Photophysical and Photosensitizing Properties of Dimetal Quadruply Bonded Paddlewheel Complexes Probed Through Ultrafast Spectroscopy

Brown-Xu, Samantha E.

10 October 2014

No description available.

Chemistry

Manipulating Photocarrier and Exciton Transport in Hybrid and Molecular Semiconductors

Linrui Jin (13162254)

27 July 2022

<p> Excitons represent the electronic excited state of organic semiconductor and many low-dimensional inorganic semiconductors. In solar energy conversion systems, exciton transport affects how fast the charges reach the electrodes thus governs the performance of photovoltaic cells. In optoelectronic applications such as semiconductor lasers and light-emitting diodes, exciton radiative rate determines the efficiency of luminescence in competition to various nonradiative processes. Therefore, understanding how exciton migrates over space as well as its decay dynamics are vital for the design of highly efficient optoelectronic devices. To interrogate these photophysical processes requires experimental tools with simultaneous high temporal and spatial resolution. In this thesis, I introduce two transient imaging systems (photoluminescence imaging with 300 ps time resolution, and transient absorption microscopy with 200 fs time) that are innovative tools to directly probe excited state dynamics and transport in sub-μm domains. The techniques were applied to a type of promising semiconductor, perovskites, including surface-passivated hybrid perovskite and 2D layered perovskites to explore the fundamental mechanisms that affect exciton transport. The fundamental understanding of excitons shed light on the underlying physics such as exciton delocalization, exciton-exciton interaction, and how these properties affected by the static and dynamic disorders of the material. We further demonstrated a novel twisted superlattice using ultrathin perovskites that confines excitons due to increased density of state from the moiré flat bands. In addition, excitons can be accelerated by strongly interacts photons, forming polariton quasiparticles that possess small effective mass. This is demonstrated by coupling 2D layered perovskites to a plasmonic array. We further showcase the formation of bulk polaritons without an external optical cavity in a self-assembled organic aggregate. Experimental investigation into these intriguing phenomena provide an approach to study fundamental processes such as many-body interaction and quantum coherence. </p>

Photochemistry

Nonlinear optics and spectroscopy

Exciton

Carrier dynamics

Polariton

Ultrafast spectroscopy

Transient Absorption Microscopy

Perovskite

NONLINEAR AND ULTRAFAST OPTICAL STUDIES OF INTERFACIAL PROCESSES IN PHOTOVOLTAIC NANOMATERIALS

FANG, HUI, 0000-0002-4024-1234

January 2020

The development of efficient solar energy conversion devices has attracted much attention. Despite the fact that progress have been achieved, a fundamental understanding examining why efficiency can be improved remains elusive. For example, dye-sensitized solar cells (DSSC) exhibit high conversion efficiency when acetonitrile is used to prepare both the working electrode and the electrolyte. However, the mechanism explaining exactly how solvent influences device performance has not yet been systematically investigated. Another prominent example is the metal/semiconductor heterojunction systems. While it has been demonstrated that such mixed systems can significantly improve solar conversion efficiency, the mechanism of the electron dynamics driving these systems remains controversial. This stems in part from the fact that the experimentally deduced time constants, which are characteristic of such systems, are only ever extracted from phenomenological models and therefore cannot be assigned to specific physical processes. Ultimately, the development of a physical model is necessary to obtain an unambiguous physical picture of the solar conversion process. In this dissertation, the ultrafast nonlinear spectroscopic methods, second harmonic light scattering (SHS) and transient absorption (TA) spectroscopy, have been employed to study dye molecular adsorption and charge transfer dynamics in several solar energy conversion systems, including 1) DSSC, where solvent effects are investigated to understand why acetonitrile is the most effective solvent; 2) Ag/TiO2 heterostructure system, where a physical model is proposed to quantitively analyze the electron dynamics; 3) porphyrin/Ag/TiO2 nanocomposite, where we found there is no electron injection from porphyrin to TiO2 and plasmonic metal can enhance the porphyrin dye adsorption to improve the device efficiency. The propensity for surface adsorption of two related dyes, ortho-ethyl red (o-ER) and para-ethyl red (p-ER), onto TiO2 particles is studied with SHS. While p-ER readily adsorbs onto TiO2, o-ER does not. It is suggested that this difference is linked to the effects of the steric hindrance of the adsorbate. The influence of the solvent on the adsorption of p-ER onto TiO2 is also investigated. Of significance, p-ER can only chemically bond to the TiO2 surface in aprotic solvents, where adsorption free energy scales with solvent polarity. For protic solvents, preferential adsorption of the solvent shell ultimately prevents direct adsorption of p-ER onto the surface of TiO2. Likewise, solvent effects on charge transfer from p-ER to TiO2 are studied by TA. The electron injection rate is shown to be positively related to solvent polarity. Overall, highly polar aprotic solvents are shown to facilitate dye adsorption and electron injection, which helps improve the efficiency of DSSC devices. Ultrafast dynamics of plasmon-induced hot electrons from Ag to TiO2 nanorods are probed by TA. The observed transient signal, which corresponds to the lifetime of the optically generated electrons, is analyzed using a physical model including electron injection, relaxation, band edge annihilation, the surface to bulk diffusion, and back diffusion from the bulk to the surface. A ca. 13 fs electron injection time is deduced for Ag to TiO2, which is faster than that generated in Au and dyes. Additionally, the excited state exciton dynamics of a porphyrin J-aggregate are investigated and subsequently modeled. More rapid dynamics are found following aggregation of the porphyrin, which can be attributed to the inclusion of more efficient relaxation channels. However, no electron injection from the J-aggregate to TiO2 is observed. This likely stems from the negatively charged repulsion between the two components. Further, when the J-aggregate is introduced into an Ag/TiO2 system, optical excitation occurs predominantly in the J-aggregate. This stems either from direct excitation of the J-aggregate or indirect excitation through plasmon-induced resonant energy transfer from Ag. Our results indicate that plasmon can enhance the dye adsorption, which has great potential for designing more efficient plasmonic DSSC devices. / Chemistry

