Phase-matching Second-order Optical Nonlinear Interactions using Bragg Reflection Waveguides: A Platform for Integrated Parametric Devices

Abolghasem, Payam

29 August 2011

Bragg reflection waveguides (BRW) or one-dimensional photonic bandgap structures have been demonstrated for phase-matching chi(2) nonlinearities in AlxGa1-xAs. The method exploits strong modal dispersion of a Bragg mode and total internal reflection modes co-propagating inside the waveguide. It is shown that phase-matching is attained among the lowest order modes of interacting harmonics, which allows maximizing the utilization of harmonics powers for nonlinear interactions. As our first demonstration, we report second-harmonic generation (SHG) of a 2-ps telecommunication pump in a 2.4 mm long slab BRW. The conversion efficiency is estimated as 2.0 %/W.cm^2 with a generated SH power of 729 nW. This efficiency has been considerably improved by introducing lateral confinement of optical modes in ridge structures. Characterizations denote that efficiency of SHG in ridge BRWs can increase by over an order of magnitude in comparison to that of the slab device. Also, we report continuous-wave SHG in BRWs. Using a telecommunication pump with a power of 98 mW, the continuous-wave SH power of 23 nW is measured in a 2.0 mm long device. Significant enhancements of chi(2) interactions is obtained in the modified design of matching-layer enhanced BRW (ML-BRW). For the first time, we report type-II SHG in ML-BRW, where the second-harmonic power of 60 µW is measured for a pump power of 3.3 mW in a 2.2 mm long sample. Also, we demonstrate the existence of type-0 SHG, where both pump and SH signal have an identical TM polarization state. It is shown that the efficiency of the type-0 process is comparable to type-I and type-II processes with the phase-matching wavelengths of all three interactions lying within a spectral window as small as 17 nm. ML-BRW is further reported for sum-frequency and difference-frequency generations. For applications requiring high pump power, a generalized ML-BRW design is proposed and demonstrated. The proposed structure offsets the destructive effects of third-order nonlinearities on chi(2) processes when high power harmonics are involved. This is carried out through incorporation of larger bandgap materials by using high aluminum content AlxGa1-xAs layers without undermining the nonlinear conversion efficiency. Theoretical investigations of BRWs as integrated sources of photon-pairs with frequency correlation properties are discussed. It is shown that the versatile dispersion properties in BRWs enables generation of telecommunication anti-correlated photon-pairs with bandwidth tunablity between 1 nm and 450 nm.

Bragg reflection waveguides

BRWs

Nonlinear optics

Optical frequency mixing

Phase-matching

Second-harmonic generation

Sum-frequency generation

Difference-frequency generation

Integrated parametric devices

0544

Structural Investigation of Biological and Semiconductor Nanostructures with Nonlinear Multicontrast Microscopy

Cisek, Richard

12 December 2013

Physical and functional properties of advanced nano-composite materials and biological structures are determined by self-organized atoms and molecules into nanostructures and in turn by microscopic organization of the nanostructures into assemblies of higher structural complexity. Therefore, microscopes are indispensable tools for structural investigations at various levels of organization. In this work, novel nonlinear optical microscopy methods were developed to non-invasively study structural organization at the nanoscopic and microscopic levels. Atomic organization of semiconductor nanowires, molecular organization of amylose biocrystallites in starch granules, and microscopic organization of several photosynthetic organisms was elucidated. The structure of ZnSe nanowires, key components in many modern nanodevices, was investigated using polarization harmonic generation microscopy. Based on nonlinear optical properties of the different crystal lattices, zinc blende and wurtzite nanowires were differentiated, and the three-dimensional orientation of the zinc blende nanowires could be found. The structure of starch granules, a model biocrystal, important in food as well as health sciences, was also investigated using polarization harmonic microscopy. The study was combined with ab initio calculations using the crystal structures of amylose A and B, revealing that second harmonic signals originate from the hydroxide and hydrogen bonds in the starch granules. Visualization of several photosynthetic organisms including the green algae, Chlamydomonas reinhardtii, two species of cyanobacteria, Leptolyngbya sp. and Anabaena sp., aggregates of light-harvesting pigment-protein complexes as well as chloroplasts from green plants were also explored, revealing that future nonlinear microscopy applications could include structural studies of cell walls, the Chlamydomonas eyespot, and photosynthetic membranes. In this study, several nonlinear optical microscopy modalities were developed for quantitative structural investigations of nano and micro-sized architectures. Non-invasive extraction of crystallographic information in microscopic samples will have a number of potential benefits, for example, in clinical applications, allowing observations of disease states inside tissues without the need for biopsy. Industrial nanotechnology will benefit from fast determination of nanostructures with nonlinear microscopy that will improve quality of nanodevices.

