Časově rozlišená fluorescence systémů polymer-tenzid / Time-resolved fluorescence of system polymer-surfactant

Mondek, Jakub

January 2012

In this diploma thesis was studied time-resolved fluorescence in polymer-surfactant system. At first aggregation numbers of cationic (cetyltrimethylammonium bromide), anionic (sodium dodecylsulfate) and nonionic (Triton X-100) surfactants were studied by steady-state and time-resolved fluorescence spectroscopy. These two methods were compared. Aggregation numbers by steady-state method were always lower than aggregation numbers measured by time-resolved method. Steady-state method of determination aggregation numbers is useless for surfactants with high aggregation number and for aerated samples. Addition of hyaluronan to surfactant system was studied. There was observed change in aggregation number after addition of hyaluronan and change in percentage of dynamic quenching after addition of hyaluronan. Hyaluronan affected aggregation number of cetyltrimethylammonium bromide and Triton X-100. Hyaluronan increased percentage of dynamic quenching in cetyltrimethylammonium bromide and in Triton X-100. Pyren in sodium dodecylsulfate was quenched by sphere of action with negligible percentage of dynamic quenching and addition of hyaluronan had no effect on quenching. As next goal of this thesis, the determination of the position of fluorescence probe pyrene in cetyltrimethylammonium bromide, sodium dodecylsulfate and Triton X-100 micelles was chosen. Position of pyrene changed with charge and structure of micelles. Next was studied how percentage of dynamic quenching by iodide compounds changes with different charge of micelle. In all cases majority of dynamic quenching was calculated.

Magnetisierungsdynamik in magnetischen Dünnschichtelementen - untersucht mit zeitaufgelöster Kerrmikroskopie

Neudert, Andreas

04 December 2006

In dieser Doktorarbeit wird die Magnetisierungsdynamik von strukturierten, weichmagnetischen Einzelschichten aus Permalloy (Ni81Fe19) mittels stroboskopischer Kerrmikroskopie untersucht. Die Dicke der in unterschiedliche Formen (Kreise, Quadrate und Rechtecke) strukturierten magnetischen Schicht beträgt 50 nm bzw. 160 nm. Durch die Verwendung eines gepulsten Lasers als Beleuchtungsquelle wird eine Zeitauflösung erreicht, die unter 25 ps liegt. Parallel zu den Laserpulsen wird die Probe mit gepulsten Magnetfeldern angeregt und die Reaktion der Magnetisierung auf diese schnellen Magnetfeldänderungen wird untersucht. Diese Reaktion der Magnetisierung unterscheidet sich deutlich von einer Anregung mit quasistatischen Magnetfeldern. Durch die stroboskopische Beobachtungsweise sind nur reversible Prozesse sichtbar, irreversible Prozesse werden durch die Mittelung über mehrere Millionen Anregungs- und Beobachtungspulse nicht abgebildet. Dies wird bei der Anregung eines Vortex in einer Kreisscheibe deutlich, bei dem die Magnetisierungsrichtung im Vortexkern durch das gepulste Magnetfeld teilweise geschaltet wird. Dadurch ändert sich der Drehsinn der spiralförmigen Relaxationsbewegung des Vortex, was zu einer Überlagerung der beiden Bewegungen während der Beobachtung führt. Desweiteren wird eine Vervielfältigung von Vortex-Antivortex Paaren in Stachelwänden durch hochfrequente Felder gezeigt. Diese Vervielfältigung führt zur Erzeugung eines neuen, metastabilen Zustandes mit geringerem Stachelabstand. Mit steigender Frequenz des Feldes fällt der Stachelabstand bis auf 30 % des Ausgangswertes. Ab einer Grenzfrequenz, die durch die ferromagnetische Resonanz gegeben ist, kann die Magnetisierung dem Feld nicht mehr folgen und die Wandstruktur ist vergleichbar mit der im quasistatischen Grenzfall. Auch in dickeren Elementen wird diese Erzeugung beobachtet, wo sie zu einer irreversiblen Wandtransformation von der asymmetrischen Blochwand zur Stachelwand führt. Bei der Pulsanregung eines Landau-Domänenzustandes in einem Quadrat kommt es zur Bildung von sichelartigen Domänen an den Ecken des Quadrates. Die Entstehung dieser Domänen geschieht relativ schnell innerhalb einer Nanosekunde. Während der Relaxation der Magnetisierung lösen sich diese neu entstandenen Domänen durch Wandverschiebung wieder auf. Die Auflösung der Domänen geschieht deutlich langsamer als die Entstehung, was durch die unterschiedlichen Mechanismen, die bei der Entstehung (Magnetisierungsdrehung) und Auflösung (Wandverschiebung) der Domänen involviert sind, begründet werden kann. Außerdem kommt es zu einer inkohärenten Drehung der Magnetisierung in der Domäne mit antiparalleler Ausrichtung der Magnetisierung bezüglich des Pulsfeldes. Diese Drehung der Magnetisierung, lateral abwechselnd nach links und rechts, wird durch eine leichte Abweichung der Magnetisierung von einer perfekt homogenen Ausrichtung begünstigt.

