Investigating the Electron Transport and Light Scattering Enhancement in Radial Core-Shell Metal-Metal Oxide Novel 3D Nanoarchitectures for Dye Sensitized Solar Cells

Sahu, Gayatri

18 May 2012

Dye-sensitized solar cells (DSSCs) have attained considerable attention during the last decade because of the potential of becoming a low cost alternative to silicon based solar cells. Electron transport is one of the prominent processes in the cell and it is further a complex process because the transport medium is a mesoporous film. The gaps in the pores are completely filled by an electrolyte with high ionic strength, resulting in electron-ion interactions. Therefore, the electron transport in these so called state-of-the-art systems has a practical limit because of the low electron diffusion coefficient (Dn) in this mesoporous film photoanode. This work focuses on the influence of the advanced core-shell nanoarchitecture geometry on electron transport and also on the influence of electron-ion interactions. In order to achieve the proposed goals, DSSCs based on ordered, highly aligned, 3D radial core-shell Au-TiO2 hybrid nanowire arrays were fabricated, using three different approaches. J-V, IPCE, and EIS characteristics were studied. The efficiency, light scattering and charge transport properties of the core-shell nanowire based devices were compared to TiO2 nanotube as well as TiO2 mesoporous film based DSSCs. The Au nanowires inside the crystalline TiO2 anatase nanoshell provided a direct conduction path from the TiO2 shell to the TCO substrate and improved transport of electrons between the TiO2 and the TCO. The optical effects were studied by IPCE measurement which demonstrated that Au-TiO2 nanowires showed an improved light harvesting efficiency, including at longer wavelengths where the sensitizer has weak absorption. The metal nanostructures could enhance the absorption in DSSCs by either scattering light enabling a longer optical path-length, localized surface plasmon resonance (LSPR) or by near-field coupling between the surface plasmon polariton (SPP) and the dye excited state. Rapid, radial electron collection is of practical significance because it should allow alternate redox shuttles that show relatively fast electron-interception dynamics to be utilized without significant sacrifice of photocurrent. A combination of improved electron transport and enhanced light harvesting capability make Au-TiO2 core-shell nanowire arrays a promising photoanode nanoarchitecture for improving photovoltaic efficiency while minimizing costs by allowing thinner devices that use less material in their construction.

Inorganic Chemistry

Materials Chemistry

Influência das interfaces TiO2/Corante, TiO2/eletrólito e rutilo/anatase sobre a eficiência de fotoconversão das células de gratzel / Role of TiO2/dye, TiO2/electrolyte and anatase/rutile interfaces on the photoconversion efficiency of gratzel cells

