Characterization of PPLN Crystal Fiber with Second Harmonic Microscopy and Orientation Analysis

Fang, Yao-Ching

08 July 2006

Lithium niobate is a high performance nonlinear optical material that has found wide-spread applications in electro-optical modulation and nonlinear optics. In this study, periodically poled lithium niobate crystal fibers are characterized with SH microscopy. The natural optical sectioning enabled by SH allows rapid and non-destructive mapping of the crystal fiber¡¦s detailed features in 3D (1024x1024 pixel image about 40 minutes). We utilize simulate and Fourier transform to analyze the SHG images, besides observing the variation of SHG efficiency after annealing.

SHG

ppln

Characterization of PPLN Crystal Fiber with Second Harmonic Microscopy

Wu, Song-Chung

27 June 2005

Lithium niobate(LiNbO3)has been widely used in optical frequency converter, electro-optical modulator¡Asurface acoustic waveguide filter¡Aand photorefractive recording due to its ease of growth, high nonlinear coefficient, and excellent optical quality. We think that we can utilize second harmonic generation (SHG) and laser scanning system to construct a reflective SHG system .From this system we can obtain PPLN poling pattern, then we can check the growth condition correctly or not. Compare to traditional method, this approach has the advantage of fast and non-invasive test. Besides, we can find crystal axis of crystal by changing the angle of incidence light and using additional half plate.

shg

linbo3

microscopy

Second-order nonlinear optical interactions and cascading effects in thinorganic films

