Probing The Equilibrium Geometry Of Weakly Interacting Systems In Solution By Hyper-Rayleigh Scattering

Pandey, Ravindra

07 1900

Under the electric dipole approximation, second harmonic of the incident light is scattered by a collection of randomly oriented molecular dipoles in solution due to instantaneous orientational fluctuation which is directional. If two such dipoles are correlated in space through intermolecular or other interactions, the intensity of the second harmonic scattered light (SHSL) will be related to the extent of such interactions. If two dipoles are arranged in a particular geometry by design, the geometry will determine the intensity of the SHSL. If a molecule has no dipole moment, the intensity of the SHSL will be less and is only allowed by higher order electric multipoles. If two such zero-dipole molecules interact with each other and transfer some amount of electronic charge from one to the other, the induced dipole moment will give rise to an enhanced SHSL. However, along with the direction of the dipole moment from the donor to the acceptor, the actual geometry of such molecular dimer/complex should also play an important role to determine the nature of the SHSL response. If all the isotropic nonzero components of first hyperpolarizability (β) are taken into account, from the measurement of β and related quantities such as depolarization ratios, in solution it should be possible to derive information about the geometry of the dimer/complex. This is precisely the motivation behind this thesis. Chapter 1 gives a brief introduction of 1:1 charge transfer (CT) complexes between a donor and an acceptor and their importance in chemistry. It also contains an introduction to nonlinear optics, various spectroscopic techniques to characterize CT complexes, etc. The motivation of extracting the geometry of such complexes from hyper-Rayleigh scattering (HRS) measurements in solution is presented in this chapter. In Chapter 2, all the experimental details of the unpolarized and polarization resolved HRS measurements at various excitation wavelengths have been described. Generation of infrared wavelengths (1543 nm and 1907 nm) using stimulated Raman scattering in gases have also been discussed. In Chapter 3, the first hyperpolarizability (βHRS) for two series of 1:1 molecular complexes between methyl substituted benzene donors with tetrachloro-p-benzoquinone (CHL) and dicyanodichloro-p-benzoquinone (DDQ) acceptors in solution at 1543 nm have been presented. Enhancement of βHRS due to charge transfer from the donor to the acceptor molecule which was predicted theoretically has been verified. Using linearly (electric field vector along X direction) and circularly polarized incident light, respectively, two macroscopic depolarization ratios D = I2ω,X,X/I2ω,Z,X and D' = I2ω,X,C/I2ω,Z,C in the laboratory fixed XYZ frame by detecting the SHSL in a polarization resolved fashion have been measured. The experimentally obtained first hyperpolarizability (βHRS), D and D' values, are then matched with the theoretically calculated values from single and double configuration interaction calculations using the Zerner’s intermediate neglect of differential overlap and the self-consistent reaction field (ZINDO–SDCI– SCRF) approach by adjusting the geometrical parameters. It has been found that in most of the CT complexes studied here, there exists a significant twist in the equilibrium geometry at room temperature which is not a simple slipped parallel geometry as was believed. In chapter 4, the βHRS, D and D' values of 1:1 pyridine (PY)-chloranil (CHL) complex at 1064 nm have been described. Previous theoretical studies have shown that there is a tilt angle of 77.9 degree in the gas phase PY-CHL complex. In this chapter, this prediction about the geometry of 1:1 PY-CHL complex has been probed. The experimentally found βHRS, D and D' are matched well with theoretically calculated values, using ZINDO–SDCI–SCRF, for a cofacial geometry of PY-CHL complex in solution indicating that the solution geometry is different from the gas phase geometry. In Chapter 5, the βHRS, D and D' for a series of 1:1 complexes of tropyliumtetrafluoroborate and methyl-substituted benzenes in solution at 1064 nm have been reported. The measured D and D' values vary from 1.36 to 1.46 and 1.62 to 1.72, respectively and are much lower than the values expected from a typical sandwich or a T-shaped geometry. The lowering in D and D' indicates that these complexes have higher symmetry than C2v. The value of D close to 1.5 indicates there is a significant octupolar contribution in such complexes. In order to probe it further, βHRS, D and D' were computed using the ZINDO-SDCI-SCRF technique in the presence of BF4-anion. By arranging the three BF4-ions in a C3 symmetry around the complex in such a way that electrical neutrality is maintained, the computed values are brought to agreement with experiments. This unprecedented influence of the anion on the HRS, D and D' values of these complexes are discussed in this chapter. In Chapter 6, the effect of dipolar interactions, within a multichromophoric system, on the second order nonlinear optical properties have been studied. It has been found that the βHRS response of the multichromophoric system is always larger than expected for uncorrelated chromophores demonstrating that the dipole moment of individual chromophores are not merely additive within the multichromophoric system but contribute cooperatively to the SHSL signal. Also the relative orientation and nature of the chromophores and the angle of interaction between them alter the HRS values. Chapter 7 is the concluding chapter in which all the work done in the thesis has been summarized and future direction has been proposed.

