Topics in the Theory of Josephson Arrays and Disordered Magnetic Systems

Porter, Christopher Douglas

20 October 2011

No description available.

Physics

Josephson junctions

Josephson array

weak links

SQUID

SQIF

charge transfer ferromagnetism

graphene

adatom

Effects of Charge-Transfer Excitons on the Photophysics of Organic Semiconductors

Hestand, Nicholas James

January 2017

The field of organic electronics has received considerable attention over the past several years due to the promise of novel electronic materials that are cheap, flexible and light weight. While some devices based on organic materials have already emerged on the market (e.g. organic light emitting diodes), a deeper understanding of the excited states within the condensed phase is necessary both to improve current commercial products and to develop new materials for applications that are currently in the commercial pipeline (e.g. organic photovoltaics, wearable displays, and field effect transistors). To this end, a model for pi-conjugated molecular aggregates and crystals is developed and analyzed. The model considers two types of electronic excitations, namely Frenkel and charge-transfer excitons, both of which play a prominent role in determining the nature of the excited states within tightly-packed organic systems. The former consist of an electron-hole pair bound to the same molecule while in the later the electron and hole are located on different molecules. The model also considers the important nuclear reorganization that occurs when the system switches between electronic states. This is achieved using a Holstein-style Hamiltonian that includes linear vibronic coupling of the electronic states to the nuclear motion associated with the high frequency vinyl-stretching and ring-breathing modes. Analysis of the model reveals spectroscopic signatures of charge-transfer mediated J- and H-aggregation in systems where the photophysical properties are determined primarily by charge-transfer interactions. Importantly, such signatures are found to be sensitive to the relative phase of the intermolecular electron and hole transfer integrals, and the relative energy of the Frenkel and charge-transfer states. When the charge-transfer integrals are in phase and the energy of the charge-transfer state is higher than the Frenkel state, the system exhibits J-aggregate characteristics including a positive band curvature, a red shifted main absorption peak, and an increase in the ratio of the first two vibronic peaks relative to the monomer. On the other hand, when the charge-transfer integrals are out of phase and the energy of the charge-transfer state is higher than the Frenkel state, the system exhibits H-aggregate characteristics including a negative band curvature, a blue shifted main absorption peak, and a decrease in the ratio of the first two vibronic peaks relative to the monomer. Notably, these signatures are consistent with those exhibited by Coulombically coupled J- and H-aggregates. Additional signatures of charge-transfer J- and H-aggregation are also discovered, the most notable of which is the appearance of a second absorption band when the charge-transfer integrals are in phase and the charge-transfer and Frenkel excitons are near resonance. In such instances, the peak-to-peak spacing is found to be proportional to the sum of the electron and hole transfer integrals. Further analysis of the charge-transfer interactions within the context of an effective Frenkel exciton coupling reveals that the charge-transfer interactions interfere directly with the intermolecular Coulombic coupling. The interference can be either constructive or destructive resulting in either enhanced or suppressed J- or H- aggregate behavior relative to what is expected based on Coulombic coupling alone. Such interferences result in four new aggregate types, namely HH-, HJ-, JH-, and JJ-aggregates, where the first letter indicates the nature of the Coulombic coupling and the second indicates the nature of the charge-transfer coupling. Vibronic signatures of such aggregates are developed and provide a means by which to rapidly screen materials for certain electronic characteristics. Notably, a large total (Coulombic plus charge-transfer) exciton coupling is associated with an absorption spectrum in which the ratio of the first two vibronic peaks deviates significantly from that of the unaggregated monomer. Hence, strongly coupled, high exciton mobility aggregates can be readily distinguished from low mobility aggregates by the ratio of their first two vibronic peaks. Analysis of the spatial dependence of the intermolecular interactions reveals that all four aggregate types (HH-, HJ-, JH-, JJ-) can be achieved by enforcing the appropriate crystalline packing arrangement. Such tunability is possible due of the different length scales over which the natures of the two coupling sources interconvert from J-like to H-like; whereas the nature of the Coulombic coupling is known to be sensitive to displacements on the order of half the molecular length, the nature of the charge-transfer mediated exciton coupling is sensitive to geometric displacements of approximately a carbon-carbon bond length. It is proposed that such sensitivity should allow for fine tuning of the total excitonic coupling via modifications in the packing structure, as determined, for example, by the side chains. Several examples of the different aggregate types are provided throughout this dissertation as the model is used to probe the excited state character of several relevant conjugated organic systems. Such examples include pentacene and 7,8,15,16-tetraazaterrylene (TAT) along with several derivatives from the perylene family. / Chemistry