Chemistry

Physical Chemistry

Optics

Electron Dynamics

Molecule Adsorption

Nonlinear Optical Spectroscopy

Photovoltaic and Photocatalysis

Surface and Interface

Ultrafast Spectroscopy

Femtosekunden-zeitaufgelöste Fluoreszenzspektroskopie von solvatochromen Sonden: Eine Suche nach lokaler Wasserdynamik

Gerecke, Mario

13 December 2017

In dieser Arbeit wurde die Methode der breitbandigen fs-zeitaufgelösten Fluoreszenzaufkonversionsspektroskopie (FLUPS) weiterentwickelt und vollständig theoretisch beschrieben, was anhand des Vergleichs von vorhergesagten und experimentell bestimmten photometrischen Korrekturfunktionen gezeigt werden konnte. Die Methode wurde verwendet, um lokale Fluoreszenzspektren von solvatochromen Sonden in der Nähe bestimmter Matrizes in wässrigen Lösungen zu messen. Aus der Dynamik der Stokes-Verschiebung konnte die Solvatations- bzw. Umgebungsdynamik bestimmt werden. Es wurden mittlere Solvatationszeiten τsolv von 0.57±0.06 für reines Wasser, 2.8±0.2 ps für DNA, 480±30 ps für Phospholipid-Kopfgruppen, 0.71±0.03 ps für ein Peptid (α-Helix) und 0.76±0.03 ps für eine t-Butyl-Gruppe erhalten. Hervorzuheben sind dabei die überraschend schnelle Relaxation nahe des Peptids und die sehr langsame Dynamik nahe der Lipid-Kopfgruppen, welche über 5 Größenordnungen der Zeit beobachtet wurde. Um den Einfluss einer hydrophoben Gruppe auf die Solvatationsdynamik erstmals zu aufzuzeigen, wurden präzise Messungen bei verschiedenen Temperaturen vor-genommen. Zuordnungen dieser Dynamiken zu molekularen Prozessen konnten durch Vergleiche zu MD-Simulationen durchgeführt werden. / The method of broadband fs time-resolved fluorescence upconversion spectroscopy (FLUPS) was further developed and completely theoretically described in this work. This was shown by comparing predicted and measured photometric correction functions. This method was used to obtain local fluorescence spectra of solvatochromic dyes near certain matrices in aqueous solution. From the dynamics of the Stokes-Shift the solvation or environmental dynamics respectively were obtained. Average solvation times τsolv of 0.57±0.06 for bulk water, 2.8±0.2 ps for DNA, 480±30 ps for phospholipid head groups, 0.71±0.03 ps for a peptide (α-helix) and 0.76±0.03 ps for a t-butyl group were obtained. Emphasized are the surprisingly fast dynamics near the peptide and the slow dynamics of the lipid head group region. The latter was observed over 5 orders of magnitude in time. To distinguish the influence a hydrophobic group for the first time, precise measurements at different temperatures were performed. Molecular processes were assigned to the obtained dynamics by comparisons to MD studies.