Rayleigh Scattering

Scattering - Equilibrium - Geometry

Charge Transfer Complexes

Hyperpolarization

Nonlinear Optics

Charge Transfer Complexes - Geometry

Hyper-Rayleigh Scattering

Electron Donor-acceptor Complexes

Pyridine-Chloranil Complex

Optics

Synthesis And Electronic Properties Of Nanowires Of Charge Transfer Complexes

Sai, T Phanindra

01 1900

In case of charge-transfer complex of TTF:TCNQ lot of work had previously been done on single crystals and thin films to study various interesting properties including phase transitions which were attributed to Peierls instability. But as seen from the review of molecular wires it is clear that apart from synthesis of TTF:TCNQ in molecular wire form, not much was known about the behavior of these wires at low temperatures. There were some open questions listed below, which we tried to address in the thesis Can nanowires of TTF:TCNQ be grown across prefabricated electrodes which are separated by gaps < 1 μm. Can the nanowires grown in such smaller gaps, show Peierls transition, which is the signature of quasi one dimensional conduction. As the size and length of the grown wires are small it was expected that they will have less staking disorder as compared to the thin films. What will be conduction mechanism at low temperatures in such single/few nanowire samples. If the nanowires show Peierls transition and CDW formation at low temperatures, can nonlinear conduction be seen due to motion of CDW, if so how well do they compare with the reported results for TTF:TCNQ single crystals. In case of Cu:TCNQ it can be noted from the above review that even though much advances have been made on synthesizing good quality Cu:TCNQ films and incorporating them in novel device structures, there has been much controversy regarding conduction mechanism. There were many conflicting results in literature regarding switching in these devices. In this thesis work we wanted to address the feasibility of switching in Cu:TCNQ under reduced size of top electrodes and also address few other issues like To grow Cu:TCNQ nanowires by using vapor phase evaporation method Can resistive switching be induced in Cu:TCNQ by using a local probe STM tip (Pt-Rh) operated in high vacuum. Since the measurement will be done in high vacuum what will be the effect of environment (absence of oxygen, water vapor) on reproducibility of resistive switching. Will localized switching depend on the top electrode material. This has been probed by coating different metals on the C-AFM tip and using them as top electrode in conducting mode. With what contact force will we get reproducible resistive switching. Can a device structure be made with an array of top electrode in the form of metal dots (< 10 μm) and study switching using C-AFM. This thesis is divided into seven main chapters and two appendix chapters, which are listed below: In the present chapter 1, a detailed overview and literature survey of charge-transfer complexes TTF:TCNQ and Cu:TCNQ which were relevant to our present study was presented. This was followed by our motivation in undertaking the present work. In chapter 2 the various experimental techniques developed during the course of the thesis work such as e-beam lithography, design of the vacuum chamber for deposition of organic molecules, design of ultra high vacuum scanning tunneling microscope (UHV-STM chamber along with the STM head, modification of conducting AFM for obtaining the switching data have been described. In chapter 3 we describe the preparation of TTF:TCNQ molecular wires across prefabricated electrodes and different measurements done on the samples. In particular the observation Peierls transition in the grown nanowires of TTF:TCNQ and the nonlinear conduction mechanism involved at low temperatures will be discussed in detail. In chapter 4 we describe the preparation of Cu:TCNQ nanowires on Cu substrate using vapor phase technique. Resistive switching measurements done on the Cu:TCNQ nanowires in high vacuum with Pt-Rh tip as top electrode will be discussed in detail. In chapter 5 we describe the resistive switching measurements performed on Cu:TCNQ nanowires with different metal coated C-AFM tips as well as FIB deposited platinum dots as top electrodes. In chapter 6 we make a few comments about possible switching mechanism involved, when STM tip, C-AFM induced as well as platinum coated dots were used as top electrodes. In chapter 7 we conclude this thesis by summarizing the main results. Also we point out the scope for future work that can be based upon the results presented in this work. In Appendix A a brief review of self assembled monolayer (SAM) of alkane thiols is presented followed by details about experiments done for insitu study of growth of SAMs of decanethiol and octadecanethiol on silver substrates using ellipsometry and force-displacement spectroscopy. In Appendix B a brief description of work done to grow isolated nanowires of Cu:TCNQ, between two metal electrodes in planar geometry and in anodic alumina membranes is given.