Chemistry

Physics

Quantum Physics

Absorption

Charge-transfer Exciton

Frenkel Exciton

H-aggregates

J-aggregates

Photophysics

Active Control of Surface Plasmons in MXenes for Advanced Optoelectronics

El Demellawi, Jehad K.

18 November 2020

MXenes, a new class of two-dimensional (2D) materials, have recently demonstrated impressive optoelectronic properties associated with its ultrathin layered structure. Particularly, Ti3C2Tx, the most studied MXene by far, was shown to exhibit intense surface plasmons (SPs), i.e. collective oscillations of free charge carriers, when excited by electromagnetic waves. However, due to the lack of information about the spatial and energy variation of those SPs over individual MXene flakes, the potential use of MXenes in photonics and plasmonics is still marginally explored. Hence, the main objective of this dissertation is to shed the light upon the plasmonic behavior of MXenes at the nanoscale and extend their use beyond their typical electrochemical applications. To fulfill our objective, we first elucidated the underlying characteristics governing the plasmonic behavior of MXenes. Then, we revealed the existence of various tunable SP modes supported by different MXenes, i.e. Ti3C2Tx and Mo2CTx, and investigated their energy and spatial distribution over individual flakes. Further, we fabricated an array of MXene-based flexible photodetectors that only operate at the resonant frequency of the SPs supported by MXenes. We also unveiled the existence of tunable SPs supported by another 2D nanomaterial (i.e. MoO2) and juxtaposed its plasmonic behavior with that of MXenes, to underline the uniqueness of the latter. Noteworthy, as in the case of MXenes, this was the first progress made on studying specific SP modes supported by MoO2 nanostructures. In this part of the dissertation, we were able to identify and tailor multipolar SPs supported by MoO2 and illustrate their dependence on their bulk band structure. In the end, we show that, on the contrary, SPs in MXenes are mainly controlled by the surface band structure. To confirm this, we selectively altered the subsurface band structure of Ti3C2Tx and modulated its work function (from 4.37 to 4.81 eV) via charge transfer doping. Interestingly, thanks to the unchanged surface stoichiometry of Ti3C2Tx, the plasmonic behavior of Ti3C2Tx was not affected by its largely tuned electronic structure. Notably, the ability to attain MXenes with tunable work functions, yet without disrupting their plasmonic behavior, is appealing to many application fields.

MXenes

Surface Plasmons

Plasmonic Photodetection

Charge Transfer Doping

Ultrafast Plasmon Dynamics

Tunable Plasmonic Behavior

Development of ab initio models for lipid embedded photo-active complexes

Hino, Alexander T.

16 July 2024

Numerous pigment protein complexes exist in natural systems to harvest light energy such as photosystem II and Nanosalina xenorhodopsin. However, the mechanisms of these lipid embedded photo-active complexes have yet to be fully understood. Photosystem II is of interest due to being a compact complex which can perform the three initial key steps of photosynthesis: absorb light, transfer the excitation from the antennae to reaction center, and perform efficient charge separation. Despite considerable theoretical and experimental effort the exact mechanism of this process remains uncertain. Nanosalina xenorhodopsin is a more recently discovered inwards proton pump with minimal studies into the inwards proton pumping mechanism. Nanosalina xenorhodopsin is of interest as it contrasts with other known and well studied rhodopsins which serve as outwards proton pumps, moving H+ ions out of a cell. In this work, we use the Hamiltonian ensemble method to construct the first fully ab initio computational models of these systems which will be used to determine the mechanisms of these systems. To construct these models we first investigated the effect of the modeled surrounding membrane and simulated temperature. The effect of the extended modeled environment on calculated results is often overlooked but important for the construction of an accurate ab initio model. Our models showed that both membrane composition and temperature result in significant changes in the behavior of the extended membrane system, relative excitation energies of chromophores, and energy dynamics of a pigment protein complex. The absolute excitation energies of chromophores, absorption spectra, and linear dichroism spectra were comparatively insensitive to changes in the modeled environment. With the effect of the environment established, we present a preliminary method to extend our photosystem II model to include charge transfer states, and a preliminary model of Nanosalina xenorhodopsin which can determine the photocycle states through validation of calculated spectra against experimental results.

