In this paper, we report on a method to reduce thin films of graphene oxide (GO) to a spatial resolution better than 100 nm over several tens of micrometers by means of an electrochemical scanning probe based lithography.

A photonic lab on a chip (PhLOC), comprising a solid-state light emitter (SSLE) aligned with a biofunctionalized optofluidic multiple internal reflection (MIR) system, is presented.

This work reports on the thermal influence of an LED (Light Emitting Diode) driver on a retrofit LED lamp, also reporting on a procedure for its thermal characterization and multi-scale modeling to optimise its integration.

We report on the production of a low cost microfluidic device for the multiplexed electrochemical detection of magneto bioassays. As a proof of concept, the device has been used to detect Myeloperoxidase (MPO), a cardiovascular biomarker.

The adhesion of small silicon chips to cells has many potential applications as direct interconnection of the cells to the external world can be accomplished.

The presence of lattice defects in graphene might degrade its mechanical properties. We report a study on the elastic modulus and strength with a controlled density of defects.

Taking advantage of the ability of microelectronics to manufacture devices under cell dimensions and a large variety of features, we report a technology for the fabrication of multi-material chips as bi-functional cell-internalizable devices.

by Jean-Christophe Crebier, CNRS-G2ELab.

Les activitats de recerca de l'IMB-CNM estan dedicades als sistemes integrats micro i nanoelectrònics: sistemes electrònics miniaturitzats que inclouen capacitats de detecció i/o actuació, a més de processament d’informació electrònica, gestió d’energia i interfícies externes.

The research activities of IMB-CNM are dedicated to Micro/Nano Integrated Systems: miniaturized electronic systems which include sensing and/or actuating capabilities in addition to electronic information processing, power management and external interfaces.