Nanowires

Fourier Transform Infrared Spectroscopy

Charge-Transfer Complexes

Resistive Switching

Molecular Wires

Charge Transfer Complexes

Nanotechnology

Espectroscopia Raman ressonante e cálculos DFT de sistemas modelo de transferência de carga / Resonance Raman spectroscopy and DFT calculation of charge transfer model systems

Monezi, Natália Mariana

22 May 2018

Neste trabalho foram estudados os complexos de transferência de carga resultantes da interação entre as espécies aceptoras de elétrons tetracianoetileno (TCNE) e 7,7,8,8-tetracianoquinodimetano (TCNQ), com aminas mono, bi e tri aromáticas, como espécies doadoras de elétrons, em solução. Também foram estudadas as reações de substituição eletrofílica aromática que ocorre entre o TCNE e aminas. Para tal estudo, foram utilizadas as técnicas espectroscópicas de absorção UV-VIS e Raman, o que permitiu a caracterização dos complexos de transferência de carga, assim como das espécies participantes da reação de tricianovinilação que ocorre entre aminas e TCNE. Para dar suporte aos dados experimentais, cálculos DFT (Teoria do Funcional da Densidade) e TDDFT (Teoria do Funcional da Densidade dependente do tempo) foram realizados, o que permitiu a obtenção das geometrias otimizadas, valores de frequência Raman e energias de transição dessas espécies. Os espectros eletrônicos dos complexos formados entre TCNE e aminas monoaromáticas mostraram que suas energias de transição são proporcionais à capacidade de doação de elétrons da amina. De fato, as energias de transição puderam ser correlacionadas com os valores de potencial de ionização das aminas, apresentando uma correlação linear de acordo com a regra Mulliken. Os espectros Raman permitiram verificar que os modos vibracionais do TCNE envolvidos no processo de transferência de carga apresentam deslocamento para menores números de onda com a diminuição do potencial de ionização da amina, e analogamente, pôde-se obter uma correlação linear entre esses dois parâmetros. No caso das aminas bi e tri aromáticas, a tendência linear entre energia de transição e potencial de ionização foi observada, mas não para os deslocamentos Raman das bandas do TCNE. Na reação de tricianovinilação, os espectros eletrônicos possibilitaram a identificação das espécies participantes da reação, assim como sua caracterização vibracional por espectroscopia Raman ressonante. Através da espectroscopia Raman ressonante, pôde-se, pela primeira vez, caracterizar as espécies intermediárias da reação de tricianovinilação entre TCNE e aminas aromáticas. Os complexos envolvendo TCNQ e aminas monoaromáticas apresentou tendência semelhante à observada em complexos com o TCNE. As energias de transição desses complexos diminuem linearmente, assim como, os modos vibracionais do TCNQ, que apresentam deslocamentos para menores frequências Raman com a diminuição do potencial de ionização da amina. Por outro lado, complexos formados pelo TCNQ e aminas com mais de um anel aromático em sua estrutura, não apresentam correlação entre potencial de ionização do doador e energia de transição e deslocamentos Raman. Os cálculos dos espectros eletrônicos e vibracionais apresentaram boa concordância com os obtidos experimentalmente, porém algumas limitações ficam evidentes na descrição das interações &#960; nesses sistemas modelo. / In this work the charge transfer complexes resulting from the interaction between tetracyanoethylene (TCNE) and 7,7,8,8-tetracyanoquinodimethane (TCNQ), as electron accepting species and mono, bi and tri aromatic amines, as electron donating species, were studied in solution. Also the electrophilic aromatic substitution that occurs between the TCNE and amines has been studied. For this study, the spectroscopic techniques of UV-VIS absorption and Raman were used, which allowed the characterization of the charge transfer complexes, as well as of the species involved in the reaction of tricianovinylation that occurs between amines and TCNE. In order to support the experimental data, DFT (Density Functional Theory) and TDDFT (Time-dependent Density Functional Theory) calculations were performed, to obtain the optimized geometries, Raman frequency values and theoretical transition energies of such species. The electronic spectra of the complexes formed between TCNE and monoaromatic amines showed that their transition energies are proportional to the amine electron donation capacity. In fact it could be linearly correlated with the ionization potential values of the amines, following the Mullikens rule. The Raman spectra allowed to verify that the vibrational modes of the TCNE involved in the process of charge transfer, were displaced to lower wavenumbers with the reduction of the ionization potential of the amine, and analogously, a linear correlation between these two parameters could be obtained. In the case of bi and tri aromatic amines, the linear trend between transition energy and ionization potential was observed, but not for the Raman shifts of the TCNE bands. In the reaction of tricianovinylation, the electronic spectra enabled the identification of the participating species in the reaction, and their vibrational characterization by resonance Raman. Using resonance Raman spectroscopy, it was possible to characterize the intermediate species of the tricianovinylation reaction between TCNE and aromatic amines for the first time. The complexes involving TCNQ and monoaromatic amines showed a similar trend to that observed in complexes with TCNE. The transition energies of these complexes decrease linearly, as well as the vibrational modes of the TCNQ, which present shifts to lower Raman frequencies with the decrease of the ionization potential of the amine. On the other hand, complexes formed by TCNQ and amines with more than one aromatic ring in their structure do not present correlation between donor ionization potential and transition energy and Raman displacements. The calculations of the electronic and vibrational spectra presented good agreement with those obtained experimentally, however some limitations were evidenced in the description of the &#960; interactions in these model systems.