Ksianzou, Viachaslau

January 2010

The presented work describes new concepts of fast switching elements based on principles of photonics. The waveguides working in visible and infra-red ranges are put in a basis of these elements. And as materials for manufacturing of waveguides the transparent polymers, dopped by molecules of the dyes possessing second order nonlinear-optical properties are proposed. The work shows how nonlinear-optical processes in such structures can be implemented by electro-optical and opto-optical control circuit signals. In this paper we consider the complete cycle of fabrication of several types of integral photonic elements. The theoretical analysis of high-intensity beam propagation in media with second-order optical nonlinearity is performed. Quantitative estimations of necessary conditions of occurrence of the nonlinear-optical phenomena of the second order taking into account properties of used materials are made. The paper describes the various stages of manufacture of the basic structure of the integrated photonics: a planar waveguide. Using the finite element method the structure of the electromagnetic field inside the waveguide in different modes was analysed. A separate part of the work deals with the creation of composite organic materials with high optical nonlinearity. Using the methods of quantum chemistry, the dependence of nonlinear properties of dye molecules from its structure were investigated in details. In addition, the paper discusses various methods of inducing of an optical nonlinearity in dye-doping of polymer films. In the work, for the first time is proposed the use of spatial modulation of nonlinear properties of waveguide according Fibonacci law. This allows involving several different nonlinear optical processes simultaneously. The final part of the work describes various designs of integrated optical modulators and switches constructed of organic nonlinear optical waveguides. A practical design of the optical modulator based on Mach-Zehnder interferometer made by a photolithography on polymer film is presented. / Die vorliegende Arbeit beschreibt neue Konzepte für schnelle photonische Schaltelemente. Diese Elemente basieren auf optischer Wellenleitung im sichtbaren und nahen infraroten Spektralbereich. Die Arbeit ist auf organische Wellenleiter aus transparenten, farbstoffdotierten Polymeren fokussiert, welche Chromophore mit besonders großen optischen Nichtlinearitäten zweiter Ordnung enthalten. Insbesondere wird dargestellt, wie nichtlineare optische Prozesse in derartigen Bauelementen genutzt werden können, wenn man elektrische oder optische Steuersignale einsetzt. Es wird der gesamte Her-stellungszyklus verschiedener integrierter photonischer Bauelemente betrachtet. Die Arbeit umfasst weiterhin eine detaillierte theoretische Analyse der Wellenausbreitung in Medien mit großer nichtlinearer optischer Suszeptibilität zweiter Ordnung bei hoher Lichtintensität. Unter Annahme optischer Materialkonstanten, welche den experimentell ermittelten Werten entsprechen, erfolgte eine quantitative Abschätzung für das Auftreten von Szenarien, bei denen messbare Abwei-chungen der Strahlausbreitung vom linearen Regime auftreten, z:B. das Auftreten von zeitlichen, räumlichen und spektralen Satteliten zu den im Material propagierenden Laserpulsen. Es gelang, we-sentliche Aspekte der Strahlpropagationsprozesse durch Anwendung von Jacobi-Integralfunktionen in geschlossener mathematischer Form darzustellen. Darüber hinausgehende theoretische Untersuchungen nutzten die Finite-Elemente-Methode, um die Verteilung des elektromagnetischen Feldes im Inneren optischer Wellenleiter für verschiedene Pro-pagationsmoden zu analysieren. Ein weiterer Teil der Arbeit beschäftigt sich mit organischen Kompositmaterialen, welche große opti-sche Nichtlinearitäten aufweisen. Mittels quantenchemischer Verfahren erfolgte eine detaillierte Un-tersuchung der Zusammenhänge zwischen der molekularen Struktur und den linearen sowie den nichtlinearen optischen Eigenschaften der untersuchten Farbstoffmoleküle und Polymere. In Bezug auf die Probenpräparation sind unterschiedliche Verfahren zur Schichtbildung und zur molekularen Orientierung miteinander verglichen und bewertet worden, da letztere eine Voraussetzung für das Auftreten nichtlinearer optischer Prozesse zweiter Ordnung bildet. Die Untersuchungen erstreckten sich auf Vakuumaufdampfschichten aus niedermolekularen Chromophoren und auf Polymerschich-ten, welche durch Vakuumabscheidung sowie durch Spincoating oder andere Flüssigphasenabschei-dungsverfahren hergestellt worden sind. Auf orientierenden Substraten (z.B. geriebene Schichten aus Polytetrafluoräthylen) konnte eine spontane Orientierung der deponierten Chromophore nachgewie-sen werden. Die Chromophore in Polymerschichten wurden durch Coronapolung orientiert. In der Arbeit ist zum ersten Mal vorgeschlagen worden, eine räumliche Modulation der nichtlinearen optischen Eigenschaften durch gezielte lokale Coronapolung oder andere Orientierungstechniken derart zu generieren, dass die Abfolge gepolter Domänen dem Bildungsgesetz einer modifizierten Fibonacci-Reihe mit gebrochen rationalen Zahlen gehorcht. Der Vorteil von optischen Wellenleitern mit dieser Struktur darin, dass diese mehrere unterschiedli-che nichtlineare optische Prozesse gleichzeitig unterstützen und somit eine Vielzahl neuartiger Phä-nomene auftreten kann, welche man in neuartigen photonischen Bauelementen, z.B. für die optische Informations- und Kommunikationstechnik nutzen kann. Der letzte Teil der Arbeit beschreibt den Aufbau verschiedener integrierter optischer Modulatoren und Schalter, die sich mit Hilfe das neu entwickelten Verfahrens herstellen lassen. Zukünftige Entwicklungen in der Photonik, insbesondere der optischen Informations- und Kommuni-kationstechnik werden im abschließenden Teil der Arbeit diskutiert.

NLO

SHG

QPM

Cascading

NLO

SHG

QPM

Cascading

Physics

Optical second harmonic generation in bitumen films

Roberts, Aaron Joseph

28 February 2013

The ability of asphalt binders (bitumen) in road surfaces to self-heal after cracking is important to developing a robust transportation system that can tolerate heavy traffic and varying weather conditions. In order to develop improved binders, there is a need for noninvasive, in-situ, interface-specific methods of monitoring the kinetics, physics and chemistry of self-healing bitumen interfaces. Here the feasibility of using optical second-harmonic generation (SHG) by focused femtosecond laser pulses to monitor bitumen surfaces is demonstrated. SHG signals are observed in transmission through a sample composed of bitumen spin-coated onto a borosilicate microscope coverslip. The SHG signals are absent from uncoated coverslips, demonstrating that they originate from the bitumen layer. Further tests demonstrate that the bitumen-air surface makes the dominant contribution to the SHG signal. The SHG signal is observed to decay on a time scale comparable to typical self-healing times because of sample heating by the incident laser irradiation. Methods to control this effect by translating the sample during data acquisition are developed. Although the present results were obtained with a single incident wavelength (800 nm), they demonstrate the feasibility of probing bitumen interfaces spectroscopically with tunable light sources in order to monitor bond-specific chemical kinetics. / text

Bitumen

Second harmonic generation

SHG

Squaraine dyes

Williamson, Patricia Catherine

January 1999

No description available.