Nonlinear Optics

Laser Scanning Microscopy

Semiconductor Nanowires

Starch Biocrystals

Second Harmonic Generation

Third Harmonic Generation

Polarization Harmonic Microscopy

Imaging Photosynthetic Structures

0786

0752

0609

Phase-matching Second-order Optical Nonlinear Interactions using Bragg Reflection Waveguides: A Platform for Integrated Parametric Devices

Abolghasem, Payam

29 August 2011

Bragg reflection waveguides (BRW) or one-dimensional photonic bandgap structures have been demonstrated for phase-matching chi(2) nonlinearities in AlxGa1-xAs. The method exploits strong modal dispersion of a Bragg mode and total internal reflection modes co-propagating inside the waveguide. It is shown that phase-matching is attained among the lowest order modes of interacting harmonics, which allows maximizing the utilization of harmonics powers for nonlinear interactions. As our first demonstration, we report second-harmonic generation (SHG) of a 2-ps telecommunication pump in a 2.4 mm long slab BRW. The conversion efficiency is estimated as 2.0 %/W.cm^2 with a generated SH power of 729 nW. This efficiency has been considerably improved by introducing lateral confinement of optical modes in ridge structures. Characterizations denote that efficiency of SHG in ridge BRWs can increase by over an order of magnitude in comparison to that of the slab device. Also, we report continuous-wave SHG in BRWs. Using a telecommunication pump with a power of 98 mW, the continuous-wave SH power of 23 nW is measured in a 2.0 mm long device. Significant enhancements of chi(2) interactions is obtained in the modified design of matching-layer enhanced BRW (ML-BRW). For the first time, we report type-II SHG in ML-BRW, where the second-harmonic power of 60 µW is measured for a pump power of 3.3 mW in a 2.2 mm long sample. Also, we demonstrate the existence of type-0 SHG, where both pump and SH signal have an identical TM polarization state. It is shown that the efficiency of the type-0 process is comparable to type-I and type-II processes with the phase-matching wavelengths of all three interactions lying within a spectral window as small as 17 nm. ML-BRW is further reported for sum-frequency and difference-frequency generations. For applications requiring high pump power, a generalized ML-BRW design is proposed and demonstrated. The proposed structure offsets the destructive effects of third-order nonlinearities on chi(2) processes when high power harmonics are involved. This is carried out through incorporation of larger bandgap materials by using high aluminum content AlxGa1-xAs layers without undermining the nonlinear conversion efficiency. Theoretical investigations of BRWs as integrated sources of photon-pairs with frequency correlation properties are discussed. It is shown that the versatile dispersion properties in BRWs enables generation of telecommunication anti-correlated photon-pairs with bandwidth tunablity between 1 nm and 450 nm.

Bragg reflection waveguides

BRWs

Nonlinear optics

Optical frequency mixing

Phase-matching

Second-harmonic generation

Sum-frequency generation

Difference-frequency generation

Integrated parametric devices

0544

Structural Investigation of Biological and Semiconductor Nanostructures with Nonlinear Multicontrast Microscopy

Cisek, Richard

12 December 2013

Physical and functional properties of advanced nano-composite materials and biological structures are determined by self-organized atoms and molecules into nanostructures and in turn by microscopic organization of the nanostructures into assemblies of higher structural complexity. Therefore, microscopes are indispensable tools for structural investigations at various levels of organization. In this work, novel nonlinear optical microscopy methods were developed to non-invasively study structural organization at the nanoscopic and microscopic levels. Atomic organization of semiconductor nanowires, molecular organization of amylose biocrystallites in starch granules, and microscopic organization of several photosynthetic organisms was elucidated. The structure of ZnSe nanowires, key components in many modern nanodevices, was investigated using polarization harmonic generation microscopy. Based on nonlinear optical properties of the different crystal lattices, zinc blende and wurtzite nanowires were differentiated, and the three-dimensional orientation of the zinc blende nanowires could be found. The structure of starch granules, a model biocrystal, important in food as well as health sciences, was also investigated using polarization harmonic microscopy. The study was combined with ab initio calculations using the crystal structures of amylose A and B, revealing that second harmonic signals originate from the hydroxide and hydrogen bonds in the starch granules. Visualization of several photosynthetic organisms including the green algae, Chlamydomonas reinhardtii, two species of cyanobacteria, Leptolyngbya sp. and Anabaena sp., aggregates of light-harvesting pigment-protein complexes as well as chloroplasts from green plants were also explored, revealing that future nonlinear microscopy applications could include structural studies of cell walls, the Chlamydomonas eyespot, and photosynthetic membranes. In this study, several nonlinear optical microscopy modalities were developed for quantitative structural investigations of nano and micro-sized architectures. Non-invasive extraction of crystallographic information in microscopic samples will have a number of potential benefits, for example, in clinical applications, allowing observations of disease states inside tissues without the need for biopsy. Industrial nanotechnology will benefit from fast determination of nanostructures with nonlinear microscopy that will improve quality of nanodevices.