Charge transfer complexes

complexos de transferência de carga

Espectroscopia vibracional

TCNE

TCNE

TCNQ

TCNQ

TDDFT

TDDFT

Tricianovinilação

Tricyanovinylation

Vibrational spectroscopy

Estudo teórico de complexos de transferência de carga em solução / Theoretical Study of Charge-transfer Complexes in Solution

Silva, Fernando da

19 October 2016

Neste trabalho foram estudados os complexos de transferência (CTC) de carga formados por iodeto com os derivados piridínicos C4(4CP)+ e C3bis(4CP)2+ em solução. A formação de um CTC é caracterizada pelo surgimento de uma nova banda no espectro eletrônico de absorção, em solventes orgânicos como acetonitrila. Este tipo de sistema tem recebido muito interesse em diversos campos como, por exemplo, eletrônica orgânica, espectroscopia não linear, bioquímica, no ramo farmacêutico, etc. O complexo C4(4CP)+I- é caracterizado por uma banda de transferência de carga com máximo em 421 nm em acetonitrila. Cálculos das propriedades eletrônicas e das energias de excitação do complexo foram realizados usando a teoria do funcional da densidade e a teoria do funcional da densidade dependente do tempo. O emprego de funcionais de troca e correlação com correções de longo alcance foi essencial para a obtenção de resultados acurados para as energias de excitação. Usando os funcionais CAM-B3LYP e B97X-D, associados ao modelo contínuo PCM, foi possível descrever muito bem o máximo da banda experimental. No caso do C3bis(4CP)2+ foram encontradas diferentes estruturas possíveis para o complexo, que podem ser formadas pela associação de um ou dois I-. Em todos os casos apenas um dos I- participa da excitação, o que explica a estequiometria 1:1 observada experimentalmente. Uma visão mais aprofunda do comportamento do complexo em solução foi obtida usando a dinâmica molecular clássica. O campo de força foi ajustado para reproduzir os resultados de uma dinâmica por primeiros princípios de vácuo. A dinâmica clássica mostrou não haver dissociação em acetonitrila no complexo formado com o C3bis(4CP)2+. A banda calculada a partir das configurações amostradas da dinâmica está em excelente acordo com o resultado experimental. / In this work, we have studied theoretically charge-transfer complexes (CTC) formed by pyridinium derivatives with iodide. The formation of a CTC is characterized by the appearance of a new absorption band on the electronic spectra, in organic polar solvents like acetonitrile. These type of systems have recently received much interest in a broad variety of fields, for example, organic electronics, nonlinear spectroscopy, medical biochemistry, pharmaceutical industry, etc. The C4(4CP)+I- complex is characterized by the charge-transfer band with a maximum at 421 nm in acetonitrile. We have used density functional theory (DFT) and time dependent density functional theory (TDDFT) to calculate electronic properties and the excitation energies of the complex. Functionals with long-range corrections were essential in describing the charge-transfer excitations. CAM-B3LYP and wB97X-D associated with the polarizable continuum model predicts CT excitations in good agreement with experiment. Our results also indicates the existence of different conformations for the complex formed by the C3bis(4CP)2+ with iodide. Complexes were formed by the association of one or two I- to C3bbis(4CP)2+, but the charge transfer excitations were calculated from only one iodide to the aromatic ring, what explain why the stoichiometry 1:1 was observed. A better description of the complex in solution was obtained using classical molecular dynamics. The OPLS-AA force field was fine-tuned to reproduce the results of a first principle molecular dynamics for the complex. No dissociation were observed. The calculated charge-transfer band using configurations sampled from molecular dynamics is in excellent agreement with experiment.

Charge-transfer complexes

DFT

DFT

Dinâmica Molecular

Molecular Dynamics

Quantum Chemistry

TDDFT

TDDFT

Recyclage de complexes bis(oxazolines)- cuivre chiraux pour la catalyse asymétrique : hétérogénéisation par interactions non-covalentes / Recycling chiral copper-bis(oxazoline) complexes for asymmetric catalysis thanks to non-covalents interactions