Ultraschnelle Spektroskopie

Zeitaufgelöste Fluoreszenz

Farbstoffe

Wasserdynamik

Ultrafast spectroscopy

Time-resolved fluorescence

Chromophores

Water dynamics

541 Physikalische Chemie

VG 8857

WC 2600

VG 8757

VK 8567

ddc:541

Espectroscopia ultrarrápida do polímero semicondutor luminescente MEH-PPV com excitação no ultravioleta / Ultrafast spectroscopy of the luminescent semiconducting polymer MEH-PPV with ultraviolet excitation

Faleiros, Marcelo Meira

17 August 2012

A indústria optoeletrônica passa por um período de transformação em que os materiais inorgânicos estão sendo substituídos pelos orgânicos, oligômeros e polímeros, na fabricação de alguns tipos de dispositivos. No entanto, fatores como baixa eficiência e tempo de vida impedem que os aparelhos com base nos polímeros entrem definitivamente no mercado. Para resolver estas questões, é necessário um conhecimento profundo da estrutura eletrônica desses materiais. Apesar do avanço científico, ainda existem pontos a esclarecer. Por exemplo, não existe um consenso sobre a natureza das excitações óticas primárias e dos processos não radiativos nos polímeros conjugados, principalmente com excitação no ultravioleta. Tais processos limitam a eficiência e podem influenciar nos processos fotoquímicos, determinando o tempo de vida de um dispositivo. Esses fenômenos ocorrem em alguns picossegundos e, portanto, a espectroscopia ultrarrápida é a técnica mais adequada para o seu estudo. Neste trabalho, foi implementado o aparato para espectroscopia de bombeio e prova em filmes finos de polímeros conjugados, no qual podem ser usados dois métodos de aquisição de dados, sensível à fase e pulso-a-pulso. O primeiro é o método padrão citado na literatura, no qual o feixe de excitação é modulado por um chopper e os sinais são medidos por amplificadores lock-in. No segundo, o condicionamento de sinais é feito por circuitos amplificadores e o processamento dos sinais é feito pulso-a-pulso. É um método que a princípio fornece melhor estatística, pois as flutuações do laser são normalizadas pulso-a-pulso, e não na média. Além disso, apresenta menor custo e torna o experimento de bombeio e prova mais simples, pois os únicos procedimentos críticos passam a ser a sobreposição dos feixes na amostra e a determinação do atraso zero entre bombeio e prova. Foi projetado e construído o circuito eletrônico de condicionamento de sinais e o software de aquisição foi desenvolvido em linguagem LabVIEW. Entretanto, o método pulso-a-pulso forneceu uma sensibilidade inadequada para o estudo de filmes poliméricos, (&Delta;T&frasl;T ~ 0,7%, limitada pelo ruído elétrico na amplificação dos pulsos detectados), em contraste com &Delta;T/T ~ 0,1% que foi alcançada pelo método sensível à fase. Desta maneira, foi usado o último método para o estudo da evolução do espectro e da dinâmica de emissão estimulada de um filme de MEH-PPV, com excitação no visível e no ultravioleta, permitindo o estudo da dinâmica de relaxação dos estados de mais alta energia. Os resultados no visível são compatíveis com os da literatura, o que demonstra a confiabilidade do aparato quanto à sensibilidade e resolução temporal e espectral. Os resultados com excitação no UV indicam que a transferência de energia de bandas mais energéticas para a banda &pi; - &pi;&lowast; (conversão interna) ocorre em aproximadamente 300 fs, confirmando as suposições da literatura quanto à relaxação energética ultrarrápida (regra de Kasha), além de sugerir a existência de bandas ainda mais energéticas do que as já conhecidas. Pretende-se futuramente determinar a eficiência de tal transferência energética, pois ela pode ser um fator limitante na eficiência de fotoluminescência em polímeros conjugados com excitação no ultravioleta. / The optoelectronics industry is currently undergoing a transition period in which inorganic materials are being replaced by organic materials, oligomers and polymers, in the fabrication of some types of devices. However, factors such as low efficiency and low lifetime prevent polymer based devices on entering the market definitely. The solution of these issues requires a thorough knowledge of the electronic structure of these materials, but despite of scientific advances, there are still points to be clarified. For example, there is no consensus on the nature of the primary optical excitations and non-radiative processes in conjugated polymers, specially with ultraviolet excitation. Such processes limit the efficiency and can influence the photochemical processes, determining the device lifetime. These phenomena occur on a femtosecond timescale and therefore, ultrafast spectroscopy is the most appropriate technique for their study. In this work, we implemented the apparatus for pump-probe ultrafast spectroscopy on thin films of conjugated polymers, which can be used with two methods of data acquisition, phase-sensitive and shot-by-shot. The first is the standard method reported in the literature in which the excitation beam is modulated by a chopper and the signals measured by lock-in amplifiers. In the second, the detector signal conditioning is done by conventional amplifier circuits, followed shot-to-shot signal processing. This method provides the best statistics, in principle, because the laser fluctuations are normalized for each pulse, instead of using the average. In addition, the apparatus has a lower cost and the experiment is simpler, having as critical procedures the alignment of the beams on the sample and the determination of zero delay, with all other procedures done via software. The electronic circuitry for signal conditioning was designed and built and data acquisition software that enables measurements with both methods was developed in the LabVIEW programming language. However, the shot-by-shot method provided an inadequate sensitivity for the study of polymeric films (&Delta;T&frasl;T ~0.7%, limited by electronic noise in the amplification of detector signals), compared with &Delta;T&frasl;T ~ 0.1%, which was achieved by the phase sensitive method, and was the goal at the beginning of the project. Thus, the latter method was used to study the evolution of the spectrum and dynamics of stimulated emission of a film of MEH-PPV, with excitation in the visible and UV, allowing the study of the dynamics of higher lying electronic states. The results in the visible are consistent with those reported in the literature, which demonstrates the performance of the apparatus with respect to sensitivity and time/spectral resolution. The results with UV excitation indicate that the energy transfer among the more energetic bands to the &pi; - &pi;* band (internal conversion) occurs in about 300 fs, confirming the assumptions of the literature on the ultrafast energy relaxation processes (Kashas rule), besides suggesting the existence of even more energetic bands than those currently known. As future work, we plan to measure the efficiency of this energy transfer process, since it may be the limiting step in determining the overall photoluminescence efficiency of conjugated polymers with ultraviolet excitation.

