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Photophysical Studies of Photon Upconversion via Triplet-Triplet Annihilation in Polymer Systems with Potential Photovoltaic Applications2014 April 1900 (has links)
The present work reports the study of noncoherent photon upconversion (NCPU) via triplet-triplet annihilation (TTA) in polymer systems. This upconversion mechanism has application in photovoltaic devices through the utilization of sub-band gap photons for potentially enhanced power conversion efficiencies.
First, homomolecular TTA was studied in zinc tetraphenylporphyrin (ZnTPP) in polymer matrices. Here, ZnTPP acts as both the sensitizer and upconverting emitter as TTA yields an S2 excited porphyrin. Use of poly(methyl methacrylate) (PMMA) as the host polymer demonstrates aggregation-driven upconverted fluorescence (UC) by TTA (TTA-UC). The dye-loading ratio of the precursor solution was varied, controlling the degree of pre-aggregation. Power-dependence studies of the champion film demonstrated that TTA-UC is occurring toward the strong annihilation kinetic limit. A sub-linear dependence of upconverted fluorescence on film thickness was observed in this system.
The ZnTPP study was extended to polymers possessing low glass transition temperatures, representing molecular diffusion-driven TTA-UC. Upconverted fluorescence was not observed in ZnTPP in a polyurethane (PU) matrix, likely due to coordination of the PU to the axial position of the Zn2+ ion. Low intensity NCPU via homomolecular TTA was observed in ZnTPP in a poly(ethylene glycol) (PEG) matrix, but the kinetic limit was not determined due to film photodegradation. Dye-loading studies revealed that porphyrin self-quenching was evident at low dye concentrations. Likely reasons for the low upconverted fluorescence intensities realized are this self-quenching and the possibility of PEG coordination to the Zn2+ ion, though it is believed self-quenching is the dominant parasitic effect. Strategies to determine the effect and extent of polymer coordination to the Zn2+ ion are discussed.
The study of polymer-based NCPU is extended to a pair of macromolecules, each containing a single ruthenium tris(bipyridine) (Ru(bpy)3) core and multiple pendant arms, which in turn, each contain eight 9,10-diphenylanthracene (DPA) moieties. A power-dependence study of NCPU in this system is reported, and TTA-UC in the weak annihilation kinetic limit was observed. Upconverted fluorescence quantum yields vary linearly with excitation power in both polymers, consistent with the observed kinetic limit. Stern-Volmer experiments have compared the quenching of Ru(bpy)3 phosphorescence (Ph) by monomeric and polymeric DPA. These data show an enhancement in quenching rate constant for the DPA polymer (pDPA). Kinetic analysis of the Ru-DPA polymers has revealed that the energy scheme realized in this system is intrachain TTET from Ru(bpy)3 core to DPA emitter followed by interchain TTA between excited DPA moieties. Low intensity upconverted fluorescence is observed in Ru-DPA containing thin films. Based on the results presented, the requirements of future photophysically-active polymers are discussed with regards to meaningful application in photovoltaics.
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Design and Synthesis of Photoactive Metal-Organic Frameworks for Photon Upconversion and Energy Transfer StudiesRowe, Jennifer Maria 06 July 2018 (has links)
The synthesis, characterization and photophysical properties of three Zr-based Metalorganic frameworks (MOFs) assembled from 2,6-anthracenedicarboxylic acid (2,6-ADCA, 2,6- MOF) and 1,4-anthracenedicarboxylic (1,4-ADCA, 1,4-MOF), and 9,10-anthracenedicarboxylic acid (9,10-ADCA, 9,10-MOF) are described. The crystal structure of the 9,10-MOF was elucidated by synchrotron powder X-ray diffraction (PXRD) analysis and is isostructural with the well-known UiO-66 framework. The 2,6-MOFs also form highly crystalline, octahedral-shaped structures and was characterized by PXRD. Le Bail refinement of the powder pattern revealed that the 2,6-MOF also has UiO-type crystal structure. Conversely, incorporation of the 1,4-ADCA ligand results in large rod-shaped crystals. The excited-state properties of the MOFs were examined using steadstate diffuse reflectance, steady-state emission spectroscopy and time-correlated single photon counting (TCSPC) spectroscopy and are compared to those of the corresponding ligand in solution. Both the unique fluorescent properties of the ligand as well as individual framework structure, result in distinctive luminescent behavior and dictate the extent of intermolecular interactions. Specifically, the 2,6-MOF displays monomeric emission with a fluorescence lifetime (t) of 16.6 ± 1.1 and fluorescence quantum yield (Ff). On the other hand, the 1,4-MOF displays both monomeric and excimeric emission, with corresponding lifetime values of 7.5 ± 0.01 and 19.9 ± 0.1, respectively and a quantum yield of 0.002 ± 0.0001.
