

January 2009

Thesis (M.Phil.) - University of St Andrews, June 2009.

Direct observation of laser filamentation in high-order harmonic generation /

Painter, John,

January 2006

Thesis (M.S.)--Brigham Young University. Dept. of Physics and Astronomy, 2006. / Includes bibliographical references (p. 61-64).

Desenvolvimento de um sistema opto-mecanico para micro usinagem com laser de fentossegundos / Development of an opto-mechanical system for micro machining with femtosecond laser

VIDAL, JOSE T.

09 October 2014

Made available in DSpace on 2014-10-09T12:28:05Z (GMT). No. of bitstreams: 0 / Made available in DSpace on 2014-10-09T14:01:23Z (GMT). No. of bitstreams: 0 / Dissertacao (Mestrado) / IPEN/D / Instituto de Pesquisas Energeticas e Nucleares - IPEN-CNEN/SP

LASER ABLATION

ULTRASHORT PULSES

MACHINING

MICROSTRUCTURE

MECHANICS

OPTICS

Controle da fluorescência excitada por dois fótons no polímero conjugado MEH-PPV através da formatação pulsos ultracurtos / Control of the two-photon excited fluorescence in the conjugated polymer MEH-PPV by pulse shaping

Paulo Henrique Dias Ferreira

17 August 2007

Neste trabalho foi investigado o controle do processo de fluorescência excitada por absorção de dois fótons no polímero conjugado MEH-PPV, utilizando um sistema de formatação espectral da fase dos pulsos ultracurtos. Para tal estudo, foi utilizado um oscilador laser de Ti:Safira (15 fs, ~ 800 nm e largura de banda de 60 nm). Através de dois distintos métodos de formatação, observa-se a influência destes no processo de fotodegradação do MEHPPV, inferido pela diminuição da intensidade do sinal de fluorescência. No primeiro método de formatação, é estudada a influência de diferentes chirps impostos aos pulsos no processo de fluorescência do MEH-PPV. Observa-se uma menor taxa de fotodegradação para pulsos com maiores chirps, independente do sinal, em comparação a pulsos no limite de transformada. Esse efeito foi relacionado ao acréscimo na duração temporal dos pulsos com chirp, com consequente diminuição da intensidade. Numa segunda etapa, através do uso de um espelho deformável, a fase espectral do pulso é formatada usando uma máscara de fase senoidal. Neste caso, a intensidade de fluorescência foi modulada em aproximadamente 25%, num claro processo de controle coerente, sem nenhuma diferença apreciável no processo de fotodegradação. Desta forma, técnicas de controle coerente com formatação espectral da fase poderiam ser utilizadas para modular a intensidade do sinal de fluorescência no MEH-PPV, sem detrimento ao processo fotodegradativo. / In this work we studied the control of two-photon excited fluorescence in the conjugated polymer MEH-PPV, using pulse-shaping techniques to manipulate the pulse spectral phase. The experiments were carried out with a Ti:sapphire laser oscillator (15 fs, ~ 800 nm and 60 nm of bandwidth). We investigated the influence of two distinct pulse-shaping methods in the MEH-PPV photodegradation, inferred by the decrease in the fluorescence intensity. In the first method, we studied the effect of different pulse chirps on the MEH-PPV fluorescence. A smaller photodegradation rate was observed for pulses with higher chirps, independently of its sing, in comparison with pulses close to the Fourier Transform limit. This effect was attributed to the increase in the pulse duration for chirped pulses, and consequent decrease in the pulse intensity. In a second stage, we modulate the pulse spectral phase by employing a senoidal phase mask though a deformable mirror. In this case, a 25% modulation in the fluorescence intensity was determined, whereas no considerable effect was observed in the photodegradation. In this way, coherent control techniques employing spectral phase pulse-shaping could be used to modulate MEH-PPV fluorescence, without any negative effect to its photodegradation.

Controle coerente

Fluorescência

Pulsos ultracurtos

Coherent control

Fluorescence

Ultrashort pulses

Desenvolvimento de um sistema opto-mecanico para micro usinagem com laser de fentossegundos / Development of an opto-mechanical system for micro machining with femtosecond laser

VIDAL, JOSE T.