Conjugated Polymers

Espectroscopia ultrarrápida

Excitação no UV

Polímeros conjugados

Processos óticos ultrarrápidos

Pump-probe technique

Técnica de bombeio e prova

Ultrafast optical processes

Ultrafast spectroscopy

UV excitation

Revelando a estrutura eletrônica de nanomateriais através de espectroscopia óptica avançada / Revealing the electronic structure of nanomaterials using advanced optical spectroscopy

Nagamine, Gabriel, 1992-

29 June 2017

Orientador: Lázaro Aurélio Padilha Junior / Dissertação (mestrado) - Universidade Estadual de Campinas, Instituto de Física Gleb Wataghin / Made available in DSpace on 2018-09-02T09:51:28Z (GMT). No. of bitstreams: 1 Nagamine_Gabriel_M.pdf: 6846623 bytes, checksum: 1daab6ac65771517c50786728dfce86e (MD5) Previous issue date: 2017 / Resumo: Pontos quânticos coloidais (QDs) ternários de CuInS2 (CIS) surgiram como uma alternativa não tóxica, altamente promissora, aos já bem estabelecidos QDs binários de CdX e PbX (X=Se,S). Além de não possuírem metais pesados em sua composição, esses novos materiais apresentam diversas características desejáveis, o que os torna fortes candidatos a serem aplicados em novas tecnologias, tanto em biologia quanto na geração de nova fontes de energia renovável. Além disso, esses QDs apresentam diversas propriedades ópticas que os diferem radicalmente dos QDs binários já conhecidos e ainda são pouco compreendidas. Dentre elas, podemos citar um largo espectro de fotoluminescência (PL), com decaimentos longos e multi-exponenciais e um espectro de absorção pouco definido, com uma longa cauda que vai para o infravermelho. Adicionalmente, esses nanomateriais apresentam um grande Stokes shift, de até 500 meV, cuja origem ainda é desconhecida e amplamente debatida na literatura. Com o intuito de desvendar os mecanismos por trás dessas propriedades distintas, nesse trabalho, realizamos uma série de estudos da sua dinâmica ultrarrápida e de espectroscopia não-linear para revelar a estrutura eletrônica desses QDs. Das medidas de dinâmica ultrarrápida, mostramos uma maneira alternativa de medir-se o tamanho dessas nanopartículas, por meio da sua seção de choque de absorção em 3,1 eV, que seria independente da variabilidade morfológica apresentada por elas. Adicionalmente, fazendo um estudo da dependência das interações multi-éxciton desses QDs com o tamanho, reportamos que esses nanomateriais apresentam interações Coulombianas reduzidas em relação aos QDs binários já conhecidos. Das medidas de espectroscopia não-linear, mostramos a primeira comprovação experimental de que a transição óptica entre os níveis fundamentais da banda de valência e condução é proibida por paridade em partículas esféricas. Além disso, comparando o espectro de absorção de 2 fótons das amostras estudadas com imagens de microscopia eletrônica de transmissão (TEM), mostramos que quebras na simetria das funções de onda dos portadores nesses QDs alteram as suas regras de seleção para transições ópticas. Adicionalmente, verificamos que, controlando a composição e tamanho desses QDs, é possível obter seções de choque de 2PA de até 13.500 GM dentro da janela de transparência óptica do tecido do corpo humano / Abstract: Ternary CuInS2 (CIS) Colloidal Quantum Dots (QDs) have emerged as a non-toxic promising alternative to the CdX and PbX (X=Se,S) binary QDs. Besides not having heavy metals on their composition, these new materials show several desirable features, which makes them strong candidates to be applied in new technologies, from biology to the new generation of renewable energy sources. Furthermore, these QDs present various optical properties that radically differs from the already well studied binary QDs and yet are not well understood. Among them, we can cite a large photoluminescence (PL) spectra, with long and multi-exponential decays and a poorly defined absorption spectra, with