Project acronym ATLAS
Project Bioengineered autonomous cell-biomaterials devices for generating humanised micro-tissues for regenerative medicine
Researcher (PI) João Felipe Colardelle da Luz Mano
Host Institution (HI) UNIVERSIDADE DE AVEIRO
Call Details Advanced Grant (AdG), PE8, ERC-2014-ADG
Summary New generations of devices for tissue engineering (TE) should rationalize better the physical and biochemical cues operating in tandem during native regeneration, in particular at the scale/organizational-level of the stem cell niche. The understanding and the deconstruction of these factors (e.g. multiple cell types exchanging both paracrine and direct signals, structural and chemical arrangement of the extra-cellular matrix, mechanical signals…) should be then incorporated into the design of truly biomimetic biomaterials. ATLAS proposes rather unique toolboxes combining smart biomaterials and cells for the ground-breaking advances of engineering fully time-self-regulated complex 2D and 3D devices, able to adjust the cascade of processes leading to faster high-quality new tissue formation with minimum pre-processing of cells. Versatile biomaterials based on marine-origin macromolecules will be used, namely in the supramolecular assembly of instructive multilayers as nanostratified building-blocks for engineer such structures. The backbone of these biopolymers will be equipped with a variety of (bio)chemical elements permitting: post-processing chemistry and micro-patterning, specific/non-specific cell attachment, and cell-controlled degradation. Aiming at being applied in bone TE, ATLAS will integrate cells from different units of tissue physiology, namely bone and hematopoietic basic elements and consider the interactions between the immune and skeletal systems. These ingredients will permit to architect innovative films with high-level dialogue control with cells, but in particular sophisticated quasi-closed 3D capsules able to compartmentalise such components in a “globe-like” organization, providing local and long-range order for in vitro microtissue development and function. Such hybrid devices could be used in more generalised front-edge applications, including as disease models for drug discovery or test new therapies in vitro.
Summary
New generations of devices for tissue engineering (TE) should rationalize better the physical and biochemical cues operating in tandem during native regeneration, in particular at the scale/organizational-level of the stem cell niche. The understanding and the deconstruction of these factors (e.g. multiple cell types exchanging both paracrine and direct signals, structural and chemical arrangement of the extra-cellular matrix, mechanical signals…) should be then incorporated into the design of truly biomimetic biomaterials. ATLAS proposes rather unique toolboxes combining smart biomaterials and cells for the ground-breaking advances of engineering fully time-self-regulated complex 2D and 3D devices, able to adjust the cascade of processes leading to faster high-quality new tissue formation with minimum pre-processing of cells. Versatile biomaterials based on marine-origin macromolecules will be used, namely in the supramolecular assembly of instructive multilayers as nanostratified building-blocks for engineer such structures. The backbone of these biopolymers will be equipped with a variety of (bio)chemical elements permitting: post-processing chemistry and micro-patterning, specific/non-specific cell attachment, and cell-controlled degradation. Aiming at being applied in bone TE, ATLAS will integrate cells from different units of tissue physiology, namely bone and hematopoietic basic elements and consider the interactions between the immune and skeletal systems. These ingredients will permit to architect innovative films with high-level dialogue control with cells, but in particular sophisticated quasi-closed 3D capsules able to compartmentalise such components in a “globe-like” organization, providing local and long-range order for in vitro microtissue development and function. Such hybrid devices could be used in more generalised front-edge applications, including as disease models for drug discovery or test new therapies in vitro.
Max ERC Funding
2 498 988 €
Duration
Start date: 2015-12-01, End date: 2020-11-30
Project acronym BIFLOW
Project Bilingualism in Florentine and Tuscan Works (ca. 1260 - ca. 1416)
Researcher (PI) Antonio Montefusco
Host Institution (HI) UNIVERSITA CA' FOSCARI VENEZIA
Call Details Starting Grant (StG), SH5, ERC-2014-STG
Summary This project will undertake the first systematic investigation of the various literary documents that circulated simultaneously in more than one language in Tuscany, and especially Florence, between the mid-13th Century and the beginning of 15th Century.
During that period, Florence was both a prominent literary centre in the vernacular, and home to a renewal of classical Latin eloquence. While both fields are well studied, their interaction remains largely unexplored. This research, at the convergence of several disciplines (literature, philology, linguistics and medieval history), has a strong pioneering character. It aims at changing the perception of medieval Italian culture and interpretation of the break between medieval Culture and Humanism.
For this reason, the project will develop research in varying degrees of depth. First, it will provide the first catalogue of bilingual texts and manuscripts of medieval Tuscany. Organized as a database, this tool of analysis will stir innovative research in this field, some of which will be immediately promoted during the project.
Secondly, two case studies, considered as important and methodologically exemplary, will be researched in detail, through the publication of two important set of texts, of secular and religious nature : 1. The vernacular translation of the Latin Epistles of Dante Alighieri; 2. A collection of polemical, historiographical, devotional and prophetical documents produced by the Tuscan dissident Franciscans in last decades of the 14th Century.