Computational chemistry

Charge transfer

Computational spectroscopy

Electronic structure

Energy transfer

Light harvesting

Photosystem II

Creation of ternary multicomponent crystals by exploitation of charge-transfer interactions

Seaton, Colin C., Blagden, Nicholas, Munshi, Tasnim, Scowen, Ian J.

January 2013

No / Four new ternary crystalline molecular complexes have been synthesised from a common 3,5-dinitrobenzoic acid (3,5-dnda) and 4,4'-bipyridine (bipy) pairing with a series of amino-substituted aromatic compounds (4-aminobenzoic acid (4-aba), 4-(N,N-dimethylamino)benzoic acid (4-dmaba), 4-aminosalicylic acid (4-asa) and sulfanilamide (saa)). The ternary crystals were created through the application of complementary charge transfer and hydrogen-bonding interactions. For these systems a dimer was created through a charge-transfer interaction between two of the components, while hydrogen bonding between the third molecule and this dimer completed the construction of the ternary co-crystal. All resulting structures display the same acidpyridine interaction between 3,5-dnba and bipy. However, changing the third component causes the proton of this bond to shift from neutral OHN to a salt form, O(-) HN(+) , as the nature of the group hydrogen bonding to the carboxylic acid was changed. This highlights the role of the crystal environment on the level of proton transfer and the utility of ternary systems for the study of this process.

REF 2014

Charge transfer

Crystal engineering

Hydrogen bonds

multicomponent crystals

X-ray diffraction

Correlation of Structure and Magnetic Properties in Charge-Transfer Salt Molecular Magnets Composed of Decamethylmetallocene Electron Donors and Organic Electron Acceptors

Tyree, William Stuart

05 September 2005

Di-n-propyl dicyanofumarate (DnPrDCF) and di-isopropyl dicyanofumarate (DiPrDCF) have been used as one-electron acceptors in the synthesis of charge-transfer salt magnets with decamethylmetallocenes, MCp*2 (M = Mn, Cr). Salts of each acceptor with each metallocene have been characterized and the structures of the chromium analogues have been solved. The two acceptors are structurally similar to dimethyl dicyanofumarate (DMeDCF) and diethyl dicyanofumarate (DEtDCF), which have been previously studied and found to form charge-transfer salt magnets with the aforementioned decamethylmetallocenes. A typical structural motif is present in these types of charge-transfer salts which allows for the comparison of magnetic properties based on the length or size of the alkyl group of the dialkyl dicyanofumarate. Some trends were established based on the magnetic properties of the homologous series including ordering temperature/bulkiness of the alkyl group and intrastack distances/theta values. Correlation of magnetic and structural properties may give some insight into "through-space" magnetic coupling, of which little is understood. / Master of Science

metallocene-based magnets

charge-transfer salt magnets

molecular magnets

through-space coupling

Substituent-Dependent Optical Responses of Pillar[n]arenes / 置換基に依存した光学応答を示すピラー[n]アレーン

Wada, Keisuke

25 March 2024

京都大学 / 新制・課程博士 / 博士(工学) / 甲第25312号 / 工博第5271号 / 京都大学大学院工学研究科合成・生物化学専攻 / (主査)教授 生越 友樹, 教授 杉野目 道紀, 教授 松田 建児 / 学位規則第4条第1項該当 / Doctor of Philosophy (Engineering) / Kyoto University / DGAM

Pillar[n]arene

Host?guest interaction

Optical Response

Planar chirality

Charge-transfer complex

500

Electronic excited states in quasi- one- dimensional organic solids with strong coupling of Frenkel and charge-transfer excitons / Anregte elektronische Zustände in quasi-eindimensionalen organischen Festkörpern mit starker Kopplung zwischen Frenkel und Charge-Transfer Exzitonen