Guimarães, Robson Raphael

30 March 2016

Nesta tese visamos o entendimento aprofundado dos processos e mecanismos que influenciam a performance de células solares sensibilizadas por corante (DSCs), particularmente a influência das interfaces TiO2/corante, TiO2/eletrólito e rutilo/anatase, assim contribuindo para obter dispositivos eficientes. Nesse sentido, foi investigada a influência das propriedades eletrônicas do novo corante [Ru(dcbpyH2)2(tmtH2)]Cl associadas às transições de transferência de carga MLCT e LMCT sobre a eficiência de fotoinjeção e fotoconversão de energia solar nas DSCs. Por meio da aplicação das espécies isoladas (Bu4N)3[Ru(dcbpy)2(tmtH2)], (Bu4N)4[Ru(dcbpy)2(tmtH)] e (Bu4N)5[Ru(dcbpy)2(tmt)] em DSCs, foram demonstradas as contribuições de duas bandas MLCTs e uma LMCT para a fotoconversão de energia, que foram reveladas por deconvolução dos espectros de fotoação. Além disso, aquelas espécies apresentaram valores de eficiência global corrigidos pela quantidade de corante adsorvido no TiO2 maiores do que o corante N719, indicando que os novos corantes de rutênio têm potencial de aplicação como fotossensibilizadores de células solares. Também foi investigado o mecanismo do efeito sinérgico observado em misturas de rutilo e de anatase por meio do estudo das contribuições dos processos de recombinação e de difusão de elétrons nos filmes mesoporosos mistos de TiO2 sobre a performance das DSCs, em função da distribuição daqueles nanocristais em diferentes proporções, confirmadas por microscopia Raman confocal. A impedância das interfaces/junções presentes nas DSCs foi caracterizada por espectroscopia de impedância eletroquímica (EIS) para determinação de parâmetros fundamentais como capacitância química, resistência de difusão, resistências de recombinação, coeficiente de difusão, tempo de vida e comprimento de difusão dos elétrons dos filmes mistos de TiO2. As características I x V das células solares, ou seja, os parâmetros de eficiência global (η), densidade de corrente de curto-circuito (Jsc), voltagem de circuito-aberto (Voc) e fator de preenchimento (FF) foram relacionados com os parâmetros de impedância e o grau de homogeneidade das misturas de nanopartículas de rutilo e de anatase. Em particular, foi demonstrado o papel fundamental das propriedades de difusão de elétrons nos filmes mistos de TiO2 para o aumento da performance das DSCs. Os estudos de simulação dos espectros de impedância de filmes mistos não homogêneos de TiO2 comercial Aldrich mostraram que o coeficiente de difusão de elétrons desses materiais apresenta um máximo na região de 15% de rutilo e 85% anatase, coincidindo com o máximo de eficiência das DSCs de mesma composição. De fato, diferenças sutis nas contribuições da capacitância química e resistência de difusão foram responsáveis pelo aumento do coeficiente de difusão das DSCs baseadas em filmes mistos não homogêneos de TiO2. Por outro lado, quando foi aumentada a área de contato entre as nanopartículas de anatase e de rutilo, foi observado um aumento da capacitância química e tempo de vida dos elétrons nos filmes mistos homogêneos de TiO2. Estes foram atribuídos ao aumento da eficiência de transferência de elétrons entre os nanocristais de rutilo e de anatase, que diminuiram a recombinação de elétrons e promoveram a estabilização de cargas na banda de condução do TiO2. / The understanding of the detailed mechanism and processes that influence the performance of dye-sensitized solar cells (DSCs), particularly the influence of TiO2/dye, TiO2/electrolyte and rutile/anatase interfaces, thus contributing to increase the efficiency of that devices, is the main goal of this thesis. Accordingly, we investigated the influence of the electronic properties of the new dye [Ru(dcbpyH2)2(tmtH2)]Cl associated the MLCT and LMCT charge transfer transitions on the efficiency of photoinjection and solar energy photoconversion in DSCs. The species (Bu4N)3[Ru(dcbpy)2(tmtH2)], (Bu4N)4[Ru(dcbpy)2(tmtH)] and (Bu4N)5[Ru(dcbpy)2(tmt)] were isolated and used in DSCs, revealing the contributions of two MLCTs and a LMCT band for energy conversion by deconvolution of the photoaction spectra. Interestingly, these new ruthenium dyes presented overall efficiency normalized by the amount of dye adsorbed on TiO2 larger than for the N719 dye, indicating a potential for application as photosensitizers. The mechanism of the synergistic effect observed in blends of rutile and anatase was investigated studying the contributions of the recombination and electron diffusion processes in mesoporous mixed TiO2 films on the performance of DSCs, as a function of the distribution of those nanocrystals in different proportions, as confirmed by Raman microscopy (Confocal). The impedance of interfaces/junctions present in the DSCs was carefully characterized by electrochemical impedance spectroscopy (EIS) to determine key parameters such as chemical capacitance, diffusion resistance, recombination resistance, diffusion coefficient, lifetime and the electron diffusion length in mixed TiO2 films. The I x V characteristics, i.e. the overall efficiency parameter (η), density of short circuit current (Jsc), open-circuit voltage (Voc) and fill factor (FF) of solar cells were correlated with the impedance parameters and the degree of homogeneity of mixtures of rutile and anatase nanoparticles. In fact, the essential role of electron diffusion properties in the mixed TiO2 films on the performance of DSCs was demonstrated. Impedance studies of low homogeneity mixed films prepared with commercial TiO2 (Aldrich) by fitting the experimental spectra with a suitable equivalent circuit revealed that the electron diffusion coefficient of these materials exhibits a maximum at 15% rutile and 85% anatase, as expected based on the synergic effect in DSCs. In fact, subtle differences in the contributions of chemical capacitance and diffusion resistance were responsible for the increase of the electron diffusion coefficient in low homogeneity mixed TiO2 films. On the other hand, an increase in the anatase and rutile nanoparticles contact area reflected positively in the chemical capacitance and electron lifetime, as expected for an enhanced electron transfer efficiency between the rutile and anatase nanocrystals, thus decreasing the electron recombination and increasing the stability of the photoinjected charge on the TiO2 conduction band.

Anatase

Anatase

Complexo de rutênio

Dye-sensitized solar cell

Efeito sinérgico

Ruthenium complex

Rutile

Rutilo

Synergistic effect

TiO2

TiO2

Influência das interfaces TiO2/Corante, TiO2/eletrólito e rutilo/anatase sobre a eficiência de fotoconversão das células de gratzel / Role of TiO2/dye, TiO2/electrolyte and anatase/rutile interfaces on the photoconversion efficiency of gratzel cells

