Ionic Liquids under Confinement: From Systematic Variations of the Ion and Pore Sizes toward an Understanding of the Structure and Dynamics in Complex Porous Carbons

We use molecular simulations of an ionic liquid in contact with a range of nanoporous carbons to investigate correlations between the ion size, pore size, pore topology, and properties of the adsorbed ions. We show that diffusion coefficients increase with the anion size and, surprisingly, with the quantity of adsorbed ions. Both findings are interpreted in terms of confinement: when the in-pore population increases, additional ions are located in less-confined sites and diffuse faster. Simulations in which the pores are enlarged while keeping the topology constant support these observations. The interpretation of properties across structures is more challenging. An interesting point is that smaller pores do not necessarily lead to a larger confinement. In this work, the highest degrees of confinement are observed for intermediate pore sizes. We also show a correlation between the quantity of adsorbed ions and the ratio between the maximum pore diameter and the pore limiting diamete

On the development of an original mesoscopic model to predict the capacitive properties of carbon-carbon supercapacitors

We report on the development of a lattice model to predict structural, dynamical and capacitive properties of electrochemical double layer capacitors. The model uses input from molecular simulations, such as free energy profiles to describe the ion adsorption, and experiments, such as energy barriers for transitions between lattice sites. The model developed is approximately 10,000 times faster than common molecular simulations. We apply this model to a set of carbon structures with well-defined pore sizes and investigate the solvation effect by doing simulations with neat ionic liquids as well as acetonitrile-based electrolytes. We show that our model is able to predict quantities of adsorbed ions and capacitances in a range compatible with experimental values. We show that there is a strong dependency of the calculated properties on the pore size and on the presence or absence of solvent. In particular, for neat ionic liquids, larger capacitances are obtained for smaller pores, while the opposite trend is observed for organic electrolytes

Fermi level shift in carbon nanotubes by dye confinement

International audienceDye confinement into carbon nanotube significantly affects the electronic charge density distribution of the final hybrid system. Using the electron-phonon coupling sensitivity of the Raman G-band, we quantify experimentally how charge transfer from thiophene oligomers to single walled carbon nanotube is modulated by the diameter of the nano-container and its metallic or semiconducting character. This charge transfer is shown to restore the electron-phonon coupling into defected metallic nanotubes. For sub-nanometer diameter tube, an electron transfer optically activated is observed when the excitation energy matches the HOMO-LUMO transition of the confined oligothiophene. This electron doping accounts for an important enhancement of the photoluminescence intensity up to a factor of nearly six for optimal confinement configuration. This electron transfer shifts the Fermi level, acting on the photoluminescence efficiency. Therefore, thiophene oligomer encapsulation allows modulating the electronic structure and then the optical properties of the hybrid system

Confinement of pi-conjugated oligomers inside carbon nanotubes : modeling of infrared vibrational dynamics

La fonctionnalisation non covalente des nanotubes de carbone constitue une approche élégante pour moduler leurs propriétés physiques. Néanmoins, une compréhension profonde des interactions entre la matrice hôte et les substances ajoutés est nécessaire pour maîtriser les propriétés physiques des systèmes hybrides ainsi construits. Dans ce cadre, l'étude des propriétés vibrationnelles, par le biais de techniques spectroscopiques, est une étape indispensable. Cependant, la mise en jeu de plusieurs composantes en interaction au sein de ces systèmes hybrides rend difficile l'extraction de l'information pertinente de leur réponse spectrale. Ainsi, plusieurs approches doivent être considérées. Le présent travail de thèse combine une approche expérimentale et théorique, se basant sur la théorie de la fonctionnelle de la densité (DFT), pour l'étude de la réponse infrarouge d'un système modèle de nanotubes de carbone fonctionnalisés avec des diméthyl-quaterthiophènes. De plus, une étude énergétique DFT est réalisée pour un autre système modèle de nanotube de carbone fonctionnalisés avec des molécules de phthalocyanine. Cette étude est effectuée dans le but de déterminer la conformation structurale de ces molécules à l'intérieur et à l'extérieur des nanotubes.Non covalent functionalization of carbon nanotubes is an elegant approach to modulate their physical properties. Yet, a deep understanding of the interactions between the host matrix and the added substances is necessary to master the physical properties of the constructed hybrid systems. In this context, the study of the vibrational properties, via spectroscopic techniques, is an essential step. However, the interactions between several components within these hybrid systems makes it difficult to extract the relevant information from their spectral response. Thus, several approaches need to be considered. The present work combine an experimental approach and a theoretical one, based on the density functional theory (DFT), to study the infrared response of a model system of carbon nanotubes functionalized with dimethyl-quaterthiophenes. Moreover, a DFT energetic study is realized for another model system of carbon nanotubes functionalized with phthalocyanine molecules. This study is performed to determine the structural conformation of these molecules inside and outside the nanotub