info:eu-repo/classification/ddc/530

ddc:530

Ultrafast Dynamics in Quasi-One-Dimensional Organic Molecular Crystals: Self-Assembled Monolayers of Photochromic Molecules

Canzler, Tobias W.

26 September 2002

Der erste Teil der Arbeit beschäftigt sich mit ultraschnellen Relaxationsprozessen in quasi-eindimensionalen organischen Molekülkristallen. Als Modellsystem wird das Perylenderivat MePTCDI untersucht. Mit verschiedenen Methoden der optischen Ultrakurzzeit-Spektroskopie werden Prozesse der Exzitonen- und Phononenrelaxation in der Zeit-Domäne untersucht. Die dafür aufgebauten Experimente erreichen eine Zeitauflösung von 20 Femtosekunden. Durch optische Anregung der niedrigsten elektronischen Übergänge werden in einem organischen Molekülkristall freie Exzitonen mit Wellenvektor k=0 gebildet. Dabei werden gleichzeitig zahlreiche intramolekulare und intermolekulare Schwingungsfreiheitsgrade angeregt. Die Anregung mit fs-Laserpulsen führt zum Aufbau kohärenter Schwingungswellenpakete. Es werden sowohl hochenergetische Oszillationen intramolekularer Vibrationen beobachtet, als auch erstmalig niedrigenergetische Oszillationen, die von Gittervibrationen (Phononen) stammen. Die kohärenten Vibrationen im elektronischen Grundzustand klingen bei Raumtemperatur im Bereich einiger Pikosekunden ab. Durch die optische Anregung mit fs-Laserpulsen wird nicht nur phononische Kohärenz, sondern auch elektronische Kohärenz der optischen Übergänge induziert. Die elektronische Kohärenz klingt mit der Dephasierungszeit T2 ab. Trotz der hohen Zeitauflösung war es letztendlich nicht möglich, die Dephasierung des niedrigsten exzitonischen Übergangs zeitlich aufzulösen - sie liegt jedoch im Bereich 17fs < T2 < 52fs. Die energetische Relaxation der freien Exzitonen zu den relaxierten, emittierenden Exzitonenzuständen erfolgt mit einer Zeitkonstante von ca. 50fs. Von diesen relaxierten Zuständen erfolgt die energetische Abregung in den elektronischen Grundzustand im ns-Bereich. Im zweiten Teil der Arbeit werden Untersuchungen an selbst-assemblierten Monoschichten (SAM) photochromer Moleküle vorgestellt. Als Modellsystem dienen Azobenzen-funktionalisierte Thiole auf Gold (111). Es konnten hochgeordnete Monoschichten dieser photochromen Moleküle erzielt werden, allerdings sind die bisherigen Schichten aufgrund der dichten Packung nicht photoaktivierbar. Mit Hilfe von Raster-Mikroskopie und Infrarot-Spektroskopie werden diese ultradünnen Schichten strukturell untersucht. Es wird ein kommensurates Wachstum mit zwei Molekülen in der nahezu rechteckigen Einheitszelle beobachtet, wobei die laubbaumförmigen Moleküle nahezu senkrecht auf der Oberfläche stehen. Als weitere Methode wurde die Generation der zweiten Harmonischen (Second Harmonic Generation, SHG) angewendet. Diese Technik eröffnet prinzipiell die Möglichkeit, photostimuliertes Schalten der Schicht zeitaufgelöst zu untersuchen. / The first part of this thesis is devoted to ultrafast relaxation processes in quasi-one-dimensional organic molecular crystals. Crystalline samples of the perylene derivative MePTCDI are employed as a model system. Processes concerning the excitonic and phononic relaxation are investigated in time domain using various experimental techniques of optical ultrafast spectroscopy. The experimental setups attain a time-resolution of 20 femtoseconds. Free excitons at wavevector k=0 are formed in a molecular crystal by optical excitation of the lowest electronic transitions. Thereby, various intramolecular and intermolecular vibrational degrees of freedom are excited simultaneously. The excitation by fs-laser pulses results in the composition of coherent vibrational wave packets. Both, higher-energetic oscillations caused by intramolecular vibrations (internal phonons) and, for the first time in a quasi-one-dimensional organic system, lower-energetic modulations which are related to coherent lattice phonons (external phonons) are observed. The coherence of both types of phonons in the electronic ground state is damped at room temperature within a few ps. Besides phononic coherence, optical excitation by fs-laser pulses additionally induces electronic coherence of the optical transitions. The electronic coherence decays with the dephasing time T2. In spite of the high time-resolution, finally it was not possible to time resolve the dephasing of the lowest excitonic transition - however, we can estimated it to be in the range of 17fs < T2 < 52fs. The energetic relaxation of free excitons to the relaxed, emitting exciton states takes place with a time constant of approx. 50fs. The subsequent energetic relaxation to the electronic ground state occurs on a ns-time scale. In the second part, investigations of self-assembled monolayers (SAM) of photochromic molecules are presented. Azobenzene-functionalized thiols on gold (111) are employed as a model system. Highly ordered monolayers of these photochromic molecules could be realized. However, these layers are not photoactive because of dense packing. By use of scanning tunneling microscopy and infra-red spectroscopy the structural properties of these ultrathin layers are investigated. A commensurate growth, yielding a lattice with two molecules within the nearly rectangular unit cell is observed. The molecules, shaped like a broad-leafed tree, are found to stand nearly upright on the surface. Second harmonic generation (SHG) is applied as another experimental method. This technique allows to time resolve photo-stimulated conformational changes of the layers in principle.

