Global ETD Search

1	Nonlinear Absorbing platinum(II) Acetylides for Optical Power Limiting Applications Westlund, Robert January 2008 (has links) During the past few decades, laser technology has had a strong impact on our society, providing important contributions to materials processing, data storage, communications, medicine, and defense applications. However, the progress in laser technology has also brought about the development of harmful portable high‐power lasers and tactical laser weapons. As a result, the hazard of being blinded by lasers (accidentally or from hostile use) has increased significantly. Hence, the need for protection against lasers has emerged. In order to protect optical sensors against harmful laser radiation, materials that absorb high intensity light, such as nonlinear absorbing chromophores, are employed. The concept of controlling the intensity of an optical light beam is usually referred to as optical power limiting and can be used efficiently in sensor protection devices.In this thesis, various nonlinear absorbing platinum(II) acetylides have been synthesized and characterized regarding their photophysical and optical limiting properties. Dendronized platinum(II) acetylides were prepared in order to evaluate the site isolation effect offered by the dendritic surrounding. The photophysical measurements reveal that the dendritic encapsulation enhances the phosphorescence, increases the luminescence lifetimes, and improves the optical limiting performance due to reduced quenching of the excited states.Triazole‐containing chromophores were synthesized using click chemistry to achieve functionalized platinum(II) acetylides. It was found that the position of the triazole unit affects the photophysical properties of these chromophores. The most promising results were obtained for the chromophore with the triazole located at the end of the conjugation where it may act as an electron donor, thus contributing to improved two‐photon absorption.A branched platinum(II) acetylide was also prepared in order to investigate the effect of multiple conjugated arms as well as multiple heavy atoms within the same molecule on the optical limiting performance. The star shaped chromophore reached the lowest clamping level of all compounds included in this thesis and constitutes a highly suitable chromophore for optical power limiting applications.The nonlinear absorbing chromophores were also incorporated into novel solid state materials based on PMMA. The actual device fabrication of doped organic glasses as optical limiters for sensor protection is presented, and their optical limiting performance is reported. The obtained organic glasses can reduce the transmission of high intensity light by 97 %. / QC 20100920 optical power limiting Polymer chemistry Polymerkemi
2	Synthesis and development of compounds for nonlinear absorption of light Kindahl, Tomas January 2012 (has links) High-intensity light — for instance that from a laser — can be destructive, not only to the human eye, but also to equipment such as imaging sensors and optical communication devices. Therefore, effective protection against such light is desirable. A protection device should ideally have high transmission to non-damaging light, and should also be fast-acting in order to effectively stop high-intensity light. In working towards a protection device, there is a need to conduct fundamental research in order to understand the processes involved. One of the photophysical processes of special interest in the field of optical power limiting (OPL) is reverse saturable absorption, where a compound in an excited state absorbs light more strongly than it does in its ground state. In this work, several novel organoplatinum compounds for OPL, rationally designed to have a strong reverse saturable absorption, have been synthesized. The compounds have been analyzed using linear and nonlinear absorption spectroscopy, luminescence spectroscopy, and quantum chemistry calculations to gain further knowledge regarding their photophysical properties. In addition to this fundamental research, the absorption capabilities of some of these compounds indicate that they can be used for OPL applications. Consequently, compounds from these studies have been incorporated into a sol–gel glass that could be used in optical systems. / <p>Finansiellt stöd från Kempestiftelsen.</p> Platinum acetylide nonlinear absorption optical power limiting oxazole quantum chemistry calculation quantum chemical calculation triplet absorption