Nonlinear Optics

Laser Scanning Microscopy

Semiconductor Nanowires

Starch Biocrystals

Second Harmonic Generation

Third Harmonic Generation

Polarization Harmonic Microscopy

Imaging Photosynthetic Structures

0786

0752

0609

Metallische Nanoantennen: Frequenzverdopplung und photochemische Reaktionen auf kleinen Skalen

Reichenbach, Philipp

11 April 2012

Diese Arbeit beinhaltet experimentelle und theoretische Untersuchungen der optischen Frequenzverdopplung (second-harmonic generation, kurz SHG) an metallischen Nanopartikeln. Frequenzverdopplung bedeutet, daß ein bei der Frequenz omega angeregtes Nanopartikel Strahlung der Frequenz 2*omega emittiert. Dieser Effekt tritt nicht nur in Materialien mit nichtzentrosymmetrischer Kristallstruktur, sondern auch an der Oberfläche von Metallen auf. Deshalb läßt er sich gut mit plasmonischen Feldüberhöhungen an metallischen Nanoantennen verbinden. Die Frequenzverdopplung wird an verschiedenen Nanostrukturen wie dreieckförmigen, stäbchenförmigen und vor allem kegelförmigen Nanopartikeln experimentell untersucht, welche aufgrund ihrer scharfen Spitzen starke SHG-Signale emittieren. Besonders die Kegel sind interessant: Bei Anregung mit einem fokussierten, radial polarisierten Strahl dominiert je nach Kegelgröße und Umgebungsmedium ein SHG-Signal entweder von der Spitze oder von der Bodenkante des Kegels. Diese an den Kegeln gemessenen Resultate werden durch theoretische Untersuchungen untermauert. In diesen Rechnungen werden die plasmonischen Feldüberhöhungen und die sich daraus ergebende Frequenzverdopplung für einen Kegel mit verschiedenen Parametern modelliert. An einem einzelnen Kegel gewonnene Resultate werden auch mit den Fällen eines kugelförmigen und eines stäbchenförmigen Partikels verglichen. Ein weiterer Gegenstand der theoretischen Untersuchungen ist die Superposition der zweiten Harmonischen von mehreren emittierenden Nanopartikeln zu einem Feldmaximum. Dabei wird eine kreisförmige Anordnung von 8 Nanostäbchen bzw. Nanokegeln von einer radial polarisierten Mode angeregt. Die Superposition der emittierten zweiten Harmonischen ergibt ein Feldmaximum innerhalb der Anordnung der Emitter. Durch eine Verkippung des anregenden Strahls kann dieser Fokus im Raum bewegt werden. Letztere Untersuchung ist insbesondere interessant im Hinblick auf lokalisierte photochemische Reaktionen, die durch das frequenzverdoppelte Licht von Nanopartikeln ausgelöst werden sollen. Mit chemischen Substanzen, die bei omega transparent, bei 2*omega aber photoreaktiv sind, wäre im Nahfeld dieser Nanoantennen eine starke Lokalisierung der Reaktion auf Bereiche kleiner als 100~nm möglich. Anhand von Photolacken und Polymermatrizen mit diesen Eigenschaften wird experimentell untersucht, ob frequenzverdoppeltes Licht überhaupt solche Reaktionen auslösen kann oder ob die photochemische Reaktionen überwiegend durch direkte Zwei-Photonen-Absorption des anregenden Lichts ausgelöst werden. Die Ergebnisse zeigen allerdings, daß die Zwei-Photonen-Absorption dominant ist. Durch die Zwei-Photonen-Absorption im Nahfeld von Partikeln ist aber dennoch eine vergleichbare Lokalisierung der Reaktion möglich. / This work includes experimental and theoretical investigations of second-harmonic generation (SHG) at metallic nanoparticles. SHG means that a nanoparticle that is excited at the frequency omega emits radiation at the frequency 2*omega. SHG does not only occur in materials with noncentrosymmetric structure, but also on metal surfaces. Hence, SHG can be combined well with plasmonic field enhancement at metallic nanoantennae. SHG is investigated experimentally at different nanostructures such as triangle-like, rod-like and especially cone-like nanoparticles. With their sharp tips these structures show a much stronger SHG signal than spherical nanoparticles. Especially the cones are interesting: Excited with a focused radially polarized beam, for different cone sizes and in different surrounding media either the signal from the tip or the signal from the bottom edge dominates. The measurement results from the cones are underpinned by theoretical investigations. In these calculations the plasmonic field enhancements and the resulting SHG are modeled for a cone with different parameters. The single-cone results are also compared with the cases of a spherical or rod-shaped particle. A further subject of the theoretical investigations is the superposition of the SHG radiation from a number of emitting nanoparticles to a field maximum. For that, a circular arrangement of 8 nanorods or nanocones is excited by a radially polarized beam. The superposition of the second-harmonic radiation fields yields a field maximum in the space between the emitters. A tilt of the exciting beam can move this focus in space. The latter item is of special interest concerning localised photochemical reactions induced by the second-harmonic light from nanoparticles. In the near field of these nanoantennae, a strong localisation of the reaction on regions smaller than 100 nm would be possible by using chemical substances being transparent at omega, but photoreactive at 2*omega. With photoresists and polymer matrices, experiments are carried out to investigate whether SHG light can trigger such reactions at all, or if these photochemical reactions are triggered predominantly by direct two-photon absorption of the exciting light. The results show that the two-photon absorption is the dominant process. Yet, through two-photon absorption in the near field of particles, the localisation of the reaction is still similar.