Schmidt, Karin

26 February 2003

This work offers a concept to predict and comprehend the electronic excited states in regular aggregates formed of quasi-one-dimensional organic materials. The tight face-to-face stacking of the molecules justifies the idealization of the crystals and clusters as weakly interacting stacks with leading effects taking place within the columnar sub-structures. Thus, the concept of the small radius exciton theory in linear molecular chains was adopted to examine the excitonic states. The excited states are composed of molecular excitations and nearest neighbor charge transfer (CT) excitations. We analyzed the structure and properties of the excited states which result from the coupling of Frenkel and CT excitons of arbitrary strength in finite chains with idealized free ends. With the help of a partially analytical approach to determine the excitonic states of mixed Frenkel CT character by introducing a complex wave vector, two main types of states can be distinguished. The majority of states are bulk states with purely imaginary wavevector. The dispersion relation of these state matches exactly the dispersion relation known from the infinite chain. The internal structure of the excitons in infinite chains is directly transferred to the bulk states in finite chains. TAMM-like surface states belong to the second class of states. Owing to the damping mediated by a a non-vanishing real part of the wavevector, the wave function of the surface states is localized at the outermost molecules. The corresponding decay length is exclusively determined by the parameterization of the coupling and is independent of the system size. It can therefore be assigned as a characteristic quantum length which plays a vital role for the understanding of system-dependent behavior of the states. The number and type of surface states occurring is predicted for any arbitrary coupling situation. The different nature of bulk and surface states leads to distinct quantum confinement effects. Two regimes are distinguished. The first regime, the case of weak confinement, is realized if the chain length is larger than the intrinsic length. Both kinds of states arrange with the system size according to their nature. Derived from the excitonic states of the infinite chain, the bulk states preserve their quasi-particle character in these large systems. Considered as a quasi-particle confined in box, they change their energy with the system size according to the particle-in-a-box picture. The surface states do not react to a change of the chain length at all, since effectively only the outermost molecules contribute to the wavefunction. The second regime holds if the states are strongly confined, i.e., the system is smaller than the intrinsic length. Both types of states give up their typical behavior and adopt similar properties. / Diese Arbeit unterbreitet ein Konzept, um elektronische Anregungszustände in Aggregaten quasi-eindimensionaler organischer Materialien vorherzusagen und zu verstehen. Die dichte Packung der Moleküle rechtfertigt die Idealisierung der Kristalle bzw. Cluster als schwach wechselwirkende Stapel, wobei die führenden Effekte innerhalb der Molekülstapel zu erwarten sind. Zur Beschreibung der exzitonischen Zustände wurde das Konzept der 'small radius'-Exzitonen in linearen Molekülketten angewandt. Die elektronischen Zustände sind dabei aus molekularen (Frenkel) und nächsten Nachbarn 'charge-transfer' (CT) Anregungen zusammengesetzt. Die Struktur und Eigenschaften der Zustände wurden für beliebige Kopplungsstärken zwischen Frenkel- und CT Anregungen in Ketten mit idealisierten freien Enden für beliebiger Längen analysiert. Der entwickelte, überwiegend analytische Zugang, welcher auf der Einführung eines komplexen Wellenvektors beruht, ermöglicht die Unterscheidung zweier grundsätzlicher Zustandstypen. Die Mehrheit der Zustände sind Volumenzustände mit rein imaginärem Wellenvektor. Die zugehörige Dispersionsrelation entspricht exakt der Dispersionsrelation der unendlichen Kette mit äquivalenten Kopplungsverhältnissen. Die interne Struktur der Exzitonen der unendlichen Kette wird auf die Volumenzustände der endlichen Kette direkt übertragen. Der zweite grundlegende Zustandstyp umfaßt Tamm-artige Oberflächenzustände. Aufgrund der durch einen nichtverschwindenden reellen Anteil des Wellenvektors hervorgerufenen Dämpfung sind die Wellenfunktionen der Oberflächenzustände an den Randmolekülen lokalisiert. Die entsprechende Dämpfungslänge ist ausschließlich durch die Parametrisierung der Kopplungen bestimmt und ist somit unabhängig von der Kettenlänge. Sie kann daher als intrinische Quantenlänge interpretiert werden, welche von essentieller Bedeutung für das Verständnis systemgrößenabhängigen Verhaltens ist. Sowohl die Anzahl als auch die Art der Oberflächenzustände kann für jede Kopplungssituation vorhergesagt werden. Die unterschiedliche Natur der Volumen- und Oberflächenzustände führt auf ausgeprägte 'Quantum confinement' Effekte. Zwei Regime sind zu unterscheiden. Im Falle des ersten Regimes, dem schwachen 'Confinement', ist die Kettenlänge größer als die intrinsische Länge. Beide Zustandarten reagieren auf eine Veränderung der Kettenlänge gemäß ihrer Natur. Aufgrund ihrer Verwandschaft mit den Bandzuständen der unendlichen Kette bewahren die Volumenzustände ihren Quasiteilchen-Charakter. Aufgefaßt als Quasiteilchen, erfahren sie in endlichen Systemen eine energetische Verschiebung gemäß dem Potentialtopf-Modell. Oberflächenzustände zeigen keine Reaktion auf veränderte Kettenlängen, da effektiv nur die Randmoleküle zur Wellenfunktion beitragen. Es findet ein Übergang zum zweiten Regime (starkes 'Confinement') statt, sobald die Kettenlänge kleiner als intrinsische Quantenlänge wird. Beide Zustandsarten geben ihr typisches Verhalten auf und werden mit abnehmender Kettenlänge zunehmend ähnlicher.