info:eu-repo/classification/ddc/29

ddc:29

Making wood durable. A sustainable approachwith linseed oil / Att göra trä beständigt. Ett hållbart tillvägagångssätt med linolja

Olsson, Helena

January 2019

Linseed oil has been and is used for vast number of applications, such as in food and paint industry, and wood preservation. It is a good environmental choice, as it originates from renewable sources. Linseed oil is mainly a mixture of triglyceride of fatty acids, both saturated and mono- or polyunsaturated, which allows the oil to oxidize. The oxidation occurs via an auto-oxidation mechanism with the carbon-carbon double bonds and oxygen from the air, reacts to form a polymer. Herein, four different linseed oils (three commercial ones and one industrially available) were analyzed to obtain a better understanding of why different oils provide different protection of wooden materials. This was done by a study of the unoxidized oil, followed by an oxidation time-resolved study of oxidized oil films. The analysis was done by nuclear magnetic resonance, gas chromatography - mass spectrometry and/or inductively coupled plasma atomic emission spectroscopy. This study provided the fatty acid profile of the oils, which were similar for all oils. The unoxidized oils contained some metals ions which probably originate from additives. Aluminum, cobalt, iron, manganese, and zinc was detected in some of the oils at concentrations up to 135 mg/L, but only manganese was detected in all oils and its concentration was much higher than all other metals together. The time-resolved oxidation study had some problems with the solubility of the formed polymers. Several solvents were examined, such as dimethylsulfoxide, alkaline alcohol solutions and toluene, before chloroform-d was chosen as solvent. Though, chloroform-d was not a perfect solvent; it was capable to solve a fraction of the sample, but the fraction decreased with oxidation time. After fifteen days of oxidation, only a few percent of the sample could be dissolved, but for short oxidation times (<48 h) the majority of the samples were dissolved. The oils were analyzed after thirteen different oxidation times. Some structural changes appeared, for example loss of unsaturated protons and some oxidation products arose, such as peroxides and aldyhydes. The diffusion coefficient decreased over the first 3-4 days of oxidation, as expected when the polymerization progressed. After a week of oxidation, the diffusion coefficient increased again, this could possibly be explained by the solubility problem for the large polymer formed. Contrary, at shorter oxidation times this method probably could still be used, as the majority of the sample was dissolved. However, the solubility problem made it impossible to conclude anything about the oxidation rate at longer oxidation times and thus prevented any ranking of the oils. / Linolja har använts och används för många olika tillämpningar, till exempel i mat- och färgindustrin, samt för att