Finally, the entire team, led by the PI, will be involved in the preparation of a synthesis volume on Tuscan culture in the fourteenth century viewed through bilingualism, entitled Cartography of bilingual culture in Fourteenth-Century Tuscany. From this general map of the Italian culture of the time, no literary genre nor field (be it religious or lay) shall be excluded.
Summary
This project will undertake the first systematic investigation of the various literary documents that circulated simultaneously in more than one language in Tuscany, and especially Florence, between the mid-13th Century and the beginning of 15th Century.
During that period, Florence was both a prominent literary centre in the vernacular, and home to a renewal of classical Latin eloquence. While both fields are well studied, their interaction remains largely unexplored. This research, at the convergence of several disciplines (literature, philology, linguistics and medieval history), has a strong pioneering character. It aims at changing the perception of medieval Italian culture and interpretation of the break between medieval Culture and Humanism.
For this reason, the project will develop research in varying degrees of depth. First, it will provide the first catalogue of bilingual texts and manuscripts of medieval Tuscany. Organized as a database, this tool of analysis will stir innovative research in this field, some of which will be immediately promoted during the project.
Secondly, two case studies, considered as important and methodologically exemplary, will be researched in detail, through the publication of two important set of texts, of secular and religious nature : 1. The vernacular translation of the Latin Epistles of Dante Alighieri; 2. A collection of polemical, historiographical, devotional and prophetical documents produced by the Tuscan dissident Franciscans in last decades of the 14th Century.
Finally, the entire team, led by the PI, will be involved in the preparation of a synthesis volume on Tuscan culture in the fourteenth century viewed through bilingualism, entitled Cartography of bilingual culture in Fourteenth-Century Tuscany. From this general map of the Italian culture of the time, no literary genre nor field (be it religious or lay) shall be excluded.
Max ERC Funding
1 480 625 €
Duration
Start date: 2015-10-01, End date: 2020-09-30
Project acronym CapTherPV
Project Integration of Capacitor, Thermoelectric and PhotoVoltaic thin films for efficient energy conversion and storage
Researcher (PI) Isabel Maria Das Merces Ferreira
Host Institution (HI) NOVA ID FCT - ASSOCIACAO PARA A INOVACAO E DESENVOLVIMENTO DA FCT
Call Details Consolidator Grant (CoG), PE8, ERC-2014-CoG
Summary The possibility of having a unique device that converts thermal and photonics energy into electrical energy and simultaneously stores it, is something dreamed by the PI since the beginning of her research career. To achieve that goal, this project aims to gather, in a single substrate, solar cells with up-conversion nanoparticles, thermoelectrics and graphene super-capacitor, all made of thin films. These three main components will be developed separately and integrated sequentially. The innovation proposed is not limited to the integration of components, but rely in ground-breaking concepts: 1) thermoelectric elements based on thin film (TE-TF) oxides; 2) plasmonic nanoparticles for up conversion of near infrared radiation to visible emission in solar cells; 3) graphene super-capacitors; 4) integration and optimization of all components in a single CapTherPV device. This ambitious project will bring new insights at large area, low cost and flexible energy harvesting and comes from an old idea of combining energy conversion and storage that has been pursued by the PI. She started her career in amorphous silicon thin film solar cells, later she started the development of thin film batteries and more recently started a research line in thermoelectric films. If approved, this project will give financial support to consolidate the research being carried out and will give independence to the PI in terms of resources and creative think. More importantly, will facilitate the concretization of the dream that has been pursued with hard work.
Summary
The possibility of having a unique device that converts thermal and photonics energy into electrical energy and simultaneously stores it, is something dreamed by the PI since the beginning of her research career. To achieve that goal, this project aims to gather, in a single substrate, solar cells with up-conversion nanoparticles, thermoelectrics and graphene super-capacitor, all made of thin films. These three main components will be developed separately and integrated sequentially. The innovation proposed is not limited to the integration of components, but rely in ground-breaking concepts: 1) thermoelectric elements based on thin film (TE-TF) oxides; 2) plasmonic nanoparticles for up conversion of near infrared radiation to visible emission in solar cells; 3) graphene super-capacitors; 4) integration and optimization of all components in a single CapTherPV device. This ambitious project will bring new insights at large area, low cost and flexible energy harvesting and comes from an old idea of combining energy conversion and storage that has been pursued by the PI. She started her career in amorphous silicon thin film solar cells, later she started the development of thin film batteries and more recently started a research line in thermoelectric films. If approved, this project will give financial support to consolidate the research being carried out and will give independence to the PI in terms of resources and creative think. More importantly, will facilitate the concretization of the dream that has been pursued with hard work.