09 October 2014

Made available in DSpace on 2014-10-09T12:28:05Z (GMT). No. of bitstreams: 0 / Made available in DSpace on 2014-10-09T14:01:23Z (GMT). No. of bitstreams: 0 / A usinagem de estruturas micrométricas pode ser feita com pulsos laser de nano, pico ou fentossegundos. Destes, porém, somente os mais curtos podem resultar em uma interação não térmica com a matéria, o que evita a fusão, formação de rebarba e zona afetada pelo calor. Devido à sua baixa potência média, contudo, a sua utilização na produção em massa somente pode ser considerada em casos muito especiais, isto é, quando o processamento não-térmico é essencial. Este é o caso da usinagem de semicondutores, aços elétricos, produção de MEMS (sistemas micro eletro-mecânicos), de micro canais e diversos dispositivos médicos e biológicos. Assim, visando a produção destes tipos de estruturas, uma estação de trabalho foi construída com capacidade de controlar os principais parâmetros de processo necessários para uma usinagem micrométrica com laser de pulsos ultracurtos. Os principais problemas deste tipo de estação são o controle da fluência e do posicionamento do ponto focal. Assim, o controle do diâmetro do feixe (no foco) e da energia devem ser feitos com grande precisão. Além disso, o posicionamento do ponto focal com precisão micrométrica nos três eixos, também é de fundamental importância. O sistema construído neste trabalho apresenta soluções para estes problemas, utilizando diversos sensores e posicionadores controlados simultaneamente por um único programa. A estação de trabalho recebe um feixe vindo de um laser de pulsos ultracurtos localizado em outro laboratório, e manipula este feixe de maneira a focalizá-lo com precisão na superfície da amostra a ser usinada. Os principais parâmetros controlados dinamicamente são a energia, o número de pulsos e o posicionamento individual de cada um deles. A distribuição espacial da intensidade, a polarização e as vibrações também foram medidas e otimizadas. O sistema foi testado e aferido com medidas de limiar de ablação do silício, que é um material bastante estudado neste regime de operação laser. Os resultados, quando confrontados com a literatura, mostram a confiabilidade e a precisão do sistema. A automatização, além de aumentar esta precisão, também aumentou a rapidez na obtenção dos resultados. Medidas de limiar de ablação também foram realizadas para o metal molibdênio, levando a resultados ainda não vistos na literatura. Assim, de acordo com o objetivo inicial, o sistema foi desenvolvido e está pronto para utilização em estudos que levem à produção de estruturas micrométricas. / Dissertacao (Mestrado) / IPEN/D / Instituto de Pesquisas Energeticas e Nucleares - IPEN-CNEN/SP

laser ablation

ultrashort pulses

machining

microstructure

mechanics

optics

Impact of Plasma Dynamics On Femtosecond Filamentation

Emms, Rhys Mullin

January 2016

In this thesis we ran a series of 2D simulations of femtosecond laser pulses filamenting in air using the FDTD method, a saturable Lorentz oscillator model of air [1], and two separate models of plasma: a Drude model where the plasma density is static in space, and a particle-in-cell model where plasma is free to migrate throughout the simulation space. By comparing matched pairs of simulations, which varied in pulse size, duration, and intensity, we can gauge the impact plasma dynamics has upon the evolution of a filamenting laser pulse. From these tests we determine that, while there are some visible differences between dynamic and static plasmas, plasma dynamics do not significantly alter the evolution of the pulse.

nonlinear optics

filamentation

ultrashort laser pulses

ionization

optical Kerr effect

Synthesis and Characterization of Novel Self-Assembling Tetrapeptides for Biomedical Applications and Tissue Engineering

Susapto, Hepi Hari

06 1900

Molecular self-assembly is the process of molecules able to associate into more ordered structures. Examples of self-assembling molecules is a class of ultrashort amphiphilic peptides with a distinct sequence motif, which consist of only three to seven amino acids. These peptides can self-assemble to form nanofibrous scaffolds, such as in form of hydrogels, organogels or aerogels, due to their amphiphilic structure which contains a dominant hydrophobic tail and a polar head group. Interestingly, these peptide scaffolds offer a remarkably similar fiber topography to that one found in collagen which is a dominant part of the extracellular matrix. The resemblance to collagen fibers brings a potential benefit in using these peptide scaffolds together with native human cells. Specifically, they can maintain high water content over 99 % weight per volume and are suitable for tissue engineering and regenerative medicine applications. Over the last decade, they have shown promising therapeutic potential in treating several diseases thanks to their high activity, target specificity, low toxicity, and minimal nonspecific and drug-drug interactions. This dissertation describes how to characterize and use ultrashort amphiphilic peptides for tissue engineering and biomedicine. The first chapter offers an overview of already reported self-assembling ultrashort peptides and their applications. As a proof-of-concept, ultrashort peptide scaffolds were used for osteogenic differentiation. Peptide nanoparticles were embedded into 5 peptide hydrogels with the goal to tune the stiffness of the peptide gels. Furthermore, the peptide scaffold was used for the generation of gold and silver nanoparticles after UV irradiation, which allowed the production of nanoparticles in the absence of any additional reducing agent. The mechanism of the generation of these nanoparticles was then investigated. The last chapter describes how tetrameric peptide solutions were utilized for 3D bioprinting applications. Compared to earlier reported self-assembling ultrashort peptide compounds, these tetrapeptides can form hydrogels at an extremely low concentration of 0.1% w/v in a relatively short time under physiological conditions. These promising findings suggest that the peptide solutions are promising bioinks for use in 3D bioprinting.

