Long-range repulsive interaction between TTF molecules on a metal surface induced by charge transfer

The low-coverage adsorption of a molecular electron donor, tetrathiafulvalene, on Au(111) is characterized by the spontaneous formation of superlattice of monomers, whose spacing exceeds the equilibrium distance of non-covalent interactions and depends on coverage. The origin of this peculiar growth mode is due to a long-range repulsive interaction between molecules. The analysis of molecular-pair distributions obtained by scanning tunneling microscopy measurements permits us to determine that the nature of TTF intermolecular interactions on Au (111) is electrostatic. A repulsion between molecules is caused by the accumulation of charge due to electron donation into the metal surface, as pictured through density functional theory calculations

Study of the cardiovascular response to different orthostatic stress conditions

Les futures missions espacials de llarga durada requeriran un coneixement profund dels efectes de diferents nivells de gravetat al cos humà, en particular al sistema cardiovascular. Els models computacionals són una alternativa ràpida i barata als experiments de laboratori amb humans per a estudiar els efectes en diverses variables cardiovasculars. Aquest treball veu ambdós mètodes: utilitza un model computacional per a simular diferents condicions d’estrès ortostàtic i obtenir corbes de resposta en el rang entre 0 g i 1 g. A més, es veu un enfocament experimental de la resposta cardiovascular en diversos subjectes, comparant diferents instruments de mesura.Las futuras misiones espaciales de larga duración requerirán un conocimiento profundo de los efectos de diferentes niveles de gravedad al cuerpo humano, en particular al sistema cardiovascular. Los modelos computacionales son una alternativa rápida y barata a los experimentos de laboratorio con humanos para estudiar los efectos en varias variables cardiovasculares. Este trabajo ve ambos métodos: utiliza un modelo computacional para simular diferentes condiciones de estrés ortostático y obtener curvas de respuesta en el rango entre 0 g and 1 g. Además, se ve un enfoque experimental de la respuesta cardiovascular en varios sujetos, comparando diferentes instrumentos de medida.Future long duration space missions will require a deep knowledge of the effects of different levels of gravity on the human body, in particular the cardiovascular system. Computational models can be a faster, cheaper alternative to experiments with human subjects in studying the effects in different cardiovascular variables. This research effort implements both computational and experimental approaches. It uses a computational model to simulate different orthostatic stress conditions and generate dose-response curves of different cardiovascular variables in the range between 0 g and 1 g. Moreover, an experimental approach of the cardiovascular response in various subjects is also implemented, comparing different measurement instruments.Outgoin

Electrophoretic origin of long-range repulsion of colloids near water/Nafion interfaces

The ICN2 is funded by the CERCA program/Generalitat de Catalunya.One of the most striking properties of Nafion is the formation of a long-range solute exclusion zone (EZ) in contact with water. The mechanism of formation of this EZ has been the subject of a controversial and long-standing debate. Previous studies by Schurr et al. and Florea et al. root the explanation of this phenomenon in the ion-exchange properties of Nafion, which generates ion diffusion and ion gradients that drive the repulsion of solutes by diffusiophoresis. Here we have evaluated separately the electrophoretic and chemiphoretic contributions to multi-ionic diffusiophoresis using differently charged colloidal tracers as solutes to identify better their contribution in the EZ formation. Our experimental results, which are also supported by numerical simulations, show that the electric field, built up due to the unequal diffusion coefficients of the exchanged ions, is the dominant parameter behind such interfacial phenomenon in the presence of alkali metal chlorides. The EZ formation depends on the interplay of the electric field with the zeta potential of the solute and can be additionally modulated by changing ion diffusion coefficients or adding salts. As a consequence, we show that not all solutes can be expelled from the Nafion interface and hence the EZ is not always formed. This study thus provides a more detailed description of the origin and dynamics of this phenomenon and opens the door to the rational use of this active interface for many potential applications

Superconductivity in TTF[Ni(dmit)2]2 films

We report on the observation of a superconducting transition in a fiber-like film of the TTF[Ni(dmit)2]2 phase electrodeposited on silicon substrates. Superconductivity is evidenced by a broad drop of the resistance below 0.8K under the application of a hydrostatic pressure of 7.7 kbar. Zero resistance is not reached due to the contribution of inter-fiber resistance. Superconductivity is confirmed by the application of a magnetic field perpendicular to the plane of the film. The critical field determined on the film is in agreement with that obtained in bulk single crystals

Formation of dispersive hybrid bands at an organic-metal interface

An electronic band with quasi-one dimensional dispersion is found at the interface between a monolayer of a charge-transfer complex (TTF-TCNQ) and a Au(111) surface. Combined local spectroscopy and numerical calculations show that the band results from a complex mixing of metal and molecular states. The molecular layer folds the underlying metal states and mixes with them selectively, through the TTF component, giving rise to anisotropic hybrid bands. Our results suggest that, by tuning the components of such molecular layers, the dimensionality and dispersion of organic-metal interface states can be engineered

M81 Extragalactic nova explosions

Using data from the Joan Oró telescope (located in Montsec, Catalonia) and the reference catalogue from Max Planck Institute, we will observe the evolution of different novae in the M81 galaxy. This article explains the data analysis that has been performed and comments the obtained results2020/202