Frequenzverdopplung

nichtlineare Optik

Nanopartikel

Nano-Optik

Optik

Photochemie

photochemisch

second-harmonic generation

non-linear optics

optics

nanoparticles

nano-optics

nanocones

photochemistry

photochemical

ddc:535

ddc:560

rvk:UH 5690

Das unstetige Galerkin-Verfahren in der Nanooptik

Hille, Andreas

08 March 2013

Die Nanooptik beschäftigt sich mit der Wechselwirkung von Licht mit Materie, deren charakteristische Dimension im Nanometer Bereich liegt. Insbesondere wenn die Materie aus Metall besteht, zeigen sich interessante, wellenlängenabhängige Unterschiede in der Stärke der Wechselwirkung. Die Ursache dafür sind die kollektiven Moden der quasifreien Ladungsträger, die Plasmonen. Obgleich sich experimentelle Methoden in den letzten Jahren stetig verbessert haben, ist es nach wie vor nur mit erheblichem Aufwand möglich, sich Einblicke in die mikroskopischen Zusammenhänge zu verschaffen. Eine Ergänzung zu den Experimenten bieten theoretische Modelle. Auf Grund der sich mit der Zeit stetig verbesserten Leistung der Rechentechnik, kommen dabei zunehmend numerische Verfahren zum Einsatz. Eines dieser Verfahren ist das Unstetige Galerkin Verfahren, welches in dieser Arbeit auf folgende Fragestellungen der plasmonischen Nanooptik angewandt wurde: • Bei dem unstetigen Galerkin Verfahren werden die zu simulierenden Körper üblicherweise mittels Dreiecke und Tetraeder approximiert. Da die Geometrie der metallischen Systeme einen entscheidenden Einfluss auf die Wechselwirkung hat, wurde untersucht, inwieweit sich durch Einsatz von Elementen mit gekrümmten Flächen die Genauigkeit oder die Geschwindigkeit der Simulation steigern lässt. Es konnte gezeigt werden, dass runde Elemente die Genauigkeit bei gleicher Diskretisierung um bis zu zwei Größenordnungen steigern oder die Rechenzeit bei gleicher Genauigkeit auf ein Sechstel verkürzen können. • Bestrahlt man Metallnanopartikel mit intensiven Laserpulsen, so strahlen diese nicht nur bei der Frequenz des eingestrahlten Lichtes, sondern auch bei der doppelten Frequenz ab. Dieses Phänomen der Frequenzverdopplung (SHG, engl.: „Second-Harmonic-Generation“) ist unter anderem von der Form der Partikel und der Wellenlänge des Pulses abhängig. Da durchstimmbare gepulste Laser sehr teuer sind, wurde untersucht, ob sich mit Hilfe der linearen Partikelspektren Vorhersagen über die Stärke der Frequenzverdopplung machen lassen. Dabei wurde festgestellt, dass die Effizienz der Frequenzverdopplung zunimmt, wenn man die linearen Resonanzen der Partikel auf die SHG- oder Anregungswellenlänge abstimmt. Schafft man es, das plasmonische System so einzustellen, dass sowohl die Anregungswellenlänge, wie auch die SHG- Wellenlänge auf einer linearen Resonanz liegen, so kann die Effizienz der SHG weiter gesteigert werden. / Nanooptics is a discipline dealing with the interaction of light with matter where its characteristic dimensions are defined to be in the range of nanometers. In particular, if the matter consists of metal, i.e. conductive material, interesting wavelength dependent phenomena can be observed, which scale with the strength of the interaction. These phenomena are caused by the formation of collective modes between quasi-free charge carriers resulting in so called plasmons. Although improved experimental methods have evolved over the last few years, insight into the microscopic relationship between light and matter is only achievable with high effort. Supplemental information to experimental findings can be drawn from theoretical models. Due to the constantly improving computational power, numerical methods are progressively more employed. One of these methods is the discontinuous Galerkin method, which was applied to the following problems in plasmonic nanooptics: • Within the discontinuous Galerkin method the simulated objects are usually approximated by triangles or tetrahedrons. Since the geometry of conductive systems has a major impact on the interaction between light and matter, the usability of elements with curved surfaces for the discretisation of the space has been investigated with respect to accuracy and speed of the simulation. In this work, it could be shown that curved elements improve the simulations precision up to two orders of magnitude with the same amount of discretisation compared to linear elements. Related to speed, it has been found that the computational time is reduced by a factor of 6 with a comparable simulation accuracy. • By irradiating metallic nanoparticles with high power laser pulses these particles do not only emit light of the same frequency as the incident electromagnetic wave, but also with the doubled frequency (SHG, second harmonic generation). Among other things, this phenomenon of frequency doubling mainly depends on the geometry of the particle and the wavelength of the pulse. Since tunable pulsed laser sources are very expensive, it has been theoretically investigated if the strength of the frequency doubling can be deduced from the particles linear spectra. By this, it has been discovered that the efficiency of frequency doubling can be improved by adjusting the linear resonances of the particle to the SHG or excitation wavelength. The SHG efficiency can be increased even further, if the plasmonic system is tuned to a point where both the excitation and the SHG wavelength correspond to a linear resonance of the nanoparticle.