Robson Raphael Guimarães

30 March 2016

Nesta tese visamos o entendimento aprofundado dos processos e mecanismos que influenciam a performance de células solares sensibilizadas por corante (DSCs), particularmente a influência das interfaces TiO2/corante, TiO2/eletrólito e rutilo/anatase, assim contribuindo para obter dispositivos eficientes. Nesse sentido, foi investigada a influência das propriedades eletrônicas do novo corante [Ru(dcbpyH2)2(tmtH2)]Cl associadas às transições de transferência de carga MLCT e LMCT sobre a eficiência de fotoinjeção e fotoconversão de energia solar nas DSCs. Por meio da aplicação das espécies isoladas (Bu4N)3[Ru(dcbpy)2(tmtH2)], (Bu4N)4[Ru(dcbpy)2(tmtH)] e (Bu4N)5[Ru(dcbpy)2(tmt)] em DSCs, foram demonstradas as contribuições de duas bandas MLCTs e uma LMCT para a fotoconversão de energia, que foram reveladas por deconvolução dos espectros de fotoação. Além disso, aquelas espécies apresentaram valores de eficiência global corrigidos pela quantidade de corante adsorvido no TiO2 maiores do que o corante N719, indicando que os novos corantes de rutênio têm potencial de aplicação como fotossensibilizadores de células solares. Também foi investigado o mecanismo do efeito sinérgico observado em misturas de rutilo e de anatase por meio do estudo das contribuições dos processos de recombinação e de difusão de elétrons nos filmes mesoporosos mistos de TiO2 sobre a performance das DSCs, em função da distribuição daqueles nanocristais em diferentes proporções, confirmadas por microscopia Raman confocal. A impedância das interfaces/junções presentes nas DSCs foi caracterizada por espectroscopia de impedância eletroquímica (EIS) para determinação de parâmetros fundamentais como capacitância química, resistência de difusão, resistências de recombinação, coeficiente de difusão, tempo de vida e comprimento de difusão dos elétrons dos filmes mistos de TiO2. As características I x V das células solares, ou seja, os parâmetros de eficiência global (η), densidade de corrente de curto-circuito (Jsc), voltagem de circuito-aberto (Voc) e fator de preenchimento (FF) foram relacionados com os parâmetros de impedância e o grau de homogeneidade das misturas de nanopartículas de rutilo e de anatase. Em particular, foi demonstrado o papel fundamental das propriedades de difusão de elétrons nos filmes mistos de TiO2 para o aumento da performance das DSCs. Os estudos de simulação dos espectros de impedância de filmes mistos não homogêneos de TiO2 comercial Aldrich mostraram que o coeficiente de difusão de elétrons desses materiais apresenta um máximo na região de 15% de rutilo e 85% anatase, coincidindo com o máximo de eficiência das DSCs de mesma composição. De fato, diferenças sutis nas contribuições da capacitância química e resistência de difusão foram responsáveis pelo aumento do coeficiente de difusão das DSCs baseadas em filmes mistos não homogêneos de TiO2. Por outro lado, quando foi aumentada a área de contato entre as nanopartículas de anatase e de rutilo, foi observado um aumento da capacitância química e tempo de vida dos elétrons nos filmes mistos homogêneos de TiO2. Estes foram atribuídos ao aumento da eficiência de transferência de elétrons entre os nanocristais de rutilo e de anatase, que diminuiram a recombinação de elétrons e promoveram a estabilização de cargas na banda de condução do TiO2. / The understanding of the detailed mechanism and processes that influence the performance of dye-sensitized solar cells (DSCs), particularly the influence of TiO2/dye, TiO2/electrolyte and rutile/anatase interfaces, thus contributing to increase the efficiency of that devices, is the main goal of this thesis. Accordingly, we investigated the influence of the electronic properties of the new dye [Ru(dcbpyH2)2(tmtH2)]Cl associated the MLCT and LMCT charge transfer transitions on the efficiency of photoinjection and solar energy photoconversion in DSCs. The species (Bu4N)3[Ru(dcbpy)2(tmtH2)], (Bu4N)4[Ru(dcbpy)2(tmtH)] and (Bu4N)5[Ru(dcbpy)2(tmt)] were isolated and used in DSCs, revealing the contributions of two MLCTs and a LMCT band for energy conversion by deconvolution of the photoaction spectra. Interestingly, these new ruthenium dyes presented overall efficiency normalized by the amount of dye adsorbed on TiO2 larger than for the N719 dye, indicating a potential for application as photosensitizers. The mechanism of the synergistic effect observed in blends of rutile and anatase was investigated studying the contributions of the recombination and electron diffusion processes in mesoporous mixed TiO2 films on the performance of DSCs, as a function of the distribution of those nanocrystals in different proportions, as confirmed by Raman microscopy (Confocal). The impedance of interfaces/junctions present in the DSCs was carefully characterized by electrochemical impedance spectroscopy (EIS) to determine key parameters such as chemical capacitance, diffusion resistance, recombination resistance, diffusion coefficient, lifetime and the electron diffusion length in mixed TiO2 films. The I x V characteristics, i.e. the overall efficiency parameter (η), density of short circuit current (Jsc), open-circuit voltage (Voc) and fill factor (FF) of solar cells were correlated with the impedance parameters and the degree of homogeneity of mixtures of rutile and anatase nanoparticles. In fact, the essential role of electron diffusion properties in the mixed TiO2 films on the performance of DSCs was demonstrated. Impedance studies of low homogeneity mixed films prepared with commercial TiO2 (Aldrich) by fitting the experimental spectra with a suitable equivalent circuit revealed that the electron diffusion coefficient of these materials exhibits a maximum at 15% rutile and 85% anatase, as expected based on the synergic effect in DSCs. In fact, subtle differences in the contributions of chemical capacitance and diffusion resistance were responsible for the increase of the electron diffusion coefficient in low homogeneity mixed TiO2 films. On the other hand, an increase in the anatase and rutile nanoparticles contact area reflected positively in the chemical capacitance and electron lifetime, as expected for an enhanced electron transfer efficiency between the rutile and anatase nanocrystals, thus decreasing the electron recombination and increasing the stability of the photoinjected charge on the TiO2 conduction band.