3	Synthesis and optical characterization of optical power limiting platinum(II) acetylides Carlsson, Marcus January 2007 (has links) Interactions between light and a molecule can result in reversible or irreversible changes in properties of both the light and the molecule. Of the many known interactions, nonlinear absorption is a process in which an intense light signal, for instance from a laser, can be moderated. This can be manifested either in a marked lowering of the light’s intensity or in reductions in fluctuations of its intensity. Such an effect is often termed ‘optical power limiting’ (OPL). High power lasers can be very dangerous since their high intensity can damage or destroy eyes and optical sensors. However, there are currently no adequate protective measures against lasers that cover the entire visible region and there is an increasing demand for new or improved OPL materials. Some of the most promising optical power limiting materials are substances that combine nonlinear optical properties with high transparency in normal light, but after activation by a laser beam, their light transmittance falls extremely rapidly via so-called self-activating mechanisms. The platinum(II) acetylides comprise one class of compounds with such properties. In this study, various OPL Pt(II) acetylides were synthesized and their nonlinear optical properties were characterized. The emphasis of the work was on preparation of the compounds, but in order to design organoplatinum chromophores for OPL, attempts were also made to obtain insight into the mechanisms of nonlinear absorption. The work was divided into two main parts. In the first the goal was to find compounds that are good optical limiters in solution. The possibility of isolating the chromophore site by dendron shielding and the effects of incorporating a thiophene ring into the organic molecular system were also explored. In addition, a new route for synthesizing these compounds was developed. The second part was focused on incorporating the most interesting compounds into solid materials. The preparation and characterization of Pt(II) acetylides with molecular groups for covalent attachment to a silica matrix via the solution gel approach is described. Platinum acetylides nonlinear absorption optical power limiting Sonogashira coupling solution gels thiophene Organic chemistry Organisk kemi
4	Squaraine dyes for non-linear optics and organic electronics Shi, Yanrong 05 May 2011 (has links) This dissertation describes the investigation of the synthesis and characterization of new squaraine-based photonic and electronic materials. In the first part of this thesis, squaraine dyes with large conjugation systems, including extended squaraines consisting of bis(donor)substituted vinylene-heterocycles and bis(indolinylenemethyl)squaraine-based oligomers linking through different π-bridges were designed, synthesized and characterized to exhibit strong two-photon absorption (2PA) for femotosecond and nanosecond optical-power limiting applications in the near-infrared (NIR). One of the dendronized squaraine forms smooth and high optical quality films with large NIR transparency window. In the second part, a series of squaraine- and phthalocyanine-based metal complexes were studied. Those dyes did not show large triplet quantum yield but significantly improved photovoltaic performance compared to the metal-free compounds. In the last part, an effective approach on optimizing bis(indolinylenemethyl)-based squaraine sensitizers with various surface anchor groups and π-linkers, achieved high power conversion efficiencies (PCEs) of 6.7% in liquid dye-sensitized solar cells (DSSCs) and 2.7% in solid-state DSSCs, which stand out all the previous reported squaraine-based sensitizers. Two-photon absorption Dye-sensitized solar cells Squaraines Optical-power limiting Organic electronics Nonlinear optics Two-photon absorbing materials Optical materials
5	Nonlinear optical characterization of organic polymers and small molecules and their application towards optical power limiting Marshall, Ariel S. 27 August 2014 (has links) This thesis is concerned with the photophysical and nonlinear optical responses, and applications of a set of conjugated polymers and small molecules in the visible and near-IR spectral regions. Poly(phenylene ethynylene) PPE polymers were substituted with conjugated side-arms in a cruciform fashion to determine the impacts of electronic coupling on the one-photon (1PA), two-photon (2PA), and excited state absorption (ESA) properties of the co-polymer system. The cruciform-like PPEs showed significant changes in their nonlinear and phophysical behavior relative to their linear models, including shifts and splittings of the 1PA bands due to moderate mixing of the lowest singlet excited states, an increase in the 2PA cross section (δ) values, and an increase in the yield of triplet excited-state species. The cruciform-like PPE polymers exhibited effective optical pulse suppression of femtosecond and nanosecond laser pulses over a broad spectral range of ~200 nm in the visible and near-IR. The suppression capability of the cruciform-like PPEs exceeded the best reported value for alkyl-substituted PPE polymers. The spectroscopic effects due to conjugation length, structural configuration, and intramolecular charge transfer (ICT) are discussed for a family of bent donor-acceptor-donor (D-A-D) -type conjugated oligomers, which incorporate electron-rich triarylamine donors and electron-deficient triarylborane acceptor units into its conjugated structure. These organoborane oligomers are highly fluorescent and exhibit strong 2PA in the visible region with δ values as large as 1410 GM, as well as overlapping ESA bands attributed to singlet-singlet and triplet-triplet absorption. Saturation of the molar absorptivity, ε, and δ was observed at less than two repeat monomer units due to conformational disorder in the oligomer with increasing length. Positive solvatochromism of fluorescence with solvent shifts as large as ~70 nm was observed