unstetiges Galerkin Verfahren

Frequenzverdopplung

runde Elemente

Nanooptik

Plasmonik

discontinuous galerkin

second harmonic generation

curved elements

nanooptic

plasmonic

ddc:530

rvk:UH 5690

Wavelength Conversion in Domain-disordered Quasi-phase Matching Superlattice Waveguides

Wagner, Sean

31 August 2011

This thesis examines second-order optical nonlinear wave mixing processes in domain-disordered quasi-phase matching waveguides and evaluates their potential use in compact, monolithically integrated wavelength conversion devices. The devices are based on a GaAs/AlGaAs superlattice-core waveguide structure with an improved design over previous generations. Quantum-well intermixing by ion-implantation is used to create the quasi-phase matching gratings in which the nonlinear susceptibility is periodically suppressed. Photoluminescence experiments showed a large band gap energy blue shift around 70 nm after intermixing. Measured two-photon absorption coefficients showed a significant polarization dependence and suppression of up to 80% after intermixing. Similar polarization dependencies and suppression were observed in three-photon absorption and nonlinear refraction. Advanced modeling of second-harmonic generation showed reductions of over 50% in efficiency due to linear losses alone. Self-phase modulation was found to be the dominant parasitic nonlinear effect on the conversion efficiency, with reductions of over 60%. Simulations of group velocity mismatch showed modest reductions in efficiency of less than 10%. Experiments on second-harmonic generation showed improvements in efficiency over previous generations due to low linear loss and improved intermixing. The improvements permitted demonstration of continuous wave second-harmonic generation for the first time in such structures with output power exceeding 1 µW. Also, Type-II phase matching was demonstrated for the first time. Saturation was observed as the power was increased, which, as predicted, was the result of self-phase modulation when using 2 ps pulses. By using 20 ps pulses instead, saturation effects were avoided. Thermo-optically induced bistability was observed in continuous wave experiments. Difference frequency generation was demonstrated with wavelengths from the optical C-band being converted to the L- and U-bands with continuous waves. Conversion for Type-I phase matching was demonstrated over 20 nm with signal and idler wavelengths being separated by over 100 nm. Type-II phase matched conversion was also observed. Using the experimental data for analysis, self-pumped conversion devices were found to require external amplification to reach practical output powers. Threshold pump powers for optical parametric oscillators were calculated to be impractically large. Proposed improvements to the device design are predicted to allow more practical operation of integrated conversion devices based on quasi-phase matching superlattice waveguides.