Aggregat

Charge-Transfer

Exzitonen

Frenkel

Oberflächenzustand

Quantum Confinement

endlich

organisch

quasi-eindimensional

Frenkel

aggregate

charge transfer

exciton

finite

organic

quantum confinement

surface state

ddc:29

rvk:UP 3200

Angeregter Zustand

Ladungstransfer

Niederdimensionaler Halbleiter

Organischer Halbleiter

Organischer Kristall

Starke Kopplung

Functionalized Layered Double Hydroxides and Gold Nanorods

Dutta, Dipak

January 2011

The reversible and topotactic insertion of guest species within layered host lattices, known as intercalation is a widely studied phenomena. The Layered Double Hydroxides (LDHs) or Anionic Alloys are important class of layered solids with its own distinct ion-exchange host-Guest Chemistry. The LDH structure may be derived from that of Brucite, Mg(OH)2, by random isomorphous substitution of Mg2+ ions by trivalent cations like Al3+, Ga3+ etc. This substitution leaves an excess positive charge on the layers, which is compensated by interlamellar anions. These ions are exchangeable and thus new functionalities can be introduced to ion exchange reactions. Insertion of neutral, non-polar or poorly water-soluble guest molecules remains a challenge. In the present study, two methodologies were adopted to extend the host-guest chemistry of LDHs to neutral and non-polar species, first by using Hydrophobic interaction and second, charge transfer (CT) interaction as driving force. Hlydrophobic interaction as driving force involves functionalization of the Mg-Al-LDH galleries as bilayers, thus covering the essentially hydrophilic interlamellar space of the LDH to one that is hydrophobic and able to solubilize neutral molecules like Anthracene. CT interaction as driving force, involves pre-functionalization of the galleries of the LDH with a donor species e.g. 4-aminobenzoic acid by conventional ion exchange methods to form a LDH-donor intercalated compound. This compound can selectively adsorb acceptor species like Chloranil, Tetracyanoquinodimethane etc. into the interlamellar space of the solid by forming donor-acceptor complexes. The confined donor-acceptor complexes have been characterized by X-Ray Diffraction, UV-Visible, Fourier Transformed Infra-Red and Raman Spectroscopy, Molecular Dynamics Simulations were able to reproduce the experimental results. One dimensional gold nanostructure like nanorods (AuNRs) have received great attention due to their size dependent optical properties, Extending these applications requires assembling the AuNRs into one-, two- and if possible three-dimensional architectures. Several approaches have been developed to assemble AuNRs in two-orientation modes namely end-to-end and side-to-side. The present study self-assembly of the AuNRs has been achieved by anchoring β-cyclodextrin (β-CD) cavities to the nanorods surface. The host-guest chemistry of β-CD has been exploited to assemble the AuNRs. Our strategy was to use a guest molecule that is capable to link β-CD into 1:2 host-guest fashions to link up two β-CD capped nanorods. The guest molecule chosen for the present study was 1,10-phenanthroline. Linkage between the ends of rods leading to V-shaped rods dimmer assembly and side-to-side assembly was achieved by varying the extent of cyclodextrin capping of the AuNRs followed by the addition of linker, 1,10-phenanthroline. The formation of the assembly was characterized using UV-Visible-Near-IR Spectoscopy and Transmission Electron Microscopy.