Anatase

Complexo de rutênio

Efeito sinérgico

Rutilo

TiO2

Anatase

Dye-sensitized solar cell

Ruthenium complex

Rutile

Synergistic effect

TiO2

Efeito de alguns substituintes da 1,10-fenantrolina em corantes sensibilizadores do tipo cis-[Ru(R2-phen)(dcbH2)(NCS)2]

Carvalho, Fabrício de

January 2014

Orientador: Prof. Dr. André Sarto Polo / Dissertação (mestrado) - Universidade Federal do ABC, Programa de Pós-Graduação em Ciência & Tecnologia - Química, 2014. / O trabalho desenvolvido teve como foco sintetizar compostos tris-heterolepticos de rutenio(II), o cis-[Ru(phen)(dcbH2)(NCS)2], o cis-[Ru(Me2-phen)(dcbH2)(NCS)2] e o cis-[Ru(Ph2-phen)(dcbH2)(NCS)2]. Estes compostos foram sintetizados pela rota one-pot que forneceu rendimentos superiores a 60%. A escolha dos substituintes nas posicoes 4 e 7 da fenantrolina foram feitas com o intuito de analisar o efeito causado por um grupo retirador de eletrons (Ph - fenila) e por um grupo doador de eletrons (Me - metila). Os compostos sintetizados foram caracterizados por analise elementar, espectroscopia eletronica, espectroscopia vibracional, emissao e ressonancia magnetica nuclear de 1H. Pelo espectro vibracional constatou-se que o aumento da densidade eletronica causado pelo grupo doador de eletrons desloca o ¿Þ(CN)NCS para uma regiao de maior energia e apresenta um efeito contrario para o grupo retirador de eletrons. Com o auxilio da ressonancia magnetica nuclear de 1H foi possivel comparar os sinais dos protons H2 e verificou-se que o composto com o substituinte com o grupo doador de eletrons foi deslocado para campo alto em relacao ao composto com o substituinte com o grupo retirador de eletrons. Os grupos substituintes influenciam muito pouco nas propriedades eletronicas dos compostos sintetizados. Os espectros de emissao dos compostos apresentam bandas largas e nao estruturadas, tipicas de emissao proveniente do estado thexi 3MLCT. Os tres compostos foram utilizados como corantes sensibilizadores de celulas solares. Com este trabalho observou-se que pela escolha adequada dos grupos substituintes e possivel modular as propriedades dos corantes sensibilizadores. O desempenho fotoeletroquimico foi avaliado por testes de curvas de corrente potencial e apresentaram os seguintes resultados: cis-[Ru(phen)(dcbH2)(NCS)2]: Voc = 0,733 V, Jsc = 8,67 mA cm-2, ff = 0,61 e £b = 3,78%; cis-[Ru(Me2-phen)(dcbH2)(NCS)2]: Voc = 0,683 V, Jsc = 12,72 mA cm-2, ff = 0,55 e £b = 4,60%; cis-[Ru(Ph2-phen)(dcbH2)(NCS)2]: Voc = 0,738 V, Jsc = 13,28 mA cm-2, ff = 0,63 e £b = 6,18%. / The developed work focused on synthesizing compounds tris-heteroleptic ruthenium(II), cis-[Ru(phen)(dcbH2)(NCS)2], cis-[Ru(Me2-phen)(dcbH2)(NCS)2] and were synthesized cis-[Ru(Ph2-phen)(dcbH2)(NCS)2]. These compounds were synthesized by one-pot route which provided higher yields at 60%. The choice of the substituents at positions 4 and 7 of phenanthroline were made in order to analyze the effect caused by an electron withdrawing group (Ph - phenyl) and an electron donating group (Me - methyl). The synthesized compounds were characterized by elemental analysis, electronic spectroscopy, vibrational spectroscopy, emission and 1H nuclear magnetic resonance. For the vibrational spectrum it was found that increasing the electron density caused by the electron donating group displaces the ¿Þ(CN)NCS for a higher energy region and has an opposite effect to the electron withdrawing group. With the aid of 1H nuclear magnetic resonance was possible to compare the signals of the protons H2, and it was found that the compound of the substituent with electron donating group was shifted upfield compared to the compound with the substituent withdrawing group electrons. The substituent groups very little influence on the electronic properties of the synthesized compounds. Emission spectra of the compounds show broad and unstructured bands, typical of emission from the 3MLCT thexi state. The three compounds were used as sensitizing dyes of solar cells. With this work it was observed that with the appropriate choice of substituents is possible to modulate the properties of the dyes. The photoelectrochemical performance was evaluated by testing current and potential curves showed the following results: cis-[Ru(phen)(dcbH2)(NCS)2]: Voc = 0.733 V, Jsc = 8.67 mA cm- 2, ff = 0.61 and £b = 3.78 %; cis-[Ru(Me2-phen)(dcbH2)(NCS)2]: Voc = 0.683 V, Jsc = 12.72 mA cm-2, ff = 0.55 and £b = 4.60 %; cis-[Ru(Ph2-phen phen)(dcbH2)( NCS)2]: Voc = 0.738 V, Jsc = 13.28 mA cm-2, ff = 0.63 and ç = 6.18 % .

COMPOSTOS TRIS-HETEROLÉPTICOS

COMPLEXOS DE RUTÊNIO (II)

TRIS-HETEROLEPTIC COMPOUNDS

RUTHENIUM (II)

DYE-SENSITIZED SOLAR CELLS

SupressÃo de LuminescÃncia de Corantes CatiÃnicos por Complexo de RutÃnio e sua Potencial AplicaÃÃo em CÃlulas Solares Fotosensibilizadas. / SupressÃo de LuminescÃncia de Corantes CatiÃnicos por Complexo de RutÃnio e sua Potencial AplicaÃÃo em CÃlulas Solares Fotosensibilizadas.