nonlinear optics

second-harmonic generation

difference frequency generation

optical Kerr effect

photonic integrated circuit

semiconductor

second-order optical nonlinearity

quasi-phase matching

parametric conversion

superlattice

0544

0752

[en] GLASS AND OPTICAL FIBER ELECTROTHERMAL POLING / [pt] POLARIZAÇÃO ELETROTÉRMICA DE VIDROS E FIBRAS ÓPTICAS

GLADYS ADRIANA QUINTERO ROJAS

07 March 2006

[pt] Componentes ópticos para sistemas de telecomunicações estão em crescente demanda. Para aumentar a eficiência destes componentes, reduzir os custos e permitir a integração aos sistemas atuais, tem-se incentivado a pesquisa de novos materiais, como, por exemplo, a sílica fundida. Geralmente, a sílica fundida, por ser um meio isotrópico, não exibe efeitos não lineares de segunda ordem como o efeito eletro-óptico, que pode ser utilizado na fabricação de chaves e moduladores ópticos. No entanto, pode-se induzir na sílica uma não linearidade de segunda ordem (c(2)) da ordem de 1 pm/V através da técnica de polarização eletrotérmica. Observa-se a formação de uma camada depletada de íons e um campo elétrico muito intenso permanentemente gravado em sílica polarizada. A caracterização experimental desta camada de depleção, ou seja, espessura, perfil e magnitude do c(2) induzido, é importante para a compreensão do processo físico que ocorre durante a polarização. Podem ser encontrados na literatura resultados muito divergentes obtidos com diferentes técnicas de caracterização. Não se sabe se esta divergência é devida aos diferentes métodos usados, ou a diferentes condições de polarização e tipos de amostras. Nesta tese, fez-se uma comparação entre quatro técnicas de caracterização da espessura da camada de depleção em sílica polarizada: ataque químico interferométrico com ácido fluorídrico, Maker Fringe, microscopia óptica e de força atômica, e ataque interferométrico com medida de segundo harmônico em tempo real. A estabilidade da não linearidade induzida é importante para garantir a estabilidade de chaves e moduladores ópticos construídos com sílica polarizada, portanto, fez-se também um estudo de apagamento por temperatura da não linearidade induzida em amostras de sílica polarizada. Foi também estudado nesta tese a influência da superfície da amostra antes da polarização, fator importante para a otimização da reprodutibilidade do processo. Para investigar a potencialidade do desenvolvimento de um Atenuador Óptico Variável (VOA) a fibra óptica, também foi feito um estudo de polarização eletrotérmica em fibras ópticas. Estudos complementares foram realizados envolvendo a influência do campo elétrico na taxa de ataque de ácido fluorídrico em fibras ópticas. Fez-se também um estudo sobre redes de Bragg gravadas em fibras especiais. Parte desta tese foi financiada pelo CNPq (bolsa doutorado), pelo Convênio Ericsson/PUC-Rio - Termo Aditivo 04 e 14, ref: PUC.04, Polarização de fibras ópticas, e pelo Projeto GIGA - Finep - Funttel - CPqD, Subprojeto Atenuador Óptico Variável a Fibra Óptica. / [en] Over the past few years, there has been a growing demand for optical components for telecommunication systems. In order to increase the efficiency of these components, reduce costs and allow integration to current systems, efforts have been made in researching new materials, for example, silica. Due to its isotropic nature, silica, ordinarily, does not present second order effects, for example, the electro-optic effect, which can be used for optical switching and modulation. However, eletrothermal poling can be used to induce in silica a second order nonlinearity (c(2)) of the order of 1 pm/V. It can be observed that poled silica has an ion-depleted layer and a permanently recorded electric field. The experimental characterization of this depletion layer, i.e. width, profile and magnitude of the induced c(2), is important for the comprehension of the physical process occurring during polarization. Different results obtained with different characterization techniques can be found in literature. It is not known whether diverging results in literature are due to different methods of examination or due to different poling conditions and sample type. This thesis compares the findings of four experimental techniques used to monitor the width of the depletion region in fused silica samples poled under similar conditions - hydrofluoric acid (HF) etching, Maker Fringe, optical and atomic force microscope, and hydrofluoric acid (HF) etching with real time monitoring of the SH signal. The stability of the induced nonlinearity is important to guarantee the stability of optical switches and modulators built with poled silica; therefore, thermal annealing of the induced nonlinearity in poled silica is also investigated in this thesis. The influence of the sample surface before poling, an important factor in reproducibility, is also investigated in this thesis. In order to investigate the possibility of developing an optical fiber Variable Optical Attenuator (VOA), optical fiber electrothermal poling was also investigated. Additionally, studies of the influence of the electric field strength on HF etching rate were made, as well as recording of Bragg gratings on special fibers. This thesis has been partially funded by CNPq (Doctorate scholarship), by Ericsson/PUC-Rio Accord - Additive term 04 e 14, ref: PUC.04, Poling of Optical Fiber, and by GIGA - Finep - Funttel - CPqD Project, Variable Optical Attenuator Subproject.

[pt] FIBRA OPTICA

[en] OPTIC FIBER

[pt] VIDRO

[en] GLASS

[pt] GERACAO DE SEGUNDO HARMONICO

[en] SECOND HARMONIC GENERATION

[pt] FISICA

[en] PHYSICS

[pt] NAO-LINEARIDADE

[en] NON-LINEARITY

Processo alternativo de polarização termo-elétrica de indução e caracterização de não-linearidade de segunda ordem em vidros soda-lime / Alternative thermal-electric polarzation process to induce and characterize second order nonlinearity in soda-lime glasses.