547

Anilino; Second harmonic generation; SHG

The Applications of Ultrafast Laser in Microscopic Imaging¡GRF OBIC¡®SHG Microscopy

Shih, Sheng-Chih

09 July 2002

In this study¡Awe apply the broad bandwidth and high energy pulse of ultrafast laser to experiment on RF OBIC and second harmonic generation. In this paper a novel method is presented for characterizing high frequency response and behavior of ultra high-speed photosensitive semiconductor devices and the set-up is capable of generating excitation at RF bandwidths of greater than 1.8 THz. In addition¡Athe collagen of dentine is able to generate the second harmonic in the ultraviolet region, so we develop a high performance transmission mode laser scanning microscope for obtaining SHG images of a tooth slice. We also study wavelength dependence and polarization dependence.

collagen

RF OBIC

SHG

ultrafast laser

Nonlinear optical characterization of advanced electronic materials

Lei, Ming, active 2012

18 November 2013

Continuous downscaling of transistor size has been the major trend of the semiconductor industry for the past half century. In recent years, however, fundamental physical limits to continued downscaling were encountered. In order to overcome these limits, the industry experimented --- and continues to experiment --- with many new materials and architectures. Non-invasive, in-line methods of characterizing critical properties of these structures are in demand. This dissertation develops optical second-harmonic generation (SHG) to characterize performance-limiting defects, band alignment or strain distribution in four advanced electronic material systems of current interest: (1) Hot carrier injection (HCI) is a key determinant of the reliability of ultrathin silicon-on-insulator (SOI) devices. We show that time-dependent electrostatic-field-induced SHG probes HCI from SOI films into both native and buried oxides without device fabrication. (2) Band offsets between advanced high-k gate dielectrics and their substrates govern performance-limiting leakage currents, and elucidate interfacial bond structure. We evaluate band offsets of as-deposited and annealed Al₂O₃, HfO₂ and BeO films with Si using internal photoemission techniques. (3) Epi-GaAs films grown on Si combine the high carrier mobility and superior optical properties of III-V semiconductors with the established Si platform, but are susceptible to formation of anti-phase boundary (APB) defects. We show that SHG in reflection from APB-laden epi-films is dramatically weaker than from control layers without APBs. Moreover, scanning SHG images of APB-rich layers reveal microstructure lacking in APB-free layers. These findings are attributed to the reversal in sign of the second-order nonlinear optical susceptibility [chi]⁽²⁾ between neighboring anti-phase domains, and demonstrate that SHG characterizes APBs sensitively, selectively and non-invasively. (4) 3D integration --- i.e. connecting vertically stacked chips with metal through-Si-vias (TSVs) --- is an important new approach for improving performance at the inter-chip level, but thermal stress of the TSVs on surrounding Si can compromise reliability. We present scanning SHG images for different polarization combinations and azimuthal orientations that reveal the sensitivity of SHG to strain fields surrounding TSVs. Taken together, these results demonstrate that SHG can identify performance-limiting defects and important material properties quickly and non-invasively for advanced MOSFET device applications. / text

High-k

III-V

TSV

SHG

SOI

Photocrosslinkable nonlinear optical polymers and directly-patternable polyimide dielectrics