Maria do Socorro de Paula Silva

25 February 2014

Conselho Nacional de Desenvolvimento CientÃfico e TecnolÃgico / Complexos de bipiridinas de rutÃnio sÃo bastante estudados na literatura por apresentarem propriedades de interesse em diversas Ãreas como estudos fotoquÃmicos e fotofÃsicos, aplicaÃÃo em sistemas biolÃgicos e como fotosensibilizadores em cÃlulas solares. No presente trabalho, os complexos do tipo cis-[Ru(bpy)(dcbH2)(L)Cl], onde L = Azul do Nilo (NB), Azul de Toluidina (TBO), 9-Aminoacridina (9AA), Azure B (AB) e Violeta de Cresila (VC) foram sintetizados e caracterizados por tÃcnicas espectroscÃpicas e eletroquÃmica para aplicaÃÃo em cÃlulas solares sensibilizadas por corante (DSCs). AlÃm destes, o complexo cis-[Ru(dcbH2)(bpy)(TCNE)Cl] (Ru-TCNE) tambÃm foi testado como sensibilizador em DSC. Estes compostos apresentaram bandas de transferÃncia de carga do tipo MLCT na regiÃo do visÃvel e potenciais redox termodinamicamente favorÃveis para as reaÃÃes de transferÃncia de carga que ocorrem no dispositivo fotoeletroquÃmico. A adsorÃÃo quÃmica dos complexos sensibilizadores na superfÃcie do TiO2 foi evidenciada pelo deslocamento das bandas de MLCT para regiÃes de menor energia quando comparadas aos espectros em soluÃÃo. Os desempenhos fotovoltaicos dos complexos como sensibilizadores em DSC foram avaliados atravÃs das curvas corrente versus potencial, obtidas em condiÃÃes padrÃo AM 1,5. As DSCs contendo os sensibilizadores Ru-TBO e Ru-AB apresentaram os menores desempenhos fotovoltaicos com eficiÃncia global de 0,02 e 0,06%, respectivamente. JÃ as cÃlulas solares sensibilizadas pelos corantes Ru-NB e Ru-VC obtiveram um rendimento de 0,11% com baixos valores de eficiÃncia de incidÃncia de conversÃo de fÃtons a corrente, IPCE. Os melhores resultados foram para as cÃlulas contendo os corantes Ru-9AA e Ru-TCNE, as quais apresentaram rendimentos de 0,54 e 2,01%, respectivamente, com valores de IPCE iguais a 10% para Ru-9AA e 48% para Ru-TCNE. Todos os complexos apresentaram eficiÃncia global de conversÃo de energia solar em elÃtrica inferiores ao complexo padrÃo N3. / Bipyridines ruthenium complexes are widely studied in the literature for presenting interesting properties in various fields such as photochemical and photophysical studies, applications in biological systems and as photosensitizers in solar cells. In this work, the complexes of the type cis-[Ru(bpy)(dcbH2)(L)Cl], where L = Nile blue (NB), Toluidine blue (TBO), 9-aminoacridine (9AA), Azure B (AB) and Cresyl Violet (VC) were synthesized and characterized by spectroscopic and electrochemical techniques for application in dye-sensitized solar cells (DSC). In addition, the complex cis-[Ru(dcbH2)(bpy)(TCNE)Cl] (Ru-TCNE) was also tested as a sensitizer DSC. These compounds showed bands of charge transfer type MLCT in the visible region and thermodynamically favorable redox potentials for the charge transfer reactions which occur in the photoelectrochemical device. The adsorption of the chemical sensitizers complexes on the surface of TiO2 was evidenced by displacement of MLCT bands to lower-energy when compared to the spectra in solution. The photovoltaic performances of the complexes as sensitizers in DSC were evaluated through current versus potential curves obtained in standard AM 1.5 conditions. The DSC sensitizers containing Ru-TBO and Ru-AB had the lowest overall efficiency with photovoltaic performances of 0.02 and 0.06%, respectively. As for the dye-sensitized solar cells by Ru-NB and Ru-VC obtained a yield of 0.11% with low efficiency values of incident conversion of photon to current, IPCE. The best results were for cells containing the dyes Ru-9AA and Ru-TCNE, with energy conversion efficiency of 0.54 and 2.01%, respectively, with IPCE values equal to 10% for Ru-9AA and 48% for Ru-TCNE moieties. All complexes showed overall efficiency of converting solar energy into electricity below the N3 complex pattern.