Moura, André de Lima

10 February 2009

Amorphous materials present macroscopic inversion symmetry. As a consequence, their even order nonlinearities are null. The technological interest in vitreous medium with second order nonlinearity ( χ(2) ) to make photonic devices has stimulated the development of techniques to induce this property. Among them, the thermal-electric field poling is one of the most investigated due its experimental simplicity and results reproducibility. In this work the investigations were directed to the thermal-electric field poling dynamics in soda-lime glasses in view of identify the mainly contributions to the induced nonlinearity stability. Initially were identified the mainly contributions to the induced electrical current. It was observed during the polarizations electroluminescence emission which was shown to be due to ionic displacement and air ionization outside the sample. By using a simplified ionic conduction model was determined two activation energies: ~0,60 and ~3,8eV. The first one, determined from the induced electrical current, was attributed to the sodium conduction; while the second ones, determined by the electroluminescence, attributed to the calcium displacement. Besides the small contribution to the electrical current, the calcium ions, due their small diffusion coefficient, were identified as responsible to the possibility of induce stable second order nonlinearity in soda-lime glasses. Based on these evidences it was used an alternative procedure in which the electrical current flux is controlled. This procedure enabled induce stable χ(2) . This effect was demonstrated to exist 12 months after the polarization procedure, even with a ~50% decrease. The second harmonic generation efficiency was increased in until three times by pumping continuously the polarized samples with infrared radiation from an Nd-YAG laser operating at QSML regime. The threshold applied voltage to observe χ(2) was determined through a modulated applied voltage procedure to be due to the mobility difference between sodium and calcium. / Coordenação de Aperfeiçoamento de Pessoal de Nível Superior / Materiais amorfos apresentam simetria de inversão macroscópica e, como conseqüência, as nãolinearidades ópticas de ordem par são nulas. A necessidade tecnológica de que meios vítreos apresentem não-linearidade de segunda ordem ( χ(2) ), visando principalmente o desenvolvimento de dispositivos fotônicos, fortalece a busca por técnicas para a sua indução. Dentre estas, o processo termo-elétrico de polarização tem sido muito investigado devido, principalmente a sua simplicidade experimental e a reprodutibilidade dos resultados. Neste trabalho as investigações são dedicadas à dinâmica do processo termo-elétrico em vidros soda-lime visando identificar as principais contribuições para a estabilidade da não-linearidade induzida. Inicialmente foram verificadas as principais contribuições à corrente elétrica induzida. Durante as polarizações observou-se emissão de eletroluminescência. Mostrou-se que esta é devido ao deslocamento dos íons de cálcio e possíveis ionizações do ar fora da amostra. Usando um modelo simplificado de condução iônica determinou-se duas energias de ativação: ~0,60 e ~3,8eV. A primeira, determinada a partir da corrente elétrica induzida, foi atribuída à condução dos íons de sódio; enquanto a segunda, determinada pela eletroluminescência, aos íons de cálcio. Apesar de pequena contribuição na corrente elétrica induzida, os íons de cálcio, devido ao baixo coeficiente de difusão, foram identificados como os responsáveis pela possibilidade de indução de χ(2) estável em vidros soda-lime. Baseado nessas evidências foi utilizado um procedimento alternativo de polarização controlando do fluxo de corrente induzida que permitiu a indução de χ(2) estável. Este efeito pôde ser comprovado existir 12 meses após o processo de polarização, mesmo com redução de ~50% do valor inicial. Observou-se que a eficiência na geração de segundo harmônico pôde ser aumentada em até 3 vezes quando as amostras polarizadas foram bombeadas continuamente com laser Nd-YAG operando no regime QSML. Através de procedimento com tensão elétrica aplicada modulada foi identificada a origem da tensão elétrica de limiar como sendo devido à diferença de mobilidade entre os íons de sódio e cálcio.

Poling

Second harmonic generation

Glasses

Thermal electric field poling

Poling

Geração de segundo harmônico

Vidros

Polarização termoelétrica

Avaliação da cicatrização da pele de rato wistar após múltiplas sessões de terapia fotodinâmica