Didier, Dorian

17 October 2011

Les ligands de type bis(oxazolines) associés à des sels métalliques ont montré leur efficacité dans de nombreuses réactions de formation de liaisons C-C. L’utilisation de tels complexes chiraux en tant que catalyseurs asymétriques permet l’accès à une large variété de synthons fonctionnalisés énantioenrichis pour la synthèse de composés d’intérêt biologique. Cependant, un taux catalytique important (souvent 10 mol%) est nécessaire à l’obtention de bonnes activités et énantiosélectivités. Il est donc intéressant de pouvoir recycler ces complexes de manière à réduire le coût de leur emploi mais également d’augmenter le turn-over de ces réactions énantiosélectives.La structure des bis(oxazolines) a donc été choisie de manière à permettre le recyclage de catalyseurs par hétérogénéisation. Un nouveau concept a ainsi été mis en place, impliquant la formation de complexes à transfert de charge (CTC) entre un groupement anthracényle et la trinitrofluorénone. La formation de telles interactions non-covalentes permet la précipitation du catalyseur sous forme de CTC en milieu apolaire par ajout de pentane. Ce procédé ayant donné de très bons résultats pour la cycloaddition de Diels-Alder avec des complexes de cuivre, nous l’avons l’appliqué à d’autres transformations stéréosélectives dans le but d’étendre le champ d’application de notre méthode. Nous avons ainsi étudié cette méthode de recyclage pour les réactions de nitroaldolisation, ène-carbonyle et de cyclopropanation, à la fois dans des procédures mono- et multi-substrats mais également dans une procédure multi-réactions. Les rendements et les excès énantiomériques obtenus grâce à ces nouveaux complexes de cuivre chiraux sont analogues aux valeurs observées dans des conditions de catalyse homogène décrites dans la bibliographie. Dans une grande majorité des cas, une excellente stabilité du catalyseur en termes de sélectivité et d’activité est relevée à travers ses différentes réutilisations.La synthèse et l’utilisation de nouveaux supports permettant la formation de CTC ou d’interactions π ont également été réalisées de manière à éviter l’ajout de pentane jusqu’alors nécessaire à la précipitation de notre espèce catalytique. Ce type de catalyseur a pu être mis à l’épreuve dans les mêmes réactions que celles citées ci-dessus, avec des supports modifiés tels que le polystyrène ou la silice, mais également en présence de charbon actif. Cela nous a permis d’obtenir de bons résultats quant à l’efficacité des catalyseurs dans différentes procédures de catalyse hétérogène, avec une bonne conservation des valeurs de rendements et d’énantiosélectivités. / Chiral bis(oxazolines) associated to various metallic salts have been described as very powerful ligands for the catalytic C-C bond formation. The use of these chiral complexes as asymmetric catalysts allows for scalemic preparation of a wide range of functionalized synthons for the preparation of biologically active compounds. However, an important catalytic amount (around 10 mol%) is often needed to obtain high yields and enantioselectivities. Recycling these complexes can be interesting in terms of cost reduction and increase of the turn-over of these enantioselective reactions.These bisoxazolines were designed to allow recycling of the catalyst by heterogeneization thanks to a new methodology involving the formation of charge transfer complexes (CTC). This non-covalent interaction, linking the anthracenyle moiety and the trinitrofluorenone leads to precipitation of the catalytic species as a CTC due to the addition of pentane. This procedure has successfully been applied to the Diels-Alder reaction with copper complexes and we then endeavoured to carry out other transformations in order to broaden the scope of our methodology. We therefore attempted to carry out nitroaldolizations, carbonyle-ene and cyclopropanations reactions, both in mono- and multi-substrates procedures and in an original multi-reaction concept. Yields and enantioselectivities obtained with these new chiral catalysts compared satisfactorily with described homogeneous conditions. In the most cases, the CTC proved to be highly stable over the course of its different reuses.New supports allowing for CTC formation or π interactions have been prepared and tested in order to avoid having to precipitate the catalyst with pentane for recovery. This type of catalyst was subjected to the same, previously mentioned, reactions with modified supports such as polystyrene, silica or charcoal. These modifications made for efficient homogenous catalytical systems, whilst conserving high yields and enantioselectivities.

Bis(oxazolines)

Complexes à transfert de charge

Recyclage

Catalyse asymétrique hétérogène

Bis(oxazolines)

Charge transfer complexes

Recycling

Heterogeneous asymmetric catalysis

Espectroscopia Raman ressonante e cálculos DFT de sistemas modelo de transferência de carga / Resonance Raman spectroscopy and DFT calculation of charge transfer model systems