Complexos de rutÃnio

Corantes orgÃnicos catiÃnicos

Ruthenium complexes

Cationic organic dyes

Dye-sensitized solar cells

QUIMICA BIO-INORGANICA

Techniques and Application of Electron Spectroscopy Based on Novel X-ray Sources

Plogmaker, Stefan

January 2012

The curiosity of researchers to find novel characteristics and properties of matter constantly pushes for the development of instrumentation based on X-radiation. I present in this thesis techniques for electron spectroscopy based on developments of X-ray sources both in time structure and energy. One part describes a laser driven High-Harmonic Generation source and the application of an off-plane grating monochromator with additional beamlines and spectrometers. In initial experiments, the source is capable of producing harmonics between the 13th and 23rd of the fundamental laser 800 nm wavelength. The intensity in the 19th harmonic, after monochromatization, was measured to be above 1.2·1010 photons/second with a repetition rate of 5 kHz.  The development of a chopper system synchronized to the bunch clock of an electron storage ring is also presented. The system can be used to adjust the repetition rate of a synchrotron radiation beam to values between 10 and 120 kHz, or for the modulation of continuous sources. The application of the system to both time of flight spectroscopy and laser pump X-ray probe spectroscopy is shown. It was possible to measure triple ionization of Kr and in applied studies the valence band of a laser excited dye-sensitized solar cell interface. The combination of the latter technique with transient absorption measurements is proposed. The organic molecule maleic anhydride (MA) and its binding configuration to the three anatase TiO2 crystals (101), (100), (001) has been investigated by means of Xray Photoelectron Spectroscopy (XPS) and Near Edge X-ray Absorption Fine structure Spectroscopy (NEXAFS). The results provide information on the binding configuration to the 101 crystal. High Kinetic Energy Photoelectron Spectroscopy was used to investigate multilayers of complexes of iron, ruthenium and osmium. The benefit of hard X-rays for ex-situ prepared samples is demonstrated together with the application of resonant valence band measurements to these molecules.

High Harmonic Generation HHG

HELIOS

X-ray Beam Chopper

Dye-sensitized Solar Cell

Ultra High Vacuum UHV

Photoelectron Spectroscopy

Pump-Probe

XUV

Squaraine dyes for non-linear optics and organic electronics

Shi, Yanrong

05 May 2011

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

Μελέτη του ρυθμού έκχυσης ηλεκτρονίων σε ευαισθητοποιημένα υμένια TiO2 για χρήση σε νανοκρυσταλλικά φωτοβολταϊκά στοιχεία