Confinement d'oligomères pi-conjugués dans les nanotubes de carbone : modélisation de la dynamique vibrationnelle infrarouge

Non covalent functionalization of carbon nanotubes is an elegant approach to modulate their physical properties. Yet, a deep understanding of the interactions between the host matrix and the added substances is necessary to master the physical properties of the constructed hybrid systems. In this context, the study of the vibrational properties, via spectroscopic techniques, is an essential step. However, the interactions between several components within these hybrid systems makes it difficult to extract the relevant information from their spectral response. Thus, several approaches need to be considered. The present work combine an experimental approach and a theoretical one, based on the density functional theory (DFT), to study the infrared response of a model system of carbon nanotubes functionalized with dimethyl-quaterthiophenes. Moreover, a DFT energetic study is realized for another model system of carbon nanotubes functionalized with phthalocyanine molecules. This study is performed to determine the structural conformation of these molecules inside and outside the nanotubeLa fonctionnalisation non covalente des nanotubes de carbone constitue une approche élégante pour moduler leurs propriétés physiques. Néanmoins, une compréhension profonde des interactions entre la matrice hôte et les substances ajoutés est nécessaire pour maîtriser les propriétés physiques des systèmes hybrides ainsi construits. Dans ce cadre, l'étude des propriétés vibrationnelles, par le biais de techniques spectroscopiques, est une étape indispensable. Cependant, la mise en jeu de plusieurs composantes en interaction au sein de ces systèmes hybrides rend difficile l'extraction de l'information pertinente de leur réponse spectrale. Ainsi, plusieurs approches doivent être considérées. Le présent travail de thèse combine une approche expérimentale et théorique, se basant sur la théorie de la fonctionnelle de la densité (DFT), pour l'étude de la réponse infrarouge d'un système modèle de nanotubes de carbone fonctionnalisés avec des diméthyl-quaterthiophènes. De plus, une étude énergétique DFT est réalisée pour un autre système modèle de nanotube de carbone fonctionnalisés avec des molécules de phthalocyanine. Cette étude est effectuée dans le but de déterminer la conformation structurale de ces molécules à l'intérieur et à l'extérieur des nanotubes

An ab initio investigation of photoswitches adsorbed onto metal oxide surfaces: the case of donor–acceptor Stenhouse adduct photochromes on TiO 2 anatase

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Grafting Spiropyran Molecular Switches on TiO 2 : A First-Principles Study

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Modelling excitation energy transfer in covalently linked molecular dyads containing a BODIPY unit and a macrocycle

With the help of time-dependent density functional theory coupled to an implicit solvation scheme (the polarisable continuum model), we have investigated the singlet-singlet Excitation Energy Transfer (EET) process in a panel of large BODIPY-macrocycle dyads. We have first considered different strategies to compute the electronic coupling in a representative BODIPY-zinc porphyrin assembly and, next evaluated the performances of the chosen computational protocol on several BODIPY-porphyrinoid molecular architectures for which the EET rate constants have been experimentally measured. This step showed the robustness of our approach, which is able to reproduce the magnitude of the measured rate constants in most cases. We have finally applied the validated methodology on newly designed dyads combining a BODIPY unit and an azacalixphyrin macrocycle, a recently synthesised porphyrin analogue that displays exceptional optical properties. This work allowed us to propose new molecular architectures presenting improved properties and also to highlight the interest of using azacalixphyrin as a building block in molecular light-harvesting antennas

Grafting Spiropyran Molecular Switches on TiO₂: A First-Principles Study

To explore the optoelectronic properties of spiropyran molecular switches adsorbed onto TiO₂ anatase surfaces, we performed a density functional theory (DFT)/time-dependent density functional theory (TD-DFT) study considering the two isomeric forms of the photochromes anchored by both their sides. A comparison between the features of the hybrid and isolated systems is proposed to probe the adsorption effects on both subsystems. This comparison considered, on the one hand, the density of states and the alignment of the energy levels, and, on the other hand, the UV–visible spectra of these systems. We show that several electronic and optical characteristics of the hybrid systems are modulated by the open/closed state of the photochromes. These properties are also modified by the localization of the anchor group on the photochrome