bevara trä. Det är klimatmässigt ett bra val, då det kommer från en förnyelsebar källa. Linolja innehåller huvudsakligen en blandning av triglycerider av fettsyror, som både kan vara mättade, enkelomättade eller fleromättade, detta gör att linolja kan oxidera och torka. Oxidationen sker via en auto-oxidation mekanism, med kol-kol dubbelbindningarna och syre från luften som producerar till en polymer. I detta projekt undersöktes fyra olika linoljor (tre kommersiella och en industriell), för att ge en bättre förståelse till varför olika oljor ger olika bra skydd för trämaterial. Detta gjordes genom att undersöka de icke-oxiderade oljorna och sedan göra en tidsstudie på oxiderade oljefilmer. Alla dessa prover analyserades med nuclear magnetic resonance, gas chromatography - mass spectrometry and/or inductively coupled plasma atomic emission spectroscopy. Studien gav resultat på sammansättningen av fettsyror i oljorna, vilken var liknande för alla oljorna. De icke-oxiderade oljorna innehöll ett par metaller, som förmodligen kommer från additiv. Aluminium, kobolt, järn, mangan och zink hittades i några av oljorna i koncentrationer upp till 135 mg/L, men bara mangan var detekterad i alla oljorna och dess koncentration var högre än alla andra metaller tillsammans. Tidsstudien hade problem med lösligheten av proverna. Flertalet lösningsmedel undersöktes, exempelvis dimetylsulfoxid, alkaliska alkohollösningar och toluen, innan kloroform-d valdes som lösningsmedel. Däremot var kloroform-d inte ett perfekt lösningsmedel, den hade förmågan att lösa en del av proverna, men den delen minskade med oxidationstid. Efter femton dagar kunde den bara lösa ett par procent, men efter kortare oxideringstider (<48 h) gick majoriteten av proven att lösa. Oljorna analyserades vid tretton olika oxideringstider. Några strukturella förändringar uppmättes, till exempel minskade mängden dubbelbindningar, och ett par biprodukter från oxideringen detekterades, så som peroxider och aldehyder. Diffusionskonstanterna för oljorna minskade under de första 3-4 dagarna av oxidering, precis som förväntat under polymeriseringen. Efter en vecka av oxidering ökade diffusionskonstanterna igen, det kan förmodligen förklaras av löslighetsproblemen, då diffusionskonstanten är beroende av koncentrationen. Å andra sidan, vid kortare oxideringstider kan denna metod fortfarande användas, eftersom vid denna tidpunkt löste sig fortfarande majoriteten av provet. Dock, löslighetsproblemet gjorde det omöjligt att dra slutsatser kring längre oxideringstider och därmed förhindrades rangordning av oljorna.

Linseed oil

Wood preservation

Nuclear Magnetic Resonance (NMR)

Diffusion Ordered Spectroscopy (DOSY)

Time-resolved oxidation study

Linolja

Bevarande träbehandling

Nuclear Magnetic Resonance (NMR)

Diffusion Ordered Spectroscopy (DOSY)

Oxidationstidsstudie

Analytical Chemistry

Analytisk kemi

ULTRAFAST PHOTOCHEMISTRY OF POLYATOMIC MOLECULES CONTAINING LABILE HALOGEN ATOMS IN SOLUTION

Mereshchenko, Andrey S.