Layered Double Hydroxides (LDHs)

Gold Nanorods (AuNRs)

Charge Transfer

Anionic Clays

Mg-Al LDH-DDS

Gold Nanorod Hybrids

Charge-Transfer Complexes

Inorganic Chemistry

Ultrafast photodynamics of ZnO solar cells sensitized with the organic indoline derivative D149

Rohwer, Egmont Johann

04 1900

Thesis (PhD)--Stellenbosch University, 2014. / ENGLISH ABSTRACT: The initial charge transfer from dye molecules' excited states to the conduction band of a semiconductor, after absorption of visible light by the former, is critical to the performance of Dye sensitized Solar Cells (DSC). In a ZnO-based DSC sensitized by the organic indoline derivative D149, the dynamics associated with charge transfer are investigated with femtosecond transient absorption spectroscopy. The time-resolved measurement of the photo-initiated processes reveal electron transfer rates corresponding to excited state lifetimes of 100s of fs, consistent with previously measured high absorbed photon to current conversion efficiencies. The photo-electrode measured as an isolated system shows decay times of bound electrons in excited states of the dye to be ~150 fs and shows the subsequent emergence of absorption bands of the oxidized molecules. When the I-/I-3 redox couple is added to the system, these excited state lifetimes change and are found to be dependent on the cation in the electrolytic solution. Small cations like Li+ reduce the excited state lifetime to sub-100 fs, whilst larger cations like the organic tetrabutylammonium result in longer lifetimes of 240 fs. The action of the electrolyte can be observed by the reduced lifetime of the oxidized dye molecules' absorption bands. The effect of operating parameters and changes in the production protocol of the DSC on the primary charge injection are also investigated and reported on. / AFRIKAANSE OPSOMMING: Die aanvanklike ladingsoordrag vanuit kleurstofmolekules' opgewekte toestande tot in die leidingsband van 'n halfgeleier, na absorpsie van sigbare lig deur eersgenoemde, is van kritiese belang vir die uitset van halfgeleier-gebaseerde sonkragselle wat met kleurstowwe vir absorpsie verhoging, gebind is. In hierdie werk word hierdie proses en verwante fotodinamika in die geval van 'n ZnO sonkragsel gekleur met indolien D149 ondersoek d.m.v femtosekonde-tydopgelosde absorpsiespektroskopie. Hierdie metings onthul elektron-oordragstempos wat ooreenstem met lewenstye van opgewekte toestande in die orde van 100 fs. Hierdie is met voorheen-bepaalde hoë foton-tot-stroom omskakelingsdoeltreffendheid ooreenkomstig. Die foto-elektrode, as geïsoleerde sisteem beskou, toon afvalstye van gebonde elektrone in opgewekte toestande van ~150 fs, en die gevolglike opkoms van absorpsie deur geoksideerde molekules word waargeneem. As die I-/I-3 redoks oplossing tot die sisteem bygevoeg word, verander die opgewekte toestande se afvalstye en toon 'n katioon-afhanklikheid. Klein katioone soos Li+ verkort die afvalstye tot onder 100 fs, terwyl groter katioone soos die organiese tetra-butielammonium langer afvalstye (240 fs) tot gevolg het. Die werking van die elektrolitiese oplossing kan waargeneem word deur die verkorte lewenstyd van die absorpsiebande wat aan die geoksideerde molekules toegeken is. Die uitwerking van operasionele parameter asook veranderinge in die produksie protokol op die primêre ladingsoordrag word ondersoek en verslag daarop word gelewer.

Dye sensitized solar cells

Femtosecond spectroscopy

Zinc oxide

Charge transfer

Organic dyes

Indoline

UCTD

Dissertations -- Physics

Theses -- Physics