Σεϊντής, Κωνσταντίνος

30 April 2014

Τα φωτοβολταϊκά στοιχεία με ευαισθητοποίηση χρωστικής (Dye Sensitized Solar Cells, DSSCs) κίνησαν το ενδιαφέρον της επιστημονικής κοινότητας ύστερα από την πρωτότυπη δημοσίευση του 1991 των Grätzel και O' Regan. Προτάθηκαν ως μία φθηνή εναλλακτική λύση σε σύγκριση με τα συμβατικά ηλιακά στοιχεία από άμορφο πυρίτιο (amorphous silicon). Οι κύριοι παράγοντες που οδήγησαν την επιστημονική κοινότητα να στραφεί προς αυτή την κατεύθυνση ήταν η ευκολία σύνθεσης των χρωστικών με σχετικά απλές χημικές διαδικασίες και η λειτουργία των νέων αυτών φωτοβολταϊκών στοιχείων υπό συνθήκες διάχυτου φωτός. Γενικά, ένα τέτοιο φωτοβολταϊκό στοιχείο αποτελείται από μία φωτοάνοδο (photoanode), ένα πορώδες υπόστρωμα από ημιαγώγιμο οξείδιο μετάλλου (metal oxide semiconducting film), μία χρωστική που χρησιμοποιείται ως φωτοευαισθητοποιητής (sensitizer), έναν ηλεκτρολύτη (electrolyte) και ένα αντιηλεκτρόδιο (counter electrode), το οποίο, συνήθως, επικαλύπτεται με ένα λεπτό στρώμα από πλατίνα (Pt). Η κύρια διεργασία που λαμβάνει μέρος σε ένα DSSC, μετά από την απορρόφηση φωτός, είναι μία διεπιφανειακή μεταφορά φορτίου (interfacial electron transfer IET) από την ηλεκτρονιακά διεγερμένη στάθμη της χρωστικής προς τη ζώνη αγωγιμότητας του ημιαγωγού. Η χρονική της διάρκεια είναι της τάξεως των μερικών εκατοντάδων fs και κατατάσσεται στα υπερταχέα φαινόμενα. Ο όρος που έχει επικρατήσει, για τη διεργασία αυτή στα DSSCs, είναι έκχυση ηλεκτρονίων (electron injection) και χρησιμοποιείται στην παρούσα διπλωματική εργασία. Η τεχνική της φασματοσκοπίας φθορισμού χρονικής ανάλυσης με παλμούς διάρκειας μερικών δεκάδων fs, αποτελεί μία από τις πιο αξιόπιστες και άμεσες τεχνικές για την καλύτερη δυνατή καταγραφή υπερταχέων φαινομένων, όπως η έκχυση ηλεκτρονίων. Σκοπός της παρούσας διπλωματικής εργασίας είναι η μελέτη της έκχυσης ηλεκτρονίων με τη χρήση δύο νέων οργανικών χρωστικών, της μορφής D-π-A, ως φωτοευαισθητοποιητές σε DSSCs με την τεχνική αυτή.Στο πρώτο κεφάλαιο πραγματοποιείται μία γενική επισκόπηση των βασικών αρχών που διέπουν τα φωτοβολταϊκά στοιχεία με ευαισθητοποίηση χρωστικής. Αρχικά, γίνεται αναφορά στα μέρη που αποτελούν ένα τέτοιο φωτοβολταϊκό στοιχείο και ακολούθως στα υλικά και στις διεργασίες οι οποίες συμμετέχουν σε ένα ολοκληρωμένο DSSC.Στο δεύτερο κεφάλαιο επιχειρείται, στο πρώτο σκέλος, μία γενική ανασκόπηση της θεωρίας του Markus για τη μεταφορά των ηλεκτρονίων (Markus Theory). Έπειτα, πραγματοποιείται μία αναλυτική επισκόπηση της δυναμικής και κινηματικής των διεργασιών που συντελούνται στα DSSCs. Συνεχίζοντας στο τρίτο κεφάλαιο, παρουσιάζονται πληροφορίες σχετικές με τα υποστρώματα και τις χρωστικές που χρησιμοποιούνται στα DSSCs. Το κεφάλαιο επικεντρώνεται στην περιγραφή των υποστρωμάτων TiO2 και ΖnO, τα οποία αποτελούν τα κύρια υποστρώματα που χρησιμοποιούνται στα DSSCs. Στο δεύτερο σκέλος του κεφαλαίου, πραγματοποιείται αναφορά στις ιδιότητες που οφείλουν να πληρούν οι χρωστικές, για τη χρήση τους στα DSSCs, καθώς και εκτενής ανασκόπηση των χρωστικών, οι οποίες έχουν χρησιμοποιηθεί, μέχρι σήμερα, ως φωτοευαισθητοποιητές. Στο τέταρτο κεφάλαιο παρουσιάζονται οι μηχανισμοί που συμμετέχουν κατά την αποδιέγερση ενός οργανικού μορίου και οι χρονικές κλίμακες, που αυτοί εμφανίζονται (διάγραμμα Jablonski). Επίσης, γίνεται αναφορά στις πληροφορίες που εξάγονται από τα φάσματα σταθερής κατάστασης (steady state spectra) και χρονικής ανάλυσης (time-resolved spectra), καθώς και η μεταξύ τους σύγκριση. Στο πέμπτο κεφάλαιο πραγματοποιείται μία αναλυτική περιγραφή της πειραματικής διάταξης, η οποία χρησιμοποιήθηκε για την εξαγωγή των πειραματικών δεδομένων. Τέλος, στα τελευταία δύο κεφάλαια (πέμπτο και έκτο) περιγράφεται, στο πρώτο, ο φωτοφυσικός χαρακτηρισμός των δύο νέων οργανικών χρωστικών, ΜΖ-173 και ΜΖ-175, της δομής D-π-Α, σε διάλυμα THF και σε στερεό υπόστρωμα TiO2 αντίστοιχα, το οποίο χρησιμοποιήθηκε ως το υπόστρωμα προσρόφησης των χρωστικών. Ακολούθως, μελετήθηκε η δυναμική και η απόδοση της έκχυσης των ηλεκτρονίων από τις χρωστικές αυτές προς το ημιαγώγιμο υπόστρωμα TiO2, με χρήση της τεχνικής της φασματοσκοπίας χρονικής ανάλυσης φθορισμού με παλμούς διάρκειας μερικών δεκάδων fs (femtosecond time resolved fluorescence spectroscopy). Ως δείγμα αναφοράς, για την εύρεση της απόδοσης της έκχυσης των ηλεκτρονίων στη ζώνη αγωγιμότητας του ημιαγωγού, χρησιμοποιήθηκε νανοκρυσταλλικό υπόστρωμα Al2O3. Τέλος, πραγματοποιήθηκε η μελέτη της δυναμικής της έκχυσης των ηλεκτρονίων με τη χρήση του μορίου CDCA, ως συνπροσροφητή στην επιφάνεια των υποστρωμάτων TiO2 και Al2O3, μαζί με χρωστική ΜΖ-173, σε διάφορες συγκεντρώσεις. Αυτή η μελέτη έγινε με σκοπό τη μείωση της συσσωμάτωσης των μορίων της χρωστικής, αφού το μόριο CDCA έχει την ιδιότητα, λόγω της δομής του, να κρατά σε απόσταση τα μόρια της χρωστικής. / Dye-sensitized solar cells (DSSCs) have attracted great scientific interest after the first demonstration of Grätzel and O’Regan in 1991. They were proposed as low cost alternatives to the conventional amorphous silicon solar cells. The key factors which led the scientific community to this direction are the simplicity of their fabrication procedures with mild chemical processes and their operation under ambient conditions of diffused light. Generally, a DSSC consists of a photoanode, a nanostructured metal oxide semiconducting film, a dye sensitizer, an electrolyte and a counter electrode which is usually coated with Pt. The fundamental process that takes place in a DSSC, after the absorption of a photon by the dye, is an interfacial electron transfer (IET) from the dye’s electronically excited state to the semiconductor’s conduction band (CB), taking place within a few hundred femtoseconds. The term which is generally used for this process in DSSCs is electron injection. Ultrafast fluorescence upconversion spectroscopy is one of the most precise and direct techniques for the study and interpretation of such phenomena. The main subject of this master thesis is the presentation of two novel synthesized organic dyes with D-π-A structure and their study as photosensitizers for DSSCs. It is focused on the photophycical properties of these two dyes in solution and on titanium dioxide (TiO2) substrate, which is used as the metal oxide semiconducting film, and especially on the dynamics of electron injection process from the dye’s excited state to the conduction band of the TiO2 with the aforementioned technique. Finally, the electron injection dynamics of one of dyes with coadsorption of co-adsorbers also investigated. This type of molecules can decrease the amount of aggregates penetrating among the dye molecules but on the same time they cause a decrease of the total amount of the adsorbed dye molecules.