The propensity for photon upconversion through sensitized triplet-triplet annihilation (TTA-UC) was probed in the three anthracene-based MOFs. The MOFs were surface-modified with Pd(II) mesoporphyrin IX (PdMP) as the triplet sensitizer. Upconverted emission from the 9,10-MOF was observed, with a quantum efficiency (FUC) of 0.46 % and a threshold intensity (Ith) of 142 mW/cm2 . The variation of the spacing between the anthracene units in the MOFs was found to have significant impact on TTA-UC. As a result, upconverted emission is only displayed by the 9-10-MOF. The distance between anthracene linkers in the 2,6-MOF are too large for TTA to occur, while the short distances in the 1,4-MOF inhibit upconversion through competitive excimer formation.
To further explore the effects of chromophore spacing on energy transfer processes, a series of zinc-based mixed-ligand MOF were constructed from Zn(II) tetrakis(4- carboxyphenyl)porphyrin (ZnTCPP) and pyrazine, 2,2′-bipyridine (pyz) or 4,4′-bipyridyl (bpy) or 1,4-di(4-pyridyl)benzense (dpbz), comprising ZnTCPP/Zn paddlewheel layers. Across this series, the porphyrin spacing was approximately 6 Å, 11 Å and 16 Å for pyz, bpy and dpbz, respectively. The photophysical properties of the MOFs were explored using stead-state diffuse reflectance spectroscopy and steady-state and time-resolved emission spectroscopies. Florescence quenching studies examined the correlation between porphyrin spacing and efficiency of energy transfer. / Ph. D. / Metal-organic frameworks (MOFs) are crystalline materials composed of metal clusters connected by organic molecules. Their modular nature and synthetic tunability allows for rational design of MOFs with different functionalities and has afforded their application in a variety of fields including gas storage and separation, catalysis, optoelectronics, energy conversion and storage, chemical sensing and biomedicine. MOFs provide an ideal platform for studying the structure-property relationships that govern energy-transfer processes. Furthermore, efficient and long-ranging, directional energy transfer has been demonstrated in MOFs. The work presented in this dissertation focuses on MOFs with applications in solar energy conversion schemes. The design and synthesis of photoactive MOFs is described and the effects of their structure on energy-transfer processes is explored.
Photovoltaic cells (PVCs) absorb sunlight and convert it into electricity. However, only photons that are high enough in energy are absorbed by the PVC, while the lower energy photons are not absorbed and therefore do not contribute to power production, resulting in decreased efficiency of the solar cell. One approach to enhancing solar cell efficiencies is to collect the lower energy photons and convert them into higher energy photons through a process called sensitized photon upconversion (UC). This process involves a molecule (sensitizer chromophore) that absorbs lower-energy photons and then transfers the absorbed energy to a second molecule (acceptor chromophore), which emits higher-energy photons. In order to understand how to optimize the efficiency of the UC process, we integrated sensitizer and acceptor chromophores into MOFs various molecular arrangements and probed UC in these materials. Close proximity and he appropriate orientation between chromophores resulted in UC from the framework.
Natural photosynthetic systems contain highly ordered arrays of chromophores that efficiently absorb sunlight and funnel the energy to a reaction center. Energy-harvesting materials that mimic natural photosynthetic processes also have potential applications in solar energy conversion. Porphyrins are often used in artificial photosynthetic systems because of their similarity to chlorophyll pigments found in nature. In order to design highly efficient artificial photosynthetic systems, we first need to understand how energy transfer processes are influenced by the structure of the system. Therefore, we synthesized a series of MOFs containing Zn=porphyrin layers at varied distances and examined the effects of distance between porphyrin layers on the energy-transfer processes within the MOFs. This work provides insight into the structure-property relationships in photoactive MOFs that can serve as a guide for the rational design of light-harvesting MOFs in future studies.