31 July 2013

No description available.

Physical Chemistry

Physics

Chemistry

Pump-probe

bromoform

dibromomethane

boron bromide

phosphorous(III) bromide

copper(II)

chlorocomplexes

chloride

CH2Br2

CHBr3

PBr3

BBr3

CuCl+

CuCl4

ultrafast

dynamics

femtosecond

time-resolved

strong coupling limit

Transient thermal management simulations of complete heavy-duty vehicles

Svantesson, Einar

January 2019

Transient vehicle thermal management simulations have the potential to be an important tool to ensure long component lifetimes in heavy-duty vehicles, as well as save development costs by reducing development time. Time-resolved computational fluid dynamics simulations of complete vehicles are however typically very computationally expensive, and approximation methods must be employed to keep computational costs and turn-around times at a reasonable level. In this thesis, two transient methods are used to simulate two important time-dependent scenarios for complete vehicles; hot shutdowns and long dynamic drive cycles. An approach using a time scaling between fluid solver and thermal solver is evaluated for a short drive cycle and heat soak. A quasi-transient method, utilizing limited steady-state computational fluid dynamics data repeatedly, is used for a long drive cycle. The simulation results are validated and compared with measurements from a climatic wind tunnel. The results indicate that the time-scaling approach is appropriate when boundary conditions are not changing rapidly. Heat-soak simulations show reasonable agreement between three cases with different thermal scale factors. The quasi-transient simulations suggest that complete vehicle simulations for durations of more than one hour are feasible. The quasi-transient results partly agree with measurements, although more component temperature measurements are required to fully validate the method.

Transient

Time-resolved

Vehicle thermal management

Complete vehicle

Dynamic boundary conditions

Drive cycle

Hot shutdown

Heat soak

Heavy-duty vehicles

Heavy trucks

Thermal scale factor

Quasi-transient

Computational fluid dynamics.

Mechanical Engineering

Maskinteknik

A Study of Recombination Mechanisms in Gallium Arsenide using Temperature-Dependent Time-Resolved Photoluminescence / Recombination Mechanisms in Gallium Arsenide

Gerber, Martin W

17 June 2016

Recombination mechanisms in gallium arsenide have been studied using temperature-dependent time-resolved photoluminescence-decay. New analytical methods are presented to improve the accuracy in bulk lifetime measurement, and these have been used to resolve the temperature-dependent lifetime. Fits to temperature-dependent lifetime yield measurement of the radiative-efficiency, revealing that samples grown by the Czochralski and molecular-beam-epitaxy methods are limited by radiative-recombination at 77K, with defect-mediated nonradiative-recombination becoming competitive at 300K and above. In samples grown with both doping types using molecular-beam-epitaxy, a common exponential increase in capture cross-section characterized by a high value of E_infinity=(258 +/- 1)meV was observed from the high-level injection lifetime over a wide temperature range (300-700K). This common signature was also observed from 500-600K in the hole-lifetime observed in n-type Czochralski GaAs where E_infinity=(261 +/- 7)meV was measured, which indicates that this signature parametrizes the exponential increase in hole-capture cross-section. The high E_infinity value rules out all candidate defects except for EL2, by comparison with hole-capture cross-section data previously measured by others using deep-level transient spectroscopy. / Thesis / Doctor of Philosophy (PhD)

semiconductors

photovoltaics

solar energy

radiative efficiency

time resolved photoluminescence

photoluminescence decay

gallium arsenide

GaAs

III-V

direct bandgap

lifetime

diffusion

surface recombination

trapping

deep levels

EL2

dominant defect

defect characterization

photoluminescence spectroscopy

analytical methods

defect identification

double heterostructure

MANIPULATION OF EXCITON DYNAMICS BY INTERFACIAL ENERGY/CHARGE TRANSFER IN TWO-DIMENSIONAL SEMICONDUCTORS

Dewei Sun (17468739)

