Project acronym INVISIBLE
Project Advanced Amorphous Multicomponent Oxides for Transparent Electronics
Researcher (PI) Elvira Fortunato
Host Institution (HI) FACULDADE DE CIENCIAS E TECNOLOGIADA UNIVERSIDADE NOVA DE LISBOA
Country Portugal
Call Details Advanced Grant (AdG), PE8, ERC-2008-AdG
Summary Imagine having a fully transparent and flexible, foldable, low cost, displays or at the glass window of your home/office, a transparent electronic circuit, do you believe on that? Maybe you are asking me if I am writing science fiction. No I am not. In fact this is a very ambitious objective but is tangible in the framework of this project due to the already acquired experience in the development of transparent thin film transistors using novel multifunctional and multicomponent oxides that can behave as active or passive semiconductor materials. This is an interdisciplinary research project aiming to develop a new class of transparent electronic components, based on multicomponent passive and active oxide semiconductors (n and p-types), to fabricate the novel generation of full transparent electronic devices and circuits, either using rigid or flexible substrates. The emphasis will be put on developing thin film transistors (n and p-TFTs) and integrated circuits for a broad range of applications (from inverters, C-MOS like devices, ring oscillators, CCDs backplanes for active matrices, biossensor arrays for DNA/RNA/proteins detection), boosting to its maximum their electronic performances for next generation of invisible circuits. By doing so, we are contributing for generating a free real state electronics that is able to add new electronic functionalities onto surfaces, which currently are not used in this manner and that silicon cannot contribute. The multicomponent metal oxide materials to be developed will exhibit (mainly) an amorphous or a nanocomposite structure and will be processed by PVD techniques like rf magnetron sputtering at room temperature, compatible with the use of low cost and flexible substrates (polymers, cellulose paper, among others). These will facilitate a migration away from tradition silicon like fab based batch processing to large area, roll to roll manufacturing technology which will offer significant advantages
Summary
Imagine having a fully transparent and flexible, foldable, low cost, displays or at the glass window of your home/office, a transparent electronic circuit, do you believe on that? Maybe you are asking me if I am writing science fiction. No I am not. In fact this is a very ambitious objective but is tangible in the framework of this project due to the already acquired experience in the development of transparent thin film transistors using novel multifunctional and multicomponent oxides that can behave as active or passive semiconductor materials. This is an interdisciplinary research project aiming to develop a new class of transparent electronic components, based on multicomponent passive and active oxide semiconductors (n and p-types), to fabricate the novel generation of full transparent electronic devices and circuits, either using rigid or flexible substrates. The emphasis will be put on developing thin film transistors (n and p-TFTs) and integrated circuits for a broad range of applications (from inverters, C-MOS like devices, ring oscillators, CCDs backplanes for active matrices, biossensor arrays for DNA/RNA/proteins detection), boosting to its maximum their electronic performances for next generation of invisible circuits. By doing so, we are contributing for generating a free real state electronics that is able to add new electronic functionalities onto surfaces, which currently are not used in this manner and that silicon cannot contribute. The multicomponent metal oxide materials to be developed will exhibit (mainly) an amorphous or a nanocomposite structure and will be processed by PVD techniques like rf magnetron sputtering at room temperature, compatible with the use of low cost and flexible substrates (polymers, cellulose paper, among others). These will facilitate a migration away from tradition silicon like fab based batch processing to large area, roll to roll manufacturing technology which will offer significant advantages
Max ERC Funding
2 250 000 €
Duration
Start date: 2009-01-01, End date: 2014-12-31
Project acronym VIN
Project Video-rate Scanning Probe Microscopy Imaging of Nanostructures on Surfaces
Researcher (PI) Flemming Besenbacher
Host Institution (HI) AARHUS UNIVERSITET
Country Denmark
Call Details Advanced Grant (AdG), PE4, ERC-2008-AdG
Summary The goal of this ERC proposal VIN is to develop the next generation of scanning probe microscopes (SPMs) The microscopes will set new standards in the field through their ability to acquire images at video-rate frequency, while retaining high (atomic) resolution capability. This new instrumental platform will be implemented both under ultra-high vacuum conditions, in a high-pressure gas cell, and under liquid-phase conditions. It will be utilized to create and explore novel research avenues for the study of physical, chemical, and biological surface processes at the single-atom/molecule level with the highest possible spatial and temporal resolution. In particular I will study dynamic phenomena in surface nanostructures, focusing on three mutually synergetic and interdisciplinary priority areas: i) Catalytic reactivity of nanostructures, ii) Self-organisation of organic molecules at surfaces, iii) Biomolecular structures, processes and interactions under physiological conditions. The adsorption, diffusion and interaction of molecules are the basic steps involved in reactions at surfaces. All of them are dynamic processes, where high temporal resolution can provide new groundbreaking insight into e.g. the mechanisms underlying catalysis. Video-rate SPMs will also facilitate investigations of the kinetic aspects of molecular self- organisation at surfaces such as diffusion, intra-molecular conformational dynamics, nucleation and growth of structures. The effort will build upon the world-leading expertise in design, construction and use of SPMs in my research group at the Interdisciplinary Nanoscience Center (iNANO) and the Department of Physics and Astronomy, University of Aarhus, Denmark. To achieve the ambitious research goals, I will bring together an interdisciplinary team of highly talented younger scientists.
Summary
The goal of this ERC proposal VIN is to develop the next generation of scanning probe microscopes (SPMs) The microscopes will set new standards in the field through their ability to acquire images at video-rate frequency, while retaining high (atomic) resolution capability. This new instrumental platform will be implemented both under ultra-high vacuum conditions, in a high-pressure gas cell, and under liquid-phase conditions. It will be utilized to create and explore novel research avenues for the study of physical, chemical, and biological surface processes at the single-atom/molecule level with the highest possible spatial and temporal resolution. In particular I will study dynamic phenomena in surface nanostructures, focusing on three mutually synergetic and interdisciplinary priority areas: i) Catalytic reactivity of nanostructures, ii) Self-organisation of organic molecules at surfaces, iii) Biomolecular structures, processes and interactions under physiological conditions. The adsorption, diffusion and interaction of molecules are the basic steps involved in reactions at surfaces. All of them are dynamic processes, where high temporal resolution can provide new groundbreaking insight into e.g. the mechanisms underlying catalysis. Video-rate SPMs will also facilitate investigations of the kinetic aspects of molecular self- organisation at surfaces such as diffusion, intra-molecular conformational dynamics, nucleation and growth of structures. The effort will build upon the world-leading expertise in design, construction and use of SPMs in my research group at the Interdisciplinary Nanoscience Center (iNANO) and the Department of Physics and Astronomy, University of Aarhus, Denmark. To achieve the ambitious research goals, I will bring together an interdisciplinary team of highly talented younger scientists.
Max ERC Funding
1 324 983 €
Duration
Start date: 2008-12-01, End date: 2013-11-30