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Characterization of the optical properties of metalloporphyrins in TiO2 sol-gel films for photon upconversion applications2013 October 1900 (has links)
The photophysical properties of a series of Zn (II) porphyrins adsorbed onto a
semiconductor were investigated using steady-state absorbance and emission
measurements. The ability of the porphyrins to undergo triplet-triplet annihilation (TTA), a photophysical process through which photons in the red and near-infrared (NIR) regions of the optical spectrum can be converted into higher energy photons (upconversion), was explored. Aggregation capabilities were determined to verify possibility of these molecules to undergo triplet-triplet annihilation (TTA). TTA has significant potential for increasing the efficiency of dye-sensitized solar cells (DSSCs) by
upconverting photons in the energy rich NIR region of the solar spectrum. A key
requirement for efficient TTA is aggregation of the sensitizer dye, and in this thesis, we have examined the aggregation of porphyrins in TiO2-based sol-gel films. Solution phase absorption and emission studies were conducted using zinc (II) tetraphenylporphyrin and
three of its functionalized derivatives, tetra(4-aminophenyl)porphyrin Zn(II), tetra(4-carboxyphenyl)porphyrin Zn(II), and tetra(4-sulfonatophenyl)porphyrin Zn(II), to
evaluate their potential as DSSC sensitizers on TiO2 thin films. Mesoporous TiO2 thin films were synthesized, using a polymer-templating sol-gel route, and characterized with
tunneling electron microscopy (TEM), atomic force microscopy (AFM), and UV-Vis absorbance measurements. Spectroscopy measurements were also carried out on porphyrin-sensitized TiO2 thin films and compared to solution-based results. A simple DSSC was constructed and used to further explore the application of zinc (II) porphyrin sensitizers in photovoltaic applications.
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Control of Spin State Dynamics in Quantum Dot-Molecular Composites for Energy Multiplication / エネルギー増倍を目指した量子ドット-有機分子複合系におけるスピンダイナミクスの制御Zhang, Jie 25 January 2021 (has links)
京都大学 / 0048 / 新制・課程博士 / 博士(理学) / 甲第22876号 / 理博第4642号 / 新制||理||1667(附属図書館) / 京都大学大学院理学研究科化学専攻 / (主査)教授 寺西 利治, 教授 島川 祐一, 教授 長谷川 健 / 学位規則第4条第1項該当 / Doctor of Science / Kyoto University / DGAM
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Non-Coherent Photon Upconversion on Dye-Sensitized Nanostructured ZrO2 Films for Efficient Solar Light HarvestingLissau, Jonas Sandby January 2014 (has links)
Photon upconversion by sensitized triplet–triplet annihilation (UC-STTA) is a photophysical process that facilitates the conversion of two low-energy photons into a single high-energy photon. A low-energy photon is absorbed by a sensitizer molecule that produces a triplet excited state which is transferred to an emitter molecule. When two emitter triplet states encounter each other, TTA can take place to produce a singlet excited state which decays by emission of a high-energy (upconverted) photon. While traditional single-threshold dye-sensitized solar cells (DSSCs) have a maximum efficiency limit of ca. 30%, it has been predicted theoretically that implementation of UC-STTA in DSSCs could increase that efficiency to more than 40%. A possible way to implement UC-STTA into DSSCs, would be to replace the standard sensi- tized nanostructured TiO2 photoanodes by upconverting ones loaded with emitter molecules. Following TTA, the excited emitter molecule would be quenched by injection of a high-energy electron into the conduction band of the TiO2. To explore the practical aspects of this strategy for a highly efficient DSSC, in this thesis UC-STTA is studied in model systems based on nanostructured ZrO2 films. These ZrO2 films are a good proxy for the TiO2 films used in DSSCs, and allow for relatively easy optimization and study of UC-STTA by allowing measurements of the upconverted photons without the complications of electron injection into the film. Herein it is experimentally proven that UC-STTA is viable on nanostructured metal oxide films under non-coherent irradiation with intensities comparable to sunlight. Two different system architectures are studied, differing in the position of the molecular components involved in the UC-STTA mechanism. Both architectures have the emitter molecules adsorbed onto the ZrO2 surface, but the sensitizers are positioned either in solution around the nanostructure, or co-adsorbed with the emitters onto the ZrO2 surface. A set of challenges in the study and optimization of the UC-STTA process is identified for each type of system. Proposals are also given for how to further improve the understanding and UC-STTA optimization of these systems toward application in DSSCs to overcome the present solar energy conversion efficiency limit.