a long infrared tail. Additionally, these nanomaterials present large Stokes shift, up to 500 meV, whose origin is still not well understood and largely debated on the literature. To reveal the mechanism behind these distinguished properties, here, we perform a series of ultrafast spectroscopy and non-linear spectroscopy studies to reveal the electronic band structure of these QDs. From the ultrafast dynamics measurements, we show an alternative way to measure the size of these nanoparticles, through their absorption cross section in 3,1 eV, which would be independent from the morphologic variability presented by them. Additionally, by performing studies of the size dependent multi-exciton interactions, we report that these kind of nanomaterials present reduced Coulombic interactions in relation to de already known binary QDs. From the non-linear spectroscopy measurements, we show the first experimental confirmation that the optical transition between the electron and hole ground state are parity forbidden in the spherical particles. In addition, comparing the two-photon absorption (2PA) spectra of the studied samples with their transmission electron microscopy images, we show that symmetry breaking of the electronic wave functions in these QDs change their optical transition selection rules. Additionally, we verify that, by controlling the size and composition of these QDs, it is possible to obtain 2PA cross section as high as 13,500 GM inside the transparency window of the human tissue / Mestrado / Física / Mestre em Física / 1547612/2015 / 13/16911-2 / CAPES / FAPESP

Pontos quânticos

Dissulfeto de cobre e índio

Efeito Auger

Espectroscopia ultrarrápida

Deslocamento Stokes

Absorção de dois fótons

Quantum dots

Copper indium sulfide

Auger effect

Ultrafast spectroscopy

Stokes shift

Two-photon absorption

Charge carrier relaxation in halide perovskite semiconductors for optoelectronic applications

Richter, Johannes Martin

January 2018

Lead halide perovskites have shown remarkable device performance in both solar cells and LEDs. Whilst the research efforts so far have been mainly focussed on device optimisation, little is known about the photophysical properties. For example, the nature of the bandgap is still debated and an indirect bandgap due to a Rashba splitting has been suggested. In this thesis, we study the early-time carrier relaxation and its impact on photoluminescence emission. We first study ultrafast carrier thermalization processes using 2D electronic spectroscopy and extract characteristic carrier thermalization times from below 10 fs to 85 fs. We then investigate the early-time photoluminescence emission during carrier cooling. We observe that the luminescence signal shows a rise over 2 picoseconds in CH3NH3PbI3 while carriers cool to the band edge. This shows that luminescence of hot carriers is slower than that of cold carriers, as is found in direct gap semiconductors. We conclude that electrons and holes show strong overlap in momentum space, despite the potential presence of a small band offset arising from a Rashba effect. Recombination and device performance of perovskites are thus better described within a direct bandgap model. We finally study carrier recombination in perovskites and the impact of photon recycling. We show that, for an internal photoluminescence quantum yield of 70%, we measure external yields as low as 15% in planar films, where light out-coupling is inefficient, but observe values as high as 57% in films on textured substrates that enhance out-coupling. We study the photo-excited carrier dynamics and use a rate equation to relate radiative and non-radiative recombination events to measured photoluminescence efficiencies. We conclude that the use of textured active layers has the ability to improve power conversion efficiencies for both LEDs and solar cells.