Bell, William Kenneth, III

15 September 2015

The development of high-efficiency nonlinear optical (NLO) polymers has opened up many opportunities in the field of electro-optics. However, current NLO polymers do not meet stability requirements for semiconductor integration. In an effort to improve this, we examined the effects of crosslinking following electric field poling. A series of photocrosslinkable polymers bearing side chain chromophores was synthesized, poled and evaluated on the basis of the thermal stability of Second Harmonic Generation. Photoinitiation allowed for control of the onset of curing. Crosslinking was monitored by FTIR and optimal conversion was achieved by applying a slow temperature ramp during exposure. The ultimate stability of the poled polymers was directly related to the number of crosslinking substituents attached to the chromophore pendant group. With two reactive groups per chromophore significant SHG was retained at temperatures beyond the polymer Tg. In integrated circuit packaging there is a need for directly-patternable polymers of low dielectric constant. Bridging the gap between the high-value silicon chip and circuit board is a substrate comprising alternating layers of metal conductor and polymer dielectric. PMDA-ODA, an aromatic polyimide, meets many of the requirements for integration and can be patterned using a photobase generator (PBG). Due to absorbance by the PMDA-ODA precursor, this PBG must have activity at visible wavelengths. Several oxime urethanes were synthesized and evaluated as candidate long wavelength PBG. These compounds exhibit clean photochemistry and high visible light sensitivity. Unfortunately, carbamate thermal stability is insufficient for patterning PMDA-ODA. For improved material properties, PMDA-TFMB, a fluorinated polyimide, was also evaluated. Importantly, the polymer precursor is sufficiently transparent to employ thermally-stable near-UV photobases. With photobase, 2.5 micron features were resolved in PMDA-TFMB. An ancillary benefit of this methodology is reduced cure temperature (~200 °C), a traditional drawback of polyimides. This material demonstrates a dielectric constant near 3 and a thermal expansion coefficient (CTE) of approximately 6 ppm/°C in-plane. Through-plane thermal expansion is somewhat problematic, with a CTE of approximately 160 ppm/°C, and will likely require a nanoparticle composite strategy. However, this combination of material and lithographic properties make PMDA-TFMB a promising candidate for this application. / text

NLO

SHG

Photocrosslinking

Photobase generator

Polyimide

Packaging

Preliminary Design of a Scanning Laser Second Harmonic Generation Microscope for Collagen Imaging

Liew, Sean Tsien Jen

January 2014

Second Harmonic Generation (SHG) microscopy has undergone rapid transformation as an imaging tool for research due to its noninvasive properties that provides high resolution images for quantitative analysis. Extensive research has been performed to study the type of materials compatible with SHG but the effects of varying laser wavelengths on SHG efficiency is still poorly understood. The aim of this project is to design and build a scanning laser SHG microscope that is optimised for a 1030 nm giant chirp oscillator (GCO) designed by the University of Auckland. The project has shown that this wavelength is capable of producing SHG in collagen tissues of thickness up to 100 µm. We used nonlinear crystals and collagen samples to acquire signals and high resolution 2D images. The images were found to be of excellent quality with resolutions of up to a few microns to allow accurate measurements of the size and orientation of the fibrillar structures.

Second

Harmonic

Generation

Imaging

SHG

Collagen

Microscopy

Microscopie polarimétrique du collagène de type I par génération de second harmonique dans des systèmes modèles et tissus

Aït-Belkacem, Dora

18 November 2011

La génération de second harmonique (SHG) est un processus non-linéaire qui se produit dans des structures non-centrosymétriques, comme c'est le cas de certains matériaux cristallins ou biologiques. Il consiste à coupler deux champs à la même fréquence pour générer un photon à la fréquence double. La manipulation de la polarisation des champs incidents donne accès à des informations microscopiques et structurales de l'échantillon. De plus, l'utilisation d'une détection polarisée permet de mettre à jour des effets physiques dans les assemblages moléculaires biologiques.Dans ces travaux de thèse, nous nous intéressons principalement à l'étude des fibres de collagène I en SHG polarisée dans des échantillons modèles et des tissus. Nous étendons cette étude à la compréhension de l'interaction des fibres avec leur environnement cellulaire pour ensuite, aborder la problématique des tissus cancéreux. Enfin, nous proposons différents modèles microscopiques de la structure du collagène, évalués par une méthode basée sur la décomposition en série de Fourier du signal polarisé, pour apporter un diagnostic quantitatif sur des échantillons biologiques. / Second harmonic generation (SHG) is a non-linear process which consists in coupling two photons at the same frequency to generate one photon at the twice frequency. It generally occurs in non-centrosymmetric samples such as crystals or molecular assemblies. The manipulation of the optical field polarization gives access to structural and microscopic informations. Moreover, using polarized detection allows to determine physical effects in molecular assemblies.In this Phd thesis, we are particulary interested in studying polarized SHG signals from collagen type I fibers in model samples and tissues. We extend our work to the investigation of the interaction of the fibers with their cellular environment. We also address the problematic of cancerous tissues.Finally, we propose several models for the microscopic structure of collagen, evaluated by a method based on the Fourier decomposition of the polarized SHG signal, to provide a quantitative diagnosis of biological samples.

Optique non-linéaire

Microscopie SHG

Collagène

Tissus

Non-linear optic

SHG microscopy

Collagen

Tissues