as a result of ICT from the arylamine donors to boryl-centered acceptor sites. The excited-state dynamics also show sensitivity to the solvent environment. Experimental findings suggest that these organoborane oligomers may have potential use as nonlinear material for optical power limiting (OPL) and two-photon sensing applications. The spectral properties of two bis-donor chromophores, (bis(diarylamino)biphenyl (TPD) and distyrylthiophene (DST), were investigated with and without the presence of AgNPs in order to better understand the local-field enhancement and subsequent effects on the photophysics and nonlinear behavior of 2PA dyes. While little changes were observed in the excited-state dynamics, measurements of nanoparticle aggregate-dye composite solutions with TPD revealed a 1.6-enhancement in the two-photon excited fluorescence signal. OPL measurements of nanosecond laser pulses at 532 nm revealed a reduction in threshold energy by a factor of 2 in solutions containing TPD and AgNP aggregates, relative to solutions of TPD alone. DST shows exceptional solubility (>1 M) in several organic solvents and exhibits a 2PA spectrum that overlaps well with its singlet-singlet and triplet-triplet ESA bands. Consequently, DST exhibits effective optical limiting of nanosecond laser pulses through two-photon induced excited-state absorption over a broad spectral range of approximately 200 nm in the red and near-IR. Poly(phenylene ethynylene) Organoboranes Photo-induced charge transfer Optical power limiting Metal nanoparticles Conjugated polymers Conjugated small molecules Nonlinear optical material Photophysics Ultrafast characterization
6	Contrôle et études de matériaux hybrides et plasmoniques pour des applications optiques / Control and studies of hybrid and plasmonic materials for optical applications Liotta, Adrien 05 October 2016 (has links) Les nanoparticules d’or (AuNPs) intriguent tout particulièrement ces dernières années de par leurs propriétés fascinantes. Elles sont variables selon la forme et la taille des nanoparticules ce qui en fait des objets ouvrant des perspectives dans plusieurs domaines. L’or est d’autant plus intéressant qu’il a une grande flexibilité de ces bandes de résonance plasmon de surface, allant du visible au proche infrarouge (IR). Au cours de cette thèse, nous avons donc travaillé sur la synthèse d’AuNPs de tailles et de formes différentes pour pouvoir travailler à de nombreuses longueurs d’onde du visible à l’IR. Cette multitude de AuNPs nous a permis d’étudier l’effet de ces différentes résonances plasmons sur des chromophores afin d’essayer de comprendre les mécanismes de ces interactions. Le but final de ces travaux, outre l’amélioration de la compréhension de ces interactions, est la réalisation de matériaux monolithiques pour l’optique par une approche sol-gel permettant l’incorporation de molécules optiquement actives et de ces systèmes plasmoniques, qui donnent des propriétés intéressantes aux matériaux obtenus. Nous nous sommes intéressés plus précisément aux propriétés d’absorption non-linéaire, dans le but de réaliser des matériaux limiteurs optiques pour protéger des systèmes optiques contre des rayonnements intenses, comme les lasers. Ces systèmes ont commencé à être mis au point dans les thèses précédentes faites au laboratoire mais la compréhension amenée par ces travaux auront permis d’approfondir les interactions particules-chromophores et le rôle de la longueur d’onde de la résonance plasmon afin d’optimiser l’efficacité en limitation optique. / Gold nanoparticles (AuNPs) particularly intrigued over the last decades because of their fascinating properties. They vary according to the size and shape of nanoparticles making objects opening opportunities in many areas. Gold is especially interesting since it has a great flexibility of these resonance surface plasmon bands ranging from the visible to near infrared (IR).In this thesis, we worked on the synthesis of AuNPs of different sizes and shapes in order to be able to work in many wavelengths from visible to IR. This multitude of AuNPs enabled us to study the effect of these different plasmon resonances of chromophores in an effort to understand the mechanisms of these interactions. The ultimate goal of this work, in addition to improving the understanding of these interactions, is the realization of monolithic materials for optics by a sol-gel approach allowing the incorporation of optically active molecules and these plasmonic systems, which give interesting properties to the obtained materials. We focused specifically on nonlinear absorption properties, in order to produce optical limiting materials to protect optical systems against intense radiation, such as lasers.These systems began to be developed in previous PhD thesis made in our laboratory but the understanding brought by this work have helped deepen the particles-chromophore interactions and the role of the wavelength of the plasmon resonance in order to optimize efficiency in optical limiting. Nanoparticules d’or Résonance plasmon Bipyramides Etoiles Chromophores Intéractions Matériaux sol-gel Limitation optique Gold Nanoparticles Plasmon resonance Bipyramids Stars Dye Interactions Sol-Gel Materials Optical power limiting
