Implementació de cursos d'Electrònica i Tècniques de Microscòpia en modalitat docent semipresencial amb estratègies de treball cooperatiu i avaluació continuada en entorn de programari lliure Moodle

L’objectiu principal del present projecte MQD és la implementació de cursos semipresencials en el campus virtual MOODLE per a la docència de les assignatures d’Electrònica troncals de l’ensenyament de Física que depenen del nostre departament i de l’assignatura Tècniques de Microscòpia, que és optativa i comuna als Màsters de Nanociència i Nanotecnologia i d’Enginyeria Física. Plantegem metodologies docents basades en: (1) reduir la presencialitat, (2) afavorir l'autoaprenentatge, (3) aplicar estratègies d’avaluació formativa i avaluació acreditativa continuada i (4) fer ús de les TIC com a suport a la docència. La versatilitat de la plataforma Moodle per compartir recursos permetrà generar un material docent accessible per altres professors. D’altra banda, la possibilitat de Moodle per a la gestió de grups, organització i revisió de tasques facilitarà el seguiment de l’activitat d’autoaprenentatge i de treball cooperatiu així com de l’avaluació final dels aprenentatges. Durant la duració d'aquest projecte MQD s'han implementat els segúents entorns: - Curs d'Electrònica Física, semipresencial, amb treball cooperatiu i amb implantació d'avaluació continuada - Entorn de Coordinació del Master de Nanociència i Nanotecnologia - Curs de l'assignatura optativa de Màster Oficial de Nanociència i Nanotecnologia "Tècniques de Microscòpia"

The Nonequilibrium thermodynamics of small systems

The interactions of tiny objects with their environments are dominated by thermal fluctuations. Guided by theory and assisted by new micromanipulation tools, scientists have begun to study such interactions in detail.

Bicelles: new nano systems for skin applications

Bicellar systems are lipid nanostructures formed by long- and short-chained phospholipids dispersed in aqueoussolution. Because of their attractive combination of lipid composition, small size and morphological versatility, bicellesbecame new targets for skin research. Bicelles modify the skin biophysical parameters and modulate the skin barrier function acting as enhancers for drug penetration. Moreover, these aggregates have the ability to penetrate through the narrowintercellular spaces of the skin stratum corneum and to reinforce its lipid lamellae. Their structures allows for the incorporation of different molecules that can be carried through the skin layers. Theremarkable versatility of bicelles is their most important characteristic, which makes it possible their use in different fields.These aggregates represent new nanosystems for skin applications. In this work we provide an overview of the main properties ofbicelles and their effects on the skin.

Electron energy loss spectroscopy: physical principles, state of the art and applications to the nanosciences

In the present work we review the way in which the electron-matter interaction allows us to perform electron energy loss spectroscopy (EELS), as well as the latest developments in the technique and some of the most relevant results of EELS as a characterization tool in nanoscience and nanotechnology.

Effective Electrodiffusion equation for non uniform nanochannels

We derive a one dimensional formulation of the Planck-Nernst-Poisson equation to describe the dynamics of of a symmetric binary electrolyte in channels whose section is of nanometric section and varies along the axial direction. The approach is in the spirit of the Fick-Jacobs di fusion equation and leads to a system of coupled equations for the partial densities which depends on the charge sitting at the walls in a non trivial fashion. We consider two kinds of non uniformities, those due to the spatial variation of charge distribution and those due to the shape variation of the pore and report one and three-dimensional solutions of the electrokinetic equations.

Supramolecular chemistry for nanomedicine

Mimicking Nature, supramolecular chemistry represents the chemistry beyond the molecule, in view that intermolecularinteractions constitute the driving force for the preparation of molecular and supramolecular assemblies, using the chemicalinformation contained in molecular building blocks. Upon molecular recognition between discrete units, chemical processessuch as self-assembly and self-organisation start operating, and are the leading processes to build up supramolecular aggregates and materials. When those materials have dimensions on thenanometric scale, a recently emerging scientific discipline is defined,Nanoscience. Nanomaterials are promising tools for many applications, and their use in biomedical and clinical applicationsdefines the so-called Nanomedicine. In this review we present a few selected examples of nanomaterials designed for therapeutical purposes, emphasizing the importance of the preparation methodology in terms of their therapeutical use.