Natália Mariana Monezi

22 May 2018

Neste trabalho foram estudados os complexos de transferência de carga resultantes da interação entre as espécies aceptoras de elétrons tetracianoetileno (TCNE) e 7,7,8,8-tetracianoquinodimetano (TCNQ), com aminas mono, bi e tri aromáticas, como espécies doadoras de elétrons, em solução. Também foram estudadas as reações de substituição eletrofílica aromática que ocorre entre o TCNE e aminas. Para tal estudo, foram utilizadas as técnicas espectroscópicas de absorção UV-VIS e Raman, o que permitiu a caracterização dos complexos de transferência de carga, assim como das espécies participantes da reação de tricianovinilação que ocorre entre aminas e TCNE. Para dar suporte aos dados experimentais, cálculos DFT (Teoria do Funcional da Densidade) e TDDFT (Teoria do Funcional da Densidade dependente do tempo) foram realizados, o que permitiu a obtenção das geometrias otimizadas, valores de frequência Raman e energias de transição dessas espécies. Os espectros eletrônicos dos complexos formados entre TCNE e aminas monoaromáticas mostraram que suas energias de transição são proporcionais à capacidade de doação de elétrons da amina. De fato, as energias de transição puderam ser correlacionadas com os valores de potencial de ionização das aminas, apresentando uma correlação linear de acordo com a regra Mulliken. Os espectros Raman permitiram verificar que os modos vibracionais do TCNE envolvidos no processo de transferência de carga apresentam deslocamento para menores números de onda com a diminuição do potencial de ionização da amina, e analogamente, pôde-se obter uma correlação linear entre esses dois parâmetros. No caso das aminas bi e tri aromáticas, a tendência linear entre energia de transição e potencial de ionização foi observada, mas não para os deslocamentos Raman das bandas do TCNE. Na reação de tricianovinilação, os espectros eletrônicos possibilitaram a identificação das espécies participantes da reação, assim como sua caracterização vibracional por espectroscopia Raman ressonante. Através da espectroscopia Raman ressonante, pôde-se, pela primeira vez, caracterizar as espécies intermediárias da reação de tricianovinilação entre TCNE e aminas aromáticas. Os complexos envolvendo TCNQ e aminas monoaromáticas apresentou tendência semelhante à observada em complexos com o TCNE. As energias de transição desses complexos diminuem linearmente, assim como, os modos vibracionais do TCNQ, que apresentam deslocamentos para menores frequências Raman com a diminuição do potencial de ionização da amina. Por outro lado, complexos formados pelo TCNQ e aminas com mais de um anel aromático em sua estrutura, não apresentam correlação entre potencial de ionização do doador e energia de transição e deslocamentos Raman. Os cálculos dos espectros eletrônicos e vibracionais apresentaram boa concordância com os obtidos experimentalmente, porém algumas limitações ficam evidentes na descrição das interações &#960; nesses sistemas modelo. / In this work the charge transfer complexes resulting from the interaction between tetracyanoethylene (TCNE) and 7,7,8,8-tetracyanoquinodimethane (TCNQ), as electron accepting species and mono, bi and tri aromatic amines, as electron donating species, were studied in solution. Also the electrophilic aromatic substitution that occurs between the TCNE and amines has been studied. For this study, the spectroscopic techniques of UV-VIS absorption and Raman were used, which allowed the characterization of the charge transfer complexes, as well as of the species involved in the reaction of tricianovinylation that occurs between amines and TCNE. In order to support the experimental data, DFT (Density Functional Theory) and TDDFT (Time-dependent Density Functional Theory) calculations were performed, to obtain the optimized geometries, Raman frequency values and theoretical transition energies of such species. The electronic spectra of the complexes formed between TCNE and monoaromatic amines showed that their transition energies are proportional to the amine electron donation capacity. In fact it could be linearly correlated with the ionization potential values of the amines, following the Mullikens rule. The Raman spectra allowed to verify that the vibrational modes of the TCNE involved in the process of charge transfer, were displaced to lower wavenumbers with the reduction of the ionization potential of the amine, and analogously, a linear correlation between these two parameters could be obtained. In the case of bi and tri aromatic amines, the linear trend between transition energy and ionization potential was observed, but not for the Raman shifts of the TCNE bands. In the reaction of tricianovinylation, the electronic spectra enabled the identification of the participating species in the reaction, and their vibrational characterization by resonance Raman. Using resonance Raman spectroscopy, it was possible to characterize the intermediate species of the tricianovinylation reaction between TCNE and aromatic amines for the first time. The complexes involving TCNQ and monoaromatic amines showed a similar trend to that observed in complexes with TCNE. The transition energies of these complexes decrease linearly, as well as the vibrational modes of the TCNQ, which present shifts to lower Raman frequencies with the decrease of the ionization potential of the amine. On the other hand, complexes formed by TCNQ and amines with more than one aromatic ring in their structure do not present correlation between donor ionization potential and transition energy and Raman displacements. The calculations of the electronic and vibrational spectra presented good agreement with those obtained experimentally, however some limitations were evidenced in the description of the &#960; interactions in these model systems.

complexos de transferência de carga

Espectroscopia vibracional

TCNE

TCNQ

TDDFT

Tricianovinilação

Charge transfer complexes

TCNE

TCNQ

TDDFT

Tricyanovinylation

Vibrational spectroscopy

Estudo teórico de complexos de transferência de carga em solução / Theoretical Study of Charge-transfer Complexes in Solution