29 November 2023

<p dir="ltr">In the realm of two-dimensional (2D) materials, monolayer (ML) transition metal dichalcogenides (TMDCs) have gained significant interest due to their direct bandgap transition, high carrier mobility, strong light-matter interaction, and robust spin and valley degrees of freedom, starkly contrasting their bulk counterparts. Owing to their large surface-to-volume ratio, the integration of ML TMDCs with other various 2D semiconductors and microcavities offers opportunities to study fundamental photo-physics processes at the heterointerfaces, paving the way for implementation of next-generation devices.</p><p dir="ltr">Chapter 1 provides a concise introduction to 2D materials, particularly TMDCs, and their fascinating optical and electronic properties. It examines the role of excitons in 2D materials, and the impact of energy transfer (ET) and charge transfer (CT) on exciton’s properties in TMDC through the construction of 2D van der Waals (vdW) heterostructures and coupling with optical microcavities. This chapter also delves into the potential enhancement of TMDCs’ optical properties by integrating 2D hybrid lead halide perovskites and ultra-thin three-dimensional (3D) halide perovskites with TMDCs. Furthermore, it sets the general context for light-matter interaction, another form of ET, considering both weak and strong coupling regimes.</p><p dir="ltr">Chapter 2 outlines the optical techniques employed to gather data for this work. A focus is placed on ultrafast optical techniques like transient absorption spectroscopy, which allow for direct probing and analysis of ET and CT dynamics at the heterointerface.</p><p dir="ltr">Photoinduced interfacial CT plays a critical role in the field of energy conversion involving vdW heterostructures constructed by inorganic nanostructures and organic materials. However, the control of atomic-scale stacking configurations to modulate charge separation at interfaces remains challenging. Chapter 3 aims to illustrate tunability of interfacial charge separation in a Type-II heterojunction between ML-WS₂ and an organic semiconducting molecule by rational design of relative stacking configurations using 2D perovskites as scaffoldings. This chapter investigates how different molecular stacking, face-to-face versus face-to-edge, affects CT at the heterointerface. Our findings reveal that the CT process heavily depends on the relative stacking configurations at the organic-TMDCs heterointerface, with charge separation being notably slowed down for face-to-edge configuration compared to face-to-face configuration. These investigations open new opportunities for designing efficient charge separation processes in energy conversion applications by judiciously engineering interfaces between organic and inorganic semiconductors, using 2D perovskites as scaffolds.</p><p dir="ltr">Though TMDCs’ large surface-to-volume ratios make them excellent platforms for studying interfacial properties, the presence of bulky ligands on the surface of 2D perovskite poses a challenge, impeding direct interfacial coupling in their heterostructures. Chapter 4 details the fabrication of ML-WS₂ and ultra-thin CH₃NH₃PbX₃ (MAPbX₃, X=Br, I) heterostructures with tunable energy levels, to study the dynamics of CT and ET at these hybrid interfaces. Notably, heterojunctions of WS₂ with pure MAPbBr₃ and MAPbI₃ were elucidated as Type-I and Type-II respectively, using photoluminescence (PL) and time-resolved photoluminescence (TR-PL) measurements. Transit absorption (TA) spectroscopy investigations unambiguously revealed a rapid ET facilitated by CT in the WS₂/MAPbBr₃ heterostructure, with a time constant of ~20 ps, and a predominantly CT in the WS₂/MAPbI₃ heterostructure with a time constant of ~50 femtosecond (fs). The successful interfacing of low-dimensional perovskites with an extensive array of traditional 2D materials such as TMDCs opens up possibilities for novel optoelectronic properties and applications within the field of 2D material systems. Furthermore, the ultrafast and efficient ET and CT processes hold promise for the creation of advanced energy conversion devices.</p><p dir="ltr">In the last chapter, we successfully fabricated a ML-WS₂ in conjunction with a silver (Ag) nanoparticle (NP) array. Our findings affirmed a weak light-matter coupling between ML-WS₂ and the Ag NP array, as evidenced by angle-resolved photoluminescence spectroscopy. Furthermore, an enhancement in the bright exciton emission from ML-WS₂ was observed at reduced temperatures. The analysis of PL enhancement factor at varying temperatures suggested that an upper bound of the enhancement factor for the bright exciton could reach ~51 or even higher at 7 K, given the imperfect uniformity of the electric filed generated around the NPs. This discovery carries significant implications for the manipulation of excitons in TMDCs and expands their potential applications in the field of optoelectronics.</p>