Nanomechanics: A new approach for studying the mechanical properties of materials

Mitjançant l'espectroscòpia de forces atòmiques s'ha estudiat la resposta nanomecànica a la nanoindentació de la superfície més estable d'un material trencadís FCC, com és ara el MgO (100). L'expulsió del material en forma de capes demostra que la fallida trencadissa implica, de fet, l'inici de la deformació plàstica o estrès crític, i que la deformació plàstica posterior consisteix en una sèrie d'esdeveniments discrets. Es pot determinar amb precisió el mòdul de Young, E, a partir de la regió de deformació elàstica mitjançant una mecànica senzilla, atesa l'absència de dislocacions induïdes per la nanoindentació. Amb aquesta finalitat s'ha desenvolupat un nou model fisicomatemàtic, que té en compte les interaccions laterals. El valor de l'estrès crític de fricció també s'ha calculat i comentat. Com a conseqüència d'aquesta expulsió en capes, també s'ha estudiat la resposta nanomecànica de superfícies de capes primes (gruix & 1 µm) de molècules orgàniques altament orientades, ja que es tracta de materials en capes amb interaccions de tipus Van der Waals. També en aquests materials la superfície es deforma plàsticament i presenta discontinuïtats discretes en les corbes d'indentació, associades ara a les capes moleculars expulsades per l'indentador. En el cas del metall quasiunidimensional tetratiofulvalè tetracianoquinodimetà (TTFTCNQ), el valor del mòdul de Young, E & 20 GPa, coincideix amb l'obtingut per altres mètodes. En el cas de la fase ! del radical p-nitrofenil nitronil nitròxid (p-NPNN) no es disposa d'informació per a monocristalls, i el valor obtingut per a les capes primes és de E & 2 GPa.Atomic force spectroscopy was used to study the nanomechanical response to nanoindentations on the most stable face (100) of FCC brittle materials such as MgO and alkali halides. The layered expulsion of material demonstrates that brittle failure results from the critical stress brought on by plastic deformation and that plastic deformation consists of a series of discrete events. Due to the absence of indentation- induced dislocations, Young?s modulus E can be correctly estimated from the elastic deformation region using simple mechanics. A new model is developed taking into account lateral interactions. Critical shear stress is also evaluated and discussed. As a result of the layered expulsion we also studied the nanomechanical response of surfaces of highly-oriented molecular organic thin films (ca. 1 µm thickness) because these are Van der Waals layered materials. The surfaces were again found to deform plastically and there were discrete discontinuities in the indentation curves, representing the molecular layers being expelled by the penetrating tip. Here, the Hertz model is quite good at revealing the role of lateral interactions in the indentation process. For the quasi-one-dimensional metal tetrathiafulvalene tetracyanoquinodimethane (TTF-TCNQ) the value of Young?s modulus, E & 20 GPa, coincides with that obtained by other bulk methods. For the !-phase of the p-nitrophenyl nitronyl nitroxide (p-NPNN) radical, no information is available for single crystals and the estimated value obtained for the film is E & 2 GPa

Quantification of nanomechanical properties of surfaces by higher harmonic monitoring in amplitude modulated AFM imaging

Altres ajuts: the ICN2 is funded by the CERCA programme/Generalitat de Catalunya.The determination of nanomechanical properties is an intensive topic of study in several fields of nanophysics, from surface and materials science to biology. At the same time, amplitude modulation force microscopy is one of the most established techniques for nanoscale characterization. In this work, we combine these two topics and propose a method able to extract quantitative nanomechanical information from higher harmonic amplitude imaging in atomic force microscopy. With this method it is possible to discriminate between different materials in the stiffness range of 1-3 GPa, in our case thin films of PS-PMMA based block copolymers. We were able to obtain a critical lateral resolution of less than 20 nm and discriminate between materials with less than a 1 GPa difference in modulus. We show that within this stiffness range, reliable values of the Young's moduli can be obtained under usual imaging conditions and with standard dynamic AFM probes

Role of penetrability into a brush-coated surface in directed self-assembly of block copolymers

Altres ajuts: the ICN2 is funded by the CERCA programme/Generalitat de Catalunya.High-density and high-resolution line and space patterns on surfaces are obtained by directed self-assembly of lamella-forming block copolymers (BCPs) using wide-stripe chemical guiding patterns. When the width of the chemical pattern is larger than the half-pitch of the BCP, the interaction energy between each BCP domain and the surface is crucial to obtain the desired segregated film morphology. We investigate how the intermixing between BCPs and polymer brush molecules on the surface influences the optimal surface and interface free energies to obtain a proper BCP alignment. We have found that computational models successfully predict the experimentally obtained guided patterns if the penetrability of the brush layer is taken into account instead of a hard, impenetrable surface. Experiments on directed self-assembly of lamella-forming poly(styrene-block-methyl methacrylate) using chemical guiding patterns corroborate the models used in the simulations, where the values of the surface free energy between the BCP and the guiding and background stripes are accurately determined using an experimental method based on the characterization of contact angles in droplets formed after dewetting of homopolymer blends