Angarita, Dora Patricia Ramírez

25 October 2012

Made available in DSpace on 2016-08-17T18:39:46Z (GMT). No. of bitstreams: 1 4853.pdf: 5831443 bytes, checksum: 4e6531437ba418dff23289618e0e9361 (MD5) Previous issue date: 2012-10-25 / Financiadora de Estudos e Projetos / Nonmelanoma skin cancer is the most frequent disease in the world population and it is becoming a public health problem. Due to this fact, new technologies are being tested for the treatment of this disease. Photodynamic Therapy (PDT) is a noninvasive technique with an excellent cosmetic outcome, well tolerated by patients and with good healing results when used for the initial stages of cancer lesions. PDT uses molecular oxygen, light at appropriate wavelengths and the drug photosensitizers to generation of reactive oxygen species such as singlet oxygen responsible for the photoinactivation of target cells. The characteristics of scar tissue after multiple sessions of PDT is not completely understood. It is not known whether multiple sessions of PDT may cause irreversible changes in the treated tissue. Thus, the present study has as its main objective the evaluation of the characteristics of the skin scarred after multiple sessions of PDT. For this study, we used 25 Wistar type male mice. These 25 mice were grouped into 5 subgroups of 5 each: G0, control group, non-subjected to any treatment; G1, exposed to one PDT session and after, there was made a lesion with CO2 laser over the scarred tissue; G2, the group is submitted twice for the same procedure, G3, subjected to 3 times the procedure performed for G1 group; G4, exposed to 4 times the procedure. Once the mice s skin was healed, we performed macroscopic and microscopic evaluations of the histological pieces. Furthermore, we made a microscopic evaluation of collagen fibers and the generation of the second-harmonic through multiphotons microscopy. Macroscopically, it was observed a good healing for the different groups. The aesthetic result showed a decrease after the third and fourth sessions. In the microscopic study, it was observed an conservation of the quantity of sebaceous glands per square millimeter (mm2). The morphology of collagen fibers when evaluated using two-photon excited fluorescence in the confocal microscope, showed thinner fibers with a parallel arrangement and lower density in the G3 e G4 compared to the control group. It was not observed decrease in the generation of second harmonic in histopathology slides. These results suggest that healing in skin after four (4) sessions of PDT/lesion presents alterations in aesthetic and histological of the morphology of collagen fibers that may be related to submitted of the skin in eight (8) consecutive occasions with an incomplete healing between them. / O Câncer de pele não melanoma é o câncer mais frequente da população mundial, se tornando um problema de saúde pública. Devido a essa problemática, novas tecnologias estão sendo testadas para o tratamento desta doença. A Terapia Fotodinâmica (TFD) é uma técnica não invasiva com excelentes resultados estéticos, bem tolerada pelos pacientes e com bons resultados de cura quanto usado para lesões iniciais. Usa o oxigênio molecular, a luz num comprimento de onda adequado e o medicamento fotossensibilizador para formar espécies altamente reativas como o oxigênio singleto responsável pela fotoinativação das células alvo. As características do tecido cicatrizado após múltiplas sessões de TFD não são completamente conhecidas. Ainda não se tem conhecimento se múltiplas sessões de TFD podem ocasionar modificações irreversíveis no tecido tratado. Desta forma, o presente estudo tem como principal objetivo a avaliação das características da pele cicatrizada após múltiplas sessões de TFD. Para este estudo, aprovado pelo comitê de ética e pesquisa foram utilizados 25 ratos machos, da linhagem Wistar, divididos em 5 grupos com 5 animais por cada grupo: G0 controle, não foi submetido a nenhum procedimento; G1, submetidos a uma sessão de TFD na pele do dorso, posteriormente, nesta pele cicatrizada foi feita uma lesão externa com laser de CO2; G2, o grupo passa duas vezes pelo mesmo procedimento explicado anteriormente; G3, o grupo passa três vezes pelo procedimento e para o grupo G4 é repetido os procedimentos em quatro ocasiões. Após a cicatrização dos procedimentos é feita uma avaliação macroscópica, um analise microscópica e uma avaliação da microestrutura das fibras de colágeno e geração do segundo harmônico por microscopia multi-fótons. Macroscopicamente, foi observada uma cicatrização satisfatória para os diferentes grupos tratados se apresentando uma diminuição no resultado estético após a terceira e a quarta sessão. No estudo microscópio, foi evidente uma conservação da quantidade de glândulas sebáceas por mm2. A morfologia das fibras de colágeno apresentaram modificações que foram mais acentuadas na terceira e quarta sessão, se evidenciando fibras de menor espessura, com uma disposição paralela e menor densidade quando comparadas ao grupo controle. Não foi evidente diminuição da geração do secundo harmônico nas lâminas estudadas. A partir destes dados sugere-se que a cicatrização na pele após 4 sessões de TFD/lesão, apresenta modificações no resultado estético, histológico, da morfologia das fibras de colágeno que podem estar relacionadas com acometimento consecutivo da pele em 8 ocasiões com uma cicatrização incompleta entre elas.

Biotecnologia

Terapia fotodinâmica

Cicatrização de feridas

Microscopia confocal

Geração do segundo harmônico

Photodynamic Therapy

Multiple sessions

Wound healing

Confocal microscopy

Second harmonic generation