Ultrafast spectroscopy of semiconductor nanostructures

Wen, Xiaoming, n/a

January 2007

Semiconductor nanostructures exhibit many remarkable electronic and optical properties. The key to designing and utilising semiconductor quantum structures is a physical understanding of the detailed excitation, transport and energy relaxation processes. Thus the nonequilibrium dynamics of semiconductor quantum structures have attracted extensive attention in recent years. Ultrafast spectroscopy has proven to be a versatile and powerful tool for investigating transient phenomena related to the relaxation and transport dynamics in semiconductors. In this thesis, we report investigations into the electronic and optical properties of various semiconductor quantum systems using a variety of ultrafast techniques, including up-conversion photoluminescence, pump-probe, photon echoes and four-wave mixing. The semiconductor quantum systems studied include ZnO/ZnMgO multiple quantum wells with oxygen ion implantation, InGaAs/GaAs self-assembled quantum dots with different doping, InGaAs/InP quantum wells with proton implantation, and silicon quantum dots. The spectra of these semiconductor nanostructures range from the ultraviolet region, through the visible, to the infrared. In the UV region we investigate excitons, biexcitons and oxygen implantation effects in ZnO/ZnMgO multi-quantum wells using four-wave mixing, pump-probe and photoluminescence techniques. Using time-resolved up-conversion photoluminescence, we investigate the relaxation dynamics and state filling effect in InGaAs self-assembled quantum dots with different doping, and the implantation effect in InGaAs/InP quantum wells. Finally, we study the optical properties of silicon quantum dots using time-resolved photoluminescence and photon echo spectroscopy on various time scales, ranging from microseconds to femtoseconds.

Ultrafast spectroscopy

ZnO quantum wells

InGaAs quantum dots

silicon quantum dots

up-conversion photoluminescence

pump-probe

four wave mixing

transient grating

Espectroscopia ultrarrápida do polímero semicondutor luminescente MEH-PPV com excitação no ultravioleta / Ultrafast spectroscopy of the luminescent semiconducting polymer MEH-PPV with ultraviolet excitation