Fernando da Silva

19 October 2016

Neste trabalho foram estudados os complexos de transferência (CTC) de carga formados por iodeto com os derivados piridínicos C4(4CP)+ e C3bis(4CP)2+ em solução. A formação de um CTC é caracterizada pelo surgimento de uma nova banda no espectro eletrônico de absorção, em solventes orgânicos como acetonitrila. Este tipo de sistema tem recebido muito interesse em diversos campos como, por exemplo, eletrônica orgânica, espectroscopia não linear, bioquímica, no ramo farmacêutico, etc. O complexo C4(4CP)+I- é caracterizado por uma banda de transferência de carga com máximo em 421 nm em acetonitrila. Cálculos das propriedades eletrônicas e das energias de excitação do complexo foram realizados usando a teoria do funcional da densidade e a teoria do funcional da densidade dependente do tempo. O emprego de funcionais de troca e correlação com correções de longo alcance foi essencial para a obtenção de resultados acurados para as energias de excitação. Usando os funcionais CAM-B3LYP e B97X-D, associados ao modelo contínuo PCM, foi possível descrever muito bem o máximo da banda experimental. No caso do C3bis(4CP)2+ foram encontradas diferentes estruturas possíveis para o complexo, que podem ser formadas pela associação de um ou dois I-. Em todos os casos apenas um dos I- participa da excitação, o que explica a estequiometria 1:1 observada experimentalmente. Uma visão mais aprofunda do comportamento do complexo em solução foi obtida usando a dinâmica molecular clássica. O campo de força foi ajustado para reproduzir os resultados de uma dinâmica por primeiros princípios de vácuo. A dinâmica clássica mostrou não haver dissociação em acetonitrila no complexo formado com o C3bis(4CP)2+. A banda calculada a partir das configurações amostradas da dinâmica está em excelente acordo com o resultado experimental. / In this work, we have studied theoretically charge-transfer complexes (CTC) formed by pyridinium derivatives with iodide. The formation of a CTC is characterized by the appearance of a new absorption band on the electronic spectra, in organic polar solvents like acetonitrile. These type of systems have recently received much interest in a broad variety of fields, for example, organic electronics, nonlinear spectroscopy, medical biochemistry, pharmaceutical industry, etc. The C4(4CP)+I- complex is characterized by the charge-transfer band with a maximum at 421 nm in acetonitrile. We have used density functional theory (DFT) and time dependent density functional theory (TDDFT) to calculate electronic properties and the excitation energies of the complex. Functionals with long-range corrections were essential in describing the charge-transfer excitations. CAM-B3LYP and wB97X-D associated with the polarizable continuum model predicts CT excitations in good agreement with experiment. Our results also indicates the existence of different conformations for the complex formed by the C3bis(4CP)2+ with iodide. Complexes were formed by the association of one or two I- to C3bbis(4CP)2+, but the charge transfer excitations were calculated from only one iodide to the aromatic ring, what explain why the stoichiometry 1:1 was observed. A better description of the complex in solution was obtained using classical molecular dynamics. The OPLS-AA force field was fine-tuned to reproduce the results of a first principle molecular dynamics for the complex. No dissociation were observed. The calculated charge-transfer band using configurations sampled from molecular dynamics is in excellent agreement with experiment.

DFT

Dinâmica Molecular

TDDFT

Charge-transfer complexes

DFT

Molecular Dynamics

Quantum Chemistry

TDDFT

Non-OH chemistry in oxidation flow reactors for the study of atmospheric chemistry systematically examined by modeling

Peng, Zhe, Day, Douglas A., Ortega, Amber M., Palm, Brett B., Hu, Weiwei, Stark, Harald, Li, Rui, Tsigaridis, Kostas, Brune, William H., Jimenez, Jose L.

06 April 2016

Oxidation flow reactors (OFRs) using low-pressure Hg lamp emission at 185 and 254 nm produce OH radicals efficiently and are widely used in atmospheric chemistry and other fields. However, knowledge of detailed OFR chemistry is limited, allowing speculation in the literature about whether some non-OH reactants, including several not relevant for tropospheric chemistry, may play an important role in these OFRs. These non-OH reactants are UV radiation, O(¹D), O(³P), and O₃. In this study, we investigate the relative importance of other reactants to OH for the fate of reactant species in OFR under a wide range of conditions via box modeling. The relative importance of non-OH species is less sensitive to UV light intensity than to water vapor mixing ratio (H₂O) and external OH reactivity (OHR_ext), as both non-OH reactants and OH scale roughly proportionally to UV intensity. We show that for field studies in forested regions and also the urban area of Los Angeles, reactants of atmospheric interest are predominantly consumed by OH. We find that O(¹D), O(³P), and O₃ have relative contributions to volatile organic compound (VOC) consumption that are similar or lower than in the troposphere. The impact of O atoms can be neglected under most conditions in both OFR and troposphere. We define “riskier OFR conditions” as those with either low H₂O (< 0.1 %) or high OHR_ext ( ≥  100 s⁻¹ in OFR185 and > 200 s⁻¹ in OFR254). We strongly suggest avoiding such conditions as the importance of non-OH reactants can be substantial for the most sensitive species, although OH may still dominate under some riskier conditions, depending on the species present. Photolysis at non-tropospheric wavelengths (185 and 254 nm) may play a significant (> 20 %) role in the degradation of some aromatics, as well as some oxidation intermediates, under riskier reactor conditions, if the quantum yields are high. Under riskier conditions, some biogenics can have substantial destructions by O₃, similarly to the troposphere. Working under low O₂ (volume mixing ratio of 0.002) with the OFR185 mode allows OH to completely dominate over O₃ reactions even for the biogenic species most reactive with O₃. Non-tropospheric VOC photolysis may have been a problem in some laboratory and source studies, but can be avoided or lessened in future studies by diluting source emissions and working at lower precursor concentrations in laboratory studies and by humidification. Photolysis of secondary organic aerosol (SOA) samples is estimated to be significant (> 20 %) under the upper limit assumption of unity quantum yield at medium (1 × 10¹³ and 1.5 × 10¹⁵ photons cm⁻² s⁻¹ at 185 and 254 nm, respectively) or higher UV flux settings. The need for quantum yield measurements of both VOC and SOA photolysis is highlighted in this study. The results of this study allow improved OFR operation and experimental design and also inform the design of future reactors.