Self-assembling peptide

Ultrashort Peptide

Bioprinting

Microfluidic

Biomineralization

Generation of tunable femtosecond laser pulses and the construction of an ultrafast pump-probe spectrometer

Morrison, Vance.

January 2008

No description available.

Laser pulses, Ultrashort.

Ultraviolet spectrometry.

Few-cycle Pulses Amplification For Attosecond Science Applications Modeling And Experiments

Hemmer, Michael

01 January 2011

The emergence of mode-locked oscillators providing pulses with durations as short as a few electric-field cycles in the near infra-red has paved the way toward electric-field sensitive physics experiments. In addition, the control of the relative phase between the carrier and the pulse envelope, developed in the early 2000’s and rewarded by a Nobel price in 2005, now provides unprecedented control over the pulse behaviour. The amplification of such pulses to the millijoule level has been an on-going task in a few world-class laboratories and has triggered the dawn of attoscience, the science of events happening on an attosecond timescale. This work describes the theoretical aspects, modeling and experimental implementation of HERACLES, the Laser Plasma Laboratory optical parametric chirped pulse amplifier (OPCPA) designed to deliver amplified carrier-envelope phase stabilized 8-fs pulses with energy beyond 1 mJ at repetition rates up to 10 kHz at 800 nm central wavelength. The design of the hybrid fiber/solid-state amplifier line delivering 85-ps pulses with energy up to 10 mJ at repetition rates in the multi-kHz regime tailored for pumping the optical parametric amplifier stages is presented. The novel stretcher/compressor design of HERACLES, suitable for handling optical pulses with spectra exceeding 300 nm of bandwidth with unprecedented flexibility, is fully modeled and also presented in the frame of this thesis. Finally, a 3D model of the multistage non-collinear optical parametric amplifier is also reported. The current and foreseen overall performances of HERACLES are presented. This facility is designed to enable attosecond physics experiments, high-harmonic generation and physics of plasma studies.

Laser pulses

Ultrashort

Parametric amplifiers

Electromagnetics and Photonics

Optics

Ultrashort-Pulse Laser Systems Based on External-Cavity Mode-Locked InGaAs-GaAs Semiconductor Oscillators and Semiconductor or Yb:Fibre Amplifiers

Budz, Andrew John

11 1900

Pages 10, 46, 126, 142 and 146 have been omitted because they were completely blank. / <p> This thesis describes the development of a tunable, ultrashort-pulse semiconductor-based laser system operating in the 1 μm wavelength region. The design of the oscillator is based on a two-contact long-wavelength InGaAs-GaAs quantum-well semiconductor device containing integrated gain and saturable absorber sections. A key design component of the oscillator is the fabrication of a curved ridge-waveguide in the gain section of the device, which allows the laser to be operated in a compact, linear external cavity. Under conditions of passive or hybrid mode-locking, the semiconductor oscillator can generate pulses of 1 to 10 ps in duration, which are tunable from 1030 to 1090 nm. The oscillator is also capable of being passively mode-locked at harmonics of the cavity round-trip frequency, allowing tuning of the pulse repetition rate from 0.5 to over 5 GHz. Noise measurements on two independently hybridly mode-locked semiconductor lasers reveal that the absolute noise of each laser is dominated by phase noise at frequencies below 10^5 Hz, while amplitude noise dominates at higher frequencies.</p> <p>Semiconductor and fibre optical amplifiers are used to scale the average power level of the mode-locked pulses. Semiconductor optical amplifiers consisting of narrow-stripe and flared-waveguide designs have been fabricated using the same material structure as that of the mode-locked semiconductor oscillator. Narrow-stripe devices with a length of 800 μm have produced amplified average signal powers of 13 mW, while 1700-μm-long, 2° flared-waveguide devices have produced amplified average signal powers of 50 mW. A fibre-based system consisting of a single-mode double-clad Yb-doped fibre has been constructed to investigate the suitability of a mode-locked diode laser as a seed-source for a Yb:fibre amplifier. Amplified average signal powers of up to 1.4 W have been obtained at the output of the fibre for a launched pump power of 2.1 W. Compression of the amplified pulses using a modified dual-grating compressor yields pulse durations as low as 500 fs and a peak power of up to 1.5 kW.</p> <p> Preliminary work is reported on the development of a novel dual-wavelength optical source consisting of two synchronized mode-locked diode lasers and a polarization-maintaining Yb:fibre amplifier. Numerical simulations based on a rate-equation model for the amplifier gain are conducted to investigate the performance characteristics of a Yb:fibre amplifier when operated under dual-wavelength signal amplification. The simulations are used to predict and optimize the performance of the fibre amplifier for two mode-locked semiconductor-seed-oscillators operating at wavelengths of 1040 and 1079 nm. Good agreement is obtained between the simulations and experimental results. </p> / Thesis / Doctor of Philosophy (PhD)