Marcelo Meira Faleiros

17 August 2012

A indústria optoeletrônica passa por um período de transformação em que os materiais inorgânicos estão sendo substituídos pelos orgânicos, oligômeros e polímeros, na fabricação de alguns tipos de dispositivos. No entanto, fatores como baixa eficiência e tempo de vida impedem que os aparelhos com base nos polímeros entrem definitivamente no mercado. Para resolver estas questões, é necessário um conhecimento profundo da estrutura eletrônica desses materiais. Apesar do avanço científico, ainda existem pontos a esclarecer. Por exemplo, não existe um consenso sobre a natureza das excitações óticas primárias e dos processos não radiativos nos polímeros conjugados, principalmente com excitação no ultravioleta. Tais processos limitam a eficiência e podem influenciar nos processos fotoquímicos, determinando o tempo de vida de um dispositivo. Esses fenômenos ocorrem em alguns picossegundos e, portanto, a espectroscopia ultrarrápida é a técnica mais adequada para o seu estudo. Neste trabalho, foi implementado o aparato para espectroscopia de bombeio e prova em filmes finos de polímeros conjugados, no qual podem ser usados dois métodos de aquisição de dados, sensível à fase e pulso-a-pulso. O primeiro é o método padrão citado na literatura, no qual o feixe de excitação é modulado por um chopper e os sinais são medidos por amplificadores lock-in. No segundo, o condicionamento de sinais é feito por circuitos amplificadores e o processamento dos sinais é feito pulso-a-pulso. É um método que a princípio fornece melhor estatística, pois as flutuações do laser são normalizadas pulso-a-pulso, e não na média. Além disso, apresenta menor custo e torna o experimento de bombeio e prova mais simples, pois os únicos procedimentos críticos passam a ser a sobreposição dos feixes na amostra e a determinação do atraso zero entre bombeio e prova. Foi projetado e construído o circuito eletrônico de condicionamento de sinais e o software de aquisição foi desenvolvido em linguagem LabVIEW. Entretanto, o método pulso-a-pulso forneceu uma sensibilidade inadequada para o estudo de filmes poliméricos, (&Delta;T&frasl;T ~ 0,7%, limitada pelo ruído elétrico na amplificação dos pulsos detectados), em contraste com &Delta;T/T ~ 0,1% que foi alcançada pelo método sensível à fase. Desta maneira, foi usado o último método para o estudo da evolução do espectro e da dinâmica de emissão estimulada de um filme de MEH-PPV, com excitação no visível e no ultravioleta, permitindo o estudo da dinâmica de relaxação dos estados de mais alta energia. Os resultados no visível são compatíveis com os da literatura, o que demonstra a confiabilidade do aparato quanto à sensibilidade e resolução temporal e espectral. Os resultados com excitação no UV indicam que a transferência de energia de bandas mais energéticas para a banda &pi; - &pi;&lowast; (conversão interna) ocorre em aproximadamente 300 fs, confirmando as suposições da literatura quanto à relaxação energética ultrarrápida (regra de Kasha), além de sugerir a existência de bandas ainda mais energéticas do que as já conhecidas. Pretende-se futuramente determinar a eficiência de tal transferência energética, pois ela pode ser um fator limitante na eficiência de fotoluminescência em polímeros conjugados com excitação no ultravioleta. / The optoelectronics industry is currently undergoing a transition period in which inorganic materials are being replaced by organic materials, oligomers and polymers, in the fabrication of some types of devices. However, factors such as low efficiency and low lifetime prevent polymer based devices on entering the market definitely. The solution of these issues requires a thorough knowledge of the electronic structure of these materials, but despite of scientific advances, there are still points to be clarified. For example, there is no consensus on the nature of the primary optical excitations and non-radiative processes in conjugated polymers, specially with ultraviolet excitation. Such processes limit the efficiency and can influence the photochemical processes, determining the device lifetime. These phenomena occur on a femtosecond timescale and therefore, ultrafast spectroscopy is the most appropriate technique for their study. In this work, we implemented the apparatus for pump-probe ultrafast spectroscopy on thin films of conjugated polymers, which can be used with two methods of data acquisition, phase-sensitive and shot-by-shot. The first is the standard method reported in the literature in which the excitation beam is modulated by a chopper and the signals measured by lock-in amplifiers. In the second, the detector signal conditioning is done by conventional amplifier circuits, followed shot-to-shot signal processing. This method provides the best statistics, in principle, because the laser fluctuations are normalized for each pulse, instead of using the average. In addition, the apparatus has a lower cost and the experiment is simpler, having as critical procedures the alignment of the beams on the sample and the determination of zero delay, with all other procedures done via software. The electronic circuitry for signal conditioning was designed and built and data acquisition software that enables measurements with both methods was developed in the LabVIEW programming language. However, the shot-by-shot method provided an inadequate sensitivity for the study of polymeric films (&Delta;T&frasl;T ~0.7%, limited by electronic noise in the amplification of detector signals), compared with &Delta;T&frasl;T ~ 0.1%, which was achieved by the phase sensitive method, and was the goal at the beginning of the project. Thus, the latter method was used to study the evolution of the spectrum and dynamics of stimulated emission of a film of MEH-PPV, with excitation in the visible and UV, allowing the study of the dynamics of higher lying electronic states. The results in the visible are consistent with those reported in the literature, which demonstrates the performance of the apparatus with respect to sensitivity and time/spectral resolution. The results with UV excitation indicate that the energy transfer among the more energetic bands to the &pi; - &pi;* band (internal conversion) occurs in about 300 fs, confirming the assumptions of the literature on the ultrafast energy relaxation processes (Kashas rule), besides suggesting the existence of even more energetic bands than those currently known. As future work, we plan to measure the efficiency of this energy transfer process, since it may be the limiting step in determining the overall photoluminescence efficiency of conjugated polymers with ultraviolet excitation.

Espectroscopia ultrarrápida

Excitação no UV

Polímeros conjugados

Processos óticos ultrarrápidos

Técnica de bombeio e prova

Conjugated Polymers

Pump-probe technique

Ultrafast optical processes

Ultrafast spectroscopy

UV excitation

Espectroscopia resolvida no tempo aplicada ao estudo de transferência de energia em moléculas orgânicas e em nanopartículas de ouro / Time-resolved spectroscopy applied to the study of the electronic energy transfer in organic molecules and energy transfer in gold nanoparticles