7	2D-material nanocomposites with nonlinear optical properties for laser protection Ross, Nils January 2021 (has links) Lasers are increasingly used for a wide range of different applications for both civil and military purposes. Due to the distinct properties of laser light, use of lasers often comes with a risk of damage to the human eye and other optical sensors. Therefore, an effective laser protection is needed. 2D-materials is a relatively new class of materials, which have shown to possess many unique properties compared to its bulk counterparts. Some 2D-materials exhibit nonlinear optical (NLO) properties, and specifically optical power limiting (OPL) effects, and have therefore been researched for laser protection applications. In this work, two different 2D-materials, MXene Ti3C2 and graphene oxide (GO), have been combined with a hybrid organic-inorganic polymer, a so called melting gel (MG), to synthesise nanocomposites possessing OPL effects for laser protection applications. Different methods of incorporating the 2D-materials in the polymer matrix as well as the effect on optical properties of different concentrations of 2D-materials were investigated. The prepared nanocomposites were characterised using optical microscopy, spectroscopy and OPL measurements in order to investigate and quantify their linear and nonlinear optical properties. The MG was optically clear, mechanically stable and easy to synthesise, which makes it a suitable candidate as a matrix for a laser protection nanocomposite. Additionally, it was possible to dope the MG with the two different 2D-materials to create nanocomposites showing desirable optical properties in the visible spectrum. However, many samples showed signs of clustered 2D-particles indicating that the dispersion could be improved. Finally, OPL measurements, performed at 532 nm, showed that the MG itself exhibited OPL effects, both 2D-materials showed a stronger OPL effect than the non-doped MG and that GO-doped samples gave a better protection than the MXene samples. optical power limiting OPL laser protection nanocomposites 2D-materials graphene oxide MXene Ti3C2 melting gel graphene two-dimensional materials nonlinear optical properties NLO spectroscopy Nano Technology Nanoteknik
8	Molecular Quadratic Response Properties with Inclusion of Relativity Henriksson, Johan January 2008 (has links) This thesis concerns quadratic response properties and their application to properties in Jablonski diagrams such as resonant two-photon absorption and excited state absorption. Our main interest lies in optical power limiting applications, and in this context, molecules containing heavy metal atoms prove superior. Therefore, we are interested in how relativity affects these properties, and in order to assess this, a four-component relativistic framework is adopted. To properly address the molecular properties of interest, both relativistic effects and electron correlation need to be accounted for. These two properties are not additive, and, therefore, correlation needs to be incorporated into the four-component framework. We present the implementation of quadratic response properties at the four-component density functional level of theory. For second-harmonic generation, we have, with numerical examples, demonstrated that correlation and relativity are indeed not additive and that the inclusion of noncollinear magnetization is of little importance. We report that both electron correlation as well as relativity strongly affect results for second-harmonic generation. For example, relativity alone reduces the µβ-response signal by 62% and 75% for meta- and ortho-bromobenzene, respectively, and enhances the same response by 17% and 21% for meta- and ortho-iodobenzene, respectively. In the four-component framework, we present the implementations of single and double residues of the quadratic response function, which allows for the evaluation of resonant two-photon absorption cross sections and excited state properties. Using these tools, we discuss different levels of approximation to the relativistic Hamiltonian and we demonstrate that for two-photon absorption, a proper treatment of relativistic effects qualitatively alters the spectrum. For example, already for an element as light as neon, significant differences are seen between the relativistic and nonrelativistic spectra as triplet transitions acquire substantial absorption cross sections in the former case. Finally, quantum mechanics in conjunction with electrodynamics is applied to determine clamping levels in macroscopic samples. The microscopic properties of the optically active chromophores are determined by response theory, and then, electrodynamics is used to describe the interactions between the chromophores and incident laser pulses. Using this approach a series of molecules have been investigated and their performances have been compared and ranked in order to find novel materials for optical power limiting applications. relativistic quantum chemistry molecular physics clamping levels four-component Hartree-Fock theory Kohn-Sham density functional theory response theory nonlinear optics second-harmonic generation two-photon absorption excited state properties optical power limiting Computational physics Beräkningsfysik

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