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Evaluation of Amyloid Fibrils as Templates for Photon Upconversion by Sensitized Triplet-Triplet Annihilation / Utvärdering av Amyloidfibriller som Stödmaterial för Photon Upconversion via Sensitized Triplet-Triplet AnnihilationBerkowicz, Sharon, Olsson, Helena, Broberg, Henrik January 2017 (has links)
In the face of global warming and shrinking resources of fossil fuels the interest in solar energy has increased in recent years. However, the low energy and cost efficiency of current solar cells has up to this date hindered solar energy from playing a major role on the energy market. Photon upconversion is the process in which light of low energy is converted to high energy photons. Lately, this phenomenon has attracted renewed interest and ongoing research in this field mainly focuses on solar energy applications, solar cells in particular. The aim of this study was to investigate and evaluate amyloid fibrils as nanotemplates for an upconversion system based on the dyes platinum octaetylporphyrin (PtOEP) and 9,10- diphenylanthracene (DPA). This well-known pair of organic dyes upconverts light in the visible spectrum through a mechanism known as sensitized triplet-triplet annihilation. Amyloid fibrils are β-sheet rich protein fibril structures, formed by self-assembly of peptides. Amyloid fibrils were prepared from whey protein isolate using heat and acidic solutions. Dyes were incorporated according to a wellestablished technique, in which dyes are grinded together with the protein in solid state prior to fibrillization. Photophysical properties of pure fibrils and dye-incorporated fibrils were studied using UV-VIS spectroscopy and fluorescence spectroscopy. Atomic force microscopy was further employed to confirm the presence of amyloid fibrils as well as to study fibril structure. Results indicate that amyloid fibrils may not be the optimal host material for the upconversion system PtOEP/DPA. It was found that the absorption and emission spectra of this system overlap to a great deal with that of the fibrils. Though no upconverted emission clearly generated by the dye system was recorded, anti-Stokes emission was indeed observed. Interestingly, this emission appears to be strongly enhanced by the presence of dyes. It is suggested that this emission may be attributed to the protein residues rather than the amyloid structure. Future studies are encouraged to further investigate these remarkable findings. / Intresset för solceller har ökat under de senaste åren, till stor del tillföljd av den globala uppvärmningen och de sinande oljeresurserna. Dagens solceller har dock problem med låg energi- och kostnadseffektivitet, vilket gör att solenergin än så länge har svårt att hävda sig på energimarknaden. Photon upconversion är ett fotofysikaliskt fenomen där fotoner med låg energi omvandlas till fotoner med hög energi. Den senaste tiden har denna process fått förnyat intresse och forskningen inom området har ökat, inte minst med sikte på att integrera processen i solceller och därmed öka dess effektivitet. Målet med denna studie var att undersöka huruvida amyloidfibriller kan användas som stomme för ett photon upconversion-system baserat på platinum-oktaetylporfyrin (PtOEP) och 9,10-difenylantracen (DPA). Dessa två organiska färgämnen är ett välkänt par som konverterar synligt ljus med låg frekvens till mer hög frekvent ljus i det synliga spektrumet, via en mekanism som kallas sensitized triplet-triplet annihilation. Amyloidfibriller är proteinbaserade fiberstrukturer med hög andel β-flak, vilka bildas genom självassociation av peptider. I denna studie skapades amyloidfibriller av vassleprotein genom upphettning i sur lösning. Färgämnena inkorporerades enligt en välbeprövad metod där proteinet mortlas tillsammans med färgämnena i fast tillstånd, innan fibrilleringsprocessen påbörjas. De fotofysikaliska egenskaperna hos fibriller med och utan färgämnen analyserade med UV-VIS samt fluorescensspektroskopi. Atomkraftsmikroskopi användes för att bekräfta att fibriller fanns i proven, samt för att studera dess struktur. De erhållna resultaten antyder att amyloidfibriller inte är ett optimalt material för systemet PtOEP/DPA, delvis på grund av att absorptions- och emissionsspektrumet för systemet överlappar med fibrillernas egna spektrum. Anti-Stokes emission detekterades, men denna är med stor sannolikhet inte orsakad av färgämnena. Dock noterades, intressant nog, att denna emission ökar betydligt i närvaro av färgämnena. En möjlighet är att denna emission är kopplad till monomerer i proteinet snarare än till fibrillstrukturen, eftersom emission observerades hos både nativt och fibrillerat protein. Framtida studier uppmuntras att vidare undersöka dessa effekter.
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UPCONVERTING LOW POWER PHOTONS THROUGH TRIPLET-TRIPLET ANNIHILATIONWilke, Bryn 25 April 2012 (has links)
No description available.
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Detekce luminiscenčních nanočástic v rostlinách laserovou spektoroskopií / Detection of luminescent nanoparticles in plants by laser spectroscopyStřítežská, Sára January 2021 (has links)
This diploma thesis deals with evaluation of toxicity and bioaccumulation of photon-upconversion nanoparticles (UCNPs) in model plant maize (Zea mays). Lanthanide-doped UCNPs with different composition and size were tested in three different concentrations in this work. The exposure took place for 168 hours. Toxicity was assessed based on four macroscopic toxicological endpoints (mortality, the length of belowground part of the plants, the length of aboveground part of the plants and whole plants length). Spatial distribution of elements yttrium, ytterbium, erbium and gadolinium in model plants was determined using laser induced breakdown spectroscopy with spatial resolution of 100 m and 26 m. Distribution of UCNPs in plants was further studied with photon-upconversion microscanning with spatial resolution of 40 m. Stability of UCNPs during and after the plant exposure was also discussed in this thesis.