Ferbonink, Guilherme Ferreira, 1985-

25 August 2018

Orientador: René Alfonso Nome Silva / Dissertação (mestrado) - Universidade Estadual de Campinas, Instituto de Química / Made available in DSpace on 2018-08-25T09:25:13Z (GMT). No. of bitstreams: 1 Ferbonink_GuilhermeFerreira_M.pdf: 3339040 bytes, checksum: ef20418e159acb6b4683d177155e28be (MD5) Previous issue date: 2014 / Resumo: Nos últimos anos, várias descobertas vêm sendo realizada sobre como características intrínsecas de um dado sistema podem afetar a transferência eletrônica de energia. Um dos objetivos desta pesquisa é estudar experimentalmente como a estrutura vibrônica pode afetar a transferência eletrônica de energia em moléculas orgânicas segundo o modelo de Förster. Utilizando um sistema molecular com sobreposição espectral sobre bandas vibrônicas bem definidas, podemos verificar experimentalmente que o abaixamento da intensidade de emissão do doador unicamente nos comprimentos de onda de absorção do receptor caracteriza transferência de energia pelo modelo emissivo. Abaixamento da intensidade integrada de emissão caracteriza transferência de energia pelo mecanismo de Förster. A taxa de transferência de energia pelo mecanismo de Förster foi mais significativa quando a sobreposição espectral ocorre nas bandas vibrônica 0-1,0-2 ao invés da banda 0-0. Na segunda parte do trabalho realizado, aplicamos a técnica de absorção transiente para o estudo de nano prismas de ouro depositados sobre dois substratos diferentes. Neste trabalho, nós descrevemos a preparação e caracterização de matrizes isoladas de nanoprismas triangulares de ouro sobre o vidro contendo uma camada de ITO por litografia de nanoesferas. O espectro de absorção linear de Au / vidro e Au / ITO / vidro exibe ressonância de plásmon de superfície em 800 nm e 870 nm, com um deslocamento para o vermelho de 70 nm associado ao índice de refração de ITO. Foram realizadas medidas de espectroscopia de uma única cor de bombeio e prova com resolução temporal de 100 fs em comprimentos de onda inferiores a ressonância, em ressonância, e acima da ressonância de plásmon de superfície para cada um destes dois sistemas. A dinâmica ultra-rápida em ambos os sistemas pode ser bem descrita com um modelo que contabiliza o espalhamento elétron-elétron, o acoplamento elétron-fônon, e oscilações acústicas no término do resfriamento da estrutura de ouro. Os resultados para as nanopartículas de ouro, para cada um dos comprimentos de onda são bem descritos como tendo índice de refração complexo com dependência do comprimento de onda, que modula os sinais de bombeio e prova medidos / Abstract: Structure-property relationships for electronic energy transfer have been investigated in recent years. One of the goals of the present research is to perform an experimental study vibronic structure effects in electronic energy transfer between small organic molecules according to Forster¿s model. We have chosen organic molecules with well-defined spectral overlap between vibronic bands, which enabled us to experimentally characterize a decrease in donor emission intensity at the acceptor absorption wavelengths thereby indicating radiative energy transfer. A decrease in the emission integrated intensity characterizes energy transfer by the Forster mechanism. Forster energy transfer rates were higher when the spectral overlap involved 0-1 and 0-2 vibronic bands rather than 0-0 band. In the second part of this work, we have employed ultrafast transient absorption spectroscopy to investigated gold nano prisms deposited over two different substrates: Au over glass (Au/glass) and Au over ITO deposited on glass (Au/ITO/glass). In the present work, we describe the preparation and characterization of these two samples employing the nanosphere lithography technique. The linear absorption spectra of Au/glass and Au/ITO/glass respectively show surface plasmon resonances at 800 nm and 870 nm, with a 70nm redshift attributed to the ITO refractive index. We have performed femtosecond one-color pump-probe measurements with 100 fs time resolution below the surface plasmon resonance, at resonance, and above the surface plasmon resonance for each of these two systems. For both systems, the ultrafast dynamics can be well described with a model that takes into account electron-electron scattering, electron-phonon coupling, phonon-phonon coupling and acoustic damping. The wavelength-dependence observed can be explained in terms of the sample frequency-dependent complex refractive index which modulates the measured pump-probe signals / Mestrado / Físico-Química / Mestre em Química

Espectroscopia resolvida no tempo

Femtossegundos

Estrutura vibrônica

Nanopartículas de ouro

Espectroscopia ultrarrápida

Time-resolved spectroscopy

Femtoseconds

Vibronic structure

Gold nanoparticles

Ultrafast spectroscopy