SECONDARY ORGANIC AEROSOL

COMPLEX REFRACTIVE-INDEXES

ABSORPTION CROSS-SECTIONS

CHARGE-TRANSFER COMPLEXES

PRESSURE MERCURY LAMPS

EVALUATED KINETIC-DATA

BROWN CARBON AEROSOLS

BIOMASS-BURNING SMOKE

GAS-PHASE

CHEMICAL MECHANISMS

Engineering of functionalized monolayers for molecular electronics / Ingénierie des monocouches fonctionnelles pour l’électronique moléculaire

Jalkh, Joanna

27 November 2015

La modification des surfaces revêt un intérêt primordial dans de nombreux champs d'applications de la chimie, comme la chimie analytique et l'électronique moléculaire. Ce travail a porté sur l'étude de différentes monocouches liées de façon covalente à des surfaces conductrices (principalement le carbone) et préparées à partir de l'électroréduction de sels d'aryldiazonium. Ces monocouches organiques ont été fonctionnalisées avec des groupements terminaux électroactifs différents, et l'on s'est intéressé aux propriétés de transfert de charge (au sens large) des couches résultantes. Tout d'abord des couches portant un système redox simple à base de ferrocène ont été étudiées dans différents milieux organiques conventionnels et en milieu liquides ioniques. L'effet de l'éloignement du système redox vis-à-vis de la surface a été également analysé en variant la longueur du pont ancrant. Dans un second temps, les monocouches organiques ont été fonctionnalisées par des unités tétrathiafulvalène (TTF). Les TTF sont des molécules (donneur d'électrons) connues pour former des complexes à transfert de charge avec le tétracyanoquinodiméthane (TCNQ), accepteur d'électrons. La formation de complexes à transfert de charge entre des TTF immobilisées dans la monocouche et des dérivés TCNQ a été étudiée et modulée selon l'éloignement du TTF vis-à-vis de la surface (variation de la longueur du lien ancrant) et en fonction de la force de l'accepteur. Enfin, des monocouches avec des groupements terminaux de type fluorène ou spirobifluorène (SBF) ont été préparées. Le comportement bloquant vis-à-vis-du transfert d'électron a été étudié par microscopie électrochimique (SECM) en présence de deux médiateurs redox différents et la conductivité des couches a été évaluée par CP-AFM (microscopie à force atomique – mesure de courants locaux). Il est montré que les propriétés de transfert/transport de charges sont influencées par l'encombrement stérique associé au fluorène ou au SBF (variation de la substitution). Ces monocouches organiques stables, bien organisées apparaissent très prometteuses comme composants dans des dispositifs d'électronique moléculaire. / Surface modification is of paramount importance in many fields of chemistry like analytical chemistry and molecular electronics. This work deals with the study of different monolayers covalently bound on conducting (mainly carbon) surfaces, and produced from the electroreduction of aryldiazonium salts. By introducing electroactive components in the resulting monolayers, the different studies in this work mainly focused on charge-transfer properties (in a large sense). First, monolayers bearing simple redox-active ferrocenyl terminal groups were investigated. The electrochemical behavior of these monolayers was analyzed in different conventional organic media and in ionic liquids (RTILs) and by varying the length of the bridging unit between the surface and the ferrocene groups. Second, redox-active tetrathiafulvalene (TTF) molecules were used to functionalize the monolayers. TTF molecules are well-known donor molecules able to form charge-transfer complexes with tetracyanoquinodimethane (TCNQ) as an electron-acceptor. The formation of charge-transfer complexes between immobilized TTF and TCNQ derivatives was studied and modulated by varying the chain length of the bridging unit between the TTF donor and the surface and by varying the electron-withdrawing ability of the TCNQ acceptors. Third, monolayers with fluorene and spirobifluorene (SBF) terminal groups were prepared. The blocking behavior towards electron transfer was studied by electrochemical microscopy (SECM) with two redox mediators and the conductivity of the layers was investigated by CP-AFM (Conducting Probe-Atomic Force Microscopy). Effects due to the steric hindrance of the fluorene or SBF derivatives were evidenced. Such stable, organized and organic monolayers seem to be promising candidates for molecular electronic devices.

Surfaces modifiés

Monocouches organiques

Liquides ioniques

Complexes de transfert de charges

Électronique moléculaire

Modified surfaces

Organic monolayers

Room temperature ionic liquids

Charge-Transfer complexes

Molecular electronics

On the nature of the electronics structure of metal-metal quadruply bonded complexes

D'Acchioli, Jason S.

07 October 2005

No description available.

Metal-metal multiple bonds

metal-metal quadruple bonds

density functional theory

electron paramagnetic resonance

inter-valence charge transfer complexes