Photochemistry

transition metal dichalcogenide

perovskite

organic semiconducting molecules

ultrafast spectroscopy

photoluminescence

time-resolved photoluminescence

transient absorption spectroscopy (TAS)

Exciton Dynamics and Transport

Photochemistry of Copper Coordination Complexes / Fotokemi av kopparkoordinationskomplex

Blad, Amanda, Glisén, Helena, Ludvig, Filippa

January 2021

The United Nations have set a number of sustainability goals, Agenda 2030, in order to combat the worlds largest challenges and injustices. The energy market is one of these urgent issues which must be solved. Solar energy is expected to be the fastest growing energy source in the future energy mix. It can be a great way to provide zero emission energy and also become a key part in equality as it can provide energy to people who live off the grid today and raise quality of life all over the world. The aim of this study is to compare different ligands in a copper halide complex to conclude what structural properties of the ligand might be better suited for photoluminescent applications, and especially in solar cells. Eight ligands were chosen for the complexes depending on their level of conjugation: 4,4’-bipyridine, tri(o-tolyl)phosphine, 3,6-di-2-pyridyl-1,2,4,5-tetrazine, pyridine, pyrimidine, pyrazine, phenanthroline, and 2,2’-bipyridine. A series of analytical methods were used to compare the complexes properties; X-Ray diffraction, emission and excitation spectroscopy, time-resolved photoluminescence spectroscopy, microscopy and thermochromism. From these measurements, pyridine and pyrimidine proved to have the greatest potential for working in a solar cell. This was deduced because of the detected crystallinity, having luminescence under UV-light, forming distinct wavelength peaks during excitation and emission in the flourometer, having the longest excited state lifetime and and finally, emitting distinctive colours during thermochromism. When creating the solar cell, pyridine was chosen as ligand due to higher availability than pyrimidine. The method used in this project for making the solar cell is directly applied form a previously tested method, but which was designed for another type of electron donor. This project compared the different ways of applying the copper halide complex on to the cell. The methods used were spin-coating and SILAR for creating the copper iodide thin film and vapour diffusion and immersion to introduce the ligand. These four methods were combined systematically for all combinations. The solar cells were then put in a solar simulator where voltage, current, efficiency and fill factor was measured. The best results came form the solar cell where spin coating and immersion was used, though the overall efficiency of the created cells were low. Copper halide complexes in previous studies have been proven to be reactive with oxygen and the experiments in this project were not carried out in an inert environment. This could have had significant impact on the measurements, as reactions between the complexes and oxygen may have resulted in oxidation and thus inactivation of the complexes. Therefore, it would be interesting to conduct the syntheses again but instead in an inert environment to determine whether oxygen made a major impact on the measurements. In further studies, it would also be worthwhile to investigate how the different layers of the solar cell would have to be adapted for this particular complex to obtain higher efficiency and voltage. Also, making thin film of pyrimidine to be used in a solar cell as it showed the attributes required for a solar cell. Furthermore, it would be interesting to use derivatives of pyrimidine, such as uracil and cytosine which are abundant in nature, as they might be more sustainable choices. This is due to their inherent biodegradability and not posing a threat to either health or environment when handled.

Copper Halide Organic Complex

Time-Resolved Photoluminescence

Metal-organic Framework

Coordination Polymer

Thin Film Solar Cell

Koppar halid organiska komplex

tidsberoende fotoluminesens

metallorganiska ramverk

koordinationspolymer

tunnfilmssolcell.

Physical Chemistry

Fysikalisk kemi

Materials Chemistry

Materialkemi

Inorganic Chemistry

Oorganisk kemi

Infrared Emitting PbS Nanocrystals through Matrix Encapsulation

Liyanage, Geethika Kaushalya

03 July 2014

No description available.

Chemical Engineering

Chemistry

Condensed Matter Physics

Engineering

Experiments

Materials Science

Nanoscience

Nanotechnology

Physics

nanomaterials

Lead sulfide

colloidal quantum dots

inorganic matrix

time-resolved fluorescence

quantum yield

Infrared materials

Matrix encapsulation