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Development and Evaluation of Novel Light-Responsive Drug Delivery Systems from Alkoxyphenacyl PolycarbonatesWehrung, Daniel 11 September 2015 (has links)
No description available.
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NaYF4:Yb,Er Upconversion Nanocrystals: Investigating Energy Loss Processes for the Systematic Enhancement of the Luminescence EfficiencyGrauel, Bettina 23 May 2022 (has links)
Aufkonvertierende (upconverting; UC) Nanomaterialien bilden eine neue Klasse nichtlinearer lumineszenter Reporter, die nah-infrarotes (NIR) Anregungslicht in Photonen von höherer Energie umwandeln. Das effizienteste bekannte UC-System bildet hierbei β-NaYF4: 20%Yb(III), 2%Er(III) mikrokristallines Bulkmaterial, für welches UC-Quantenausbeuten (ΦUC) von 10 % berichtet werden, während ΦUC von Nanokristallen (nanocrystals; NC) um mehrere Größenordnungen niedriger sein können. Um die Effizienz von UC-Nanomaterialien zu erhöhen, werden NC üblicherweise mit inerten Schalen versehen. In dieser Arbeit werden mehrere verschiedene Bulkmaterialien spektroskopisch untersucht, um ein Vergleichsmaterial auszuwählen, das als Maßstab für alle folgenden, vergleichbaren Messungen an NC dient. Die Oberfläche von ultrakleinen (3.7±0.5) nm NC wird mit Schalen von bis zu 10 nm Dicke versehen, um die optimale Schalendicke für vollständige Oberflächenpassivierung zu identifizieren, allerdings weisen die Ergebnisse auf eine mögliche Kern-Schale-Durchmischung hin. In einer zweiten Studie werden die unterschiedlichen Dotanden, Er(III) und Yb(III), auf ihre optischen Eigenschaften sowie die Einflüsse von Energietransfer (ET) und von ihrer Umgebung spektroskopisch untersucht. Dabei kann klar zwischen Oberflächeneffekten und oberflächenunabhängigen Volumeneffekten unterschieden werden. Die Ergebnisse werden durch ein einfaches Monte-Carlo-Modell gestützt, durch das die größen- und leistungsdichte-(P-)abhängigen Populierungsdynamiken der strahlenden Banden von Er(III) vorhergesagt werden können. Zuletzt werden durch eine verbesserte Synthesemethode UCNC mit stark verbesserten Lumineszenzeigenschaften hergestellt, mit denen bei vergleichsweise niedrigen P die gleichen ΦUC wie beim Bulkmaterial erreicht werden. Dies liefert einen Einblick in vielfältige Anwendungsmöglichkeiten für UCNC. / Upconversion (UC) nanomaterials are an emerging new class of non-linear luminescent reporters which convert near-infrared (NIR) excitation light into higher-energy photons. The most efficient known UC material is the β-NaYF4: 20%Yb(III), 2%Er(III) bulk (microcrystalline) phosphor with reported UC quantum yields (ΦUC) of 10 %, while ΦUC of nanocrystals (NC) can be several orders of magnitude lower. Strategies to improve the efficiency of UC nanomaterials include surface passivation with inert shells. In this work, several different bulk materials are compared to select one benchmark material for
comparisons with NC analyzed with the same measurement techniques. The surface of ultrasmall (3.7 ± 0.5) nm NC is coated with inert shells of up to 10 nm thickness to identify an optimal shell thickness for complete surface passivation, but the results suggest core-shell intermixing. To distinguish between the different dopant ions, Er(III) and Yb(III), and the effect of energy transfer (ET) in a second study, single- and co-doped UCNC are investigated spectroscopically and the influence of their environment is determined thoroughly. Herein, a clear distinction between surface-related and surface-independent, volume-related effects is achieved and the results are emphasized by the use of a simple random walk model which accurately predicts size- and power density (P)-dependent population dynamics of the emissive bands of Er(III). Finally, utilizing an improved synthesis technique, UCNC with enhanced luminescence properties are produced, reaching the same ΦUC as the benchmarked bulk material at reasonably low P, providing an insight into numerous possible
applications of UCNC.
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