Έκχυση ηλεκτρονίων

621.312 44

Dye sensitized solar cells

DSSCs

Time resolved fluorescence spectroscopy

Electron injection

Co-adsorption

Φασματοσκοπικός χαρακτηρισμός ευαισθητοποιημένων φωτοηλεκτροχημικών κυψελίδων / Spectroscopic characterization of dye-sensitized photoelectrochemical solar cells

Στεργιόπουλος, Θωμάς

10 May 2007

Τα συστατικά μιας ευαισθητοποιημένης φωτοηλεκτροχημικής ηλιακής κυψελίδας μελετήθηκαν ξεχωριστά: ημιαγωγός, χρωστική και ηλεκτρολύτης. Παρασκευάστηκε και χαρακτηρίστηκε ένας στερεός ηλεκτρολύτης με βάση το υψηλού μοριακού βάρους πολυαιθυλενοξείδιο και νανοδομημένη τιτάνια. Ο ηλεκτρολύτης αυτός έφτασε σε ολικές αποδόσεις μετατροπής της ηλιακής ενέργειας σε ηλεκτρική της τάξεως του 4,55%, μία από τις μεγαλύτερες τιμές στη βιβλιογραφία. Χρήση άλλων ημιαγωγών πέρα του διοξειδίου του τιτανίου, όπως το οξείδιο του κασσιτέρου, δεν επέφερε αύξηση της παραπάνω απόδοσης. Νέα σύμπλοκα δισθενούς ρουθηνίου με διαφορετικούς πυριδινικούς υποκαταστάτες χρησιμοποιήθηκαν επίσης ως χρωστικές με αποδόσεις που έφτασαν μόλις το 1.74%. Επίσης, έγινε χρήση της φασματοσκοπίας micro-Raman για να θεμελιωθούν αρχικά συνθήκες συντονισμού και να μελετηθεί η χημειορρόφηση της χρωστικής στον ημιαγωγό. Τέλος μελετήθηκαν οι αλληλεπιδράσεις του οξειδοαναγωγικού ζεύγους με τη χρωστική κατά τη λειτουργία της κυψελίδας. / Τhe components of a dye-sensitized solar cell were thoroughly studied:semiconductor, dye and electrolyte. A novel electrolyte based on high molecular weight polyethylene oxide polymer filled with titania nanoparticles was prepared and characterized. The use of this electrolyte led to significantly high overall efficiencies (solar to electrical power) up to 4.55%, a value that is still one of the highest in literature. The use of different than titania conducting substrates, like tin oxide, did not improve the above efficiencies. Novel ruthenium(II) complexes with diver pyridine ligands were used leading to efficiencies up to only 1.74%. Micro-Raman spectrocopy was also used in order to establish resonance conditions to detect the dye chemisorption on the semiconductor substrate. Finally, the redox couple-dye interactions were thorouglh studied during the cell operation.

Στερεός ηλεκτρολύτης

Φασματοσκοπία Raman

621.312 44

Nanostructured semiconductor

Solid-state electrolyte

Raman spectroscopy

Ultrafast, Non-Equilibrium Electron Transfer Reactions of Molecular Complexes in Solution

Petersson, Jonas

January 2014

Photoinduced electron transfer is a fundamentally interesting process; it occurs everywhere in the natural world. Studies on electron transfer shed light on questions about the interaction between molecules and how the dynamics of these can be utilized to steer the electron transfer processes to achieve a desired goal. The goal may be to get electrons to the electrode of a solar cell, or to make the electrons form an energy rich fuel such as hydrogen, and it may also be an input or output for molecular switches. The importance of electron transfer reactions will be highlighted in this thesis, however, the main motivation is to gain a better understanding of the fundamental processes that affect the rate and direction of the electron transfer. A study of photoinduced electron transfer (ET) in a series of metallophorphyrin/bipyridinium complexes in aqueous solution provided fresh insight concerning the intimate relationship between vibrational relaxation and electron transfer. The forward electron transfer from porphyrin to bipyridinium as well as the following back electron transfer to the ground state could be observed by femtosecond transient absorption spectroscopy. Both the reactant and the product states of the ET processes were vibrationally unrelaxed, in contrary to what is assumed for most expressions of the ET rates. This could be understood from the observation of unrelaxed ground states. The excess energy given by the initial excitation of the porphyrin does not relax completely during the two steps of electron transfer. This is an unusual observation, not reported in the literature prior the studies presented in this thesis. This study also gave the first clear evidence of electronically excited radical pairs formed as products of intramolecular electron transfer. Signs of electronically excited radical pairs were seen in transient spectra, and were further verified by the observation that the rates followed a Marcus normal region behavior for all excitation wavelengths, despite the relatively large excess energy of the second excited state. This thesis also concerns electron transfer in solar cell dyes and mixed valence complexes. In the ruthenium polypyridyl complex Ru(dcb)2(NCS)2, where dcb = 4,4’-dicarboxy-2,2’-bipyridine, inter-ligand electron transfer (ILET) in the 3MLCT state was followed by means of femtosecond transient absorption anisotropy that was probed in the mid-IR region. Unexpectedly, ILET was not observed because electron density was localized on the same bpy during the time-window allowed by the rotational lifetime.

electron transfer

laser

spectroscopy

transient absorption

anisortopy

inter ligand electron transfer

dye sensitized solar cell

DSSC

vibrational relaxation

ultrafast dynamics

fs spectroscopy