Max ERC Funding
1 999 375 €
Duration
Start date: 2015-07-01, End date: 2020-06-30
Project acronym ENSURE
Project Exploring the New Science and engineering unveiled by Ultraintense ultrashort Radiation interaction with mattEr
Researcher (PI) Matteo Passoni
Host Institution (HI) POLITECNICO DI MILANO
Call Details Consolidator Grant (CoG), PE8, ERC-2014-CoG
Summary With the ENSURE project I aim at attaining ground-breaking results in the field of superintense laser-driven ion acceleration, proposing a multidisciplinary research program in which theoretical, numerical and experimental research will be coherently developed in a team integrating in an unprecedented way advanced expertise from materials engineering and nanotechnology, laser-plasma physics, computational science. The aim will be to bring this topic from the realm of fundamental basic science into a subject having realistic engineering applications.
The discovery in 2000 of brilliant, multi-MeV, collimated ion sources from targets irradiated by intense laser pulses stimulated great interest worldwide, due to the ultra-compact spatial scale of the accelerator and ion beam properties. The laser-target system provides unique appealing features to fundamental physics which can be studied in a small lab. At the same time, laser-ion beams could have future potential in many technological areas. This is boosting the development of new labs and facilities all over Europe, but to support these efforts, crucial challenges need to be faced to make these applications a reality.
The goals of ENSURE are: i) design and production of nanoengineered targets, with properties tailored to achieve optimized ion acceleration regimes. This will be pursued exploiting advanced techniques of material science & nanotechnology ii) design of laser-ion beams for novel, key applications in nuclear and materials engineering iii) realization of engineering-oriented ion acceleration experiments, in advanced facilities iv) synergic development of all the required theoretical support for i,ii,iii).
The results of the project can determine a unique impact in the research on laser-driven ion acceleration in Europe, providing new directions to support the attainment, in the next future, of concrete applications of great societal relevance, in medical, energy and materials areas.
Summary
With the ENSURE project I aim at attaining ground-breaking results in the field of superintense laser-driven ion acceleration, proposing a multidisciplinary research program in which theoretical, numerical and experimental research will be coherently developed in a team integrating in an unprecedented way advanced expertise from materials engineering and nanotechnology, laser-plasma physics, computational science. The aim will be to bring this topic from the realm of fundamental basic science into a subject having realistic engineering applications.
The discovery in 2000 of brilliant, multi-MeV, collimated ion sources from targets irradiated by intense laser pulses stimulated great interest worldwide, due to the ultra-compact spatial scale of the accelerator and ion beam properties. The laser-target system provides unique appealing features to fundamental physics which can be studied in a small lab. At the same time, laser-ion beams could have future potential in many technological areas. This is boosting the development of new labs and facilities all over Europe, but to support these efforts, crucial challenges need to be faced to make these applications a reality.
The goals of ENSURE are: i) design and production of nanoengineered targets, with properties tailored to achieve optimized ion acceleration regimes. This will be pursued exploiting advanced techniques of material science & nanotechnology ii) design of laser-ion beams for novel, key applications in nuclear and materials engineering iii) realization of engineering-oriented ion acceleration experiments, in advanced facilities iv) synergic development of all the required theoretical support for i,ii,iii).
The results of the project can determine a unique impact in the research on laser-driven ion acceleration in Europe, providing new directions to support the attainment, in the next future, of concrete applications of great societal relevance, in medical, energy and materials areas.
Max ERC Funding
1 887 500 €
Duration
Start date: 2015-09-01, End date: 2020-08-31
Project acronym HEROIC
Project High-frequency printed and direct-written Organic-hybrid Integrated Circuits
Researcher (PI) Mario Caironi
Host Institution (HI) FONDAZIONE ISTITUTO ITALIANO DI TECNOLOGIA
Call Details Starting Grant (StG), PE7, ERC-2014-STG
Summary The HEROIC project aims at filling the gap between the currently low operation frequencies of printed, organic flexible electronics and the high-frequency regime, by demonstrating polymer-based field-effect transistors with maximum operation frequencies of 1 GHz and complementary integrated logic circuits switching in the 10-100 MHz range, fabricated by means of printing and direct-writing scalable processes in order to retain low temperature manufacturability of cost-effective large area electronics on plastic. The recent development of semiconducting polymers with mobilities in the range of 1 to 10 cm^2/Vs, and even higher in the case of aligned films, suggests that suitably downscaled printed polymer transistors with operation frequencies in the GHz regime, at least three orders of magnitude higher than current printed polymer devices, are achievable, by addressing in a holistic approach the specific challenges set in the HEROIC trans-disciplinary research programme: (i)development of scalable high resolution processes for the patterning of functional inks, where printing will be combined with direct-writing techniques such as fs-laser machining, both in an additive and subtractive approach; (ii)development of printable nanoscale hybrid dielectrics with high specific capacitance, where low-k polymer buffer materials will be combined with solution processable high-k dielectrics, such as insulating metal oxides; (iii)improvement of the control of charge injection and transport in printed polymer and hybrid semiconductors, where high-mobility 1-D and 2-D structures are included in polymer films; (iv)development of advanced printed and direct-written transistors architectures with low parasitic capacitances for high-speed operation. HEROIC will radically advance and expand the applicability of polymer-based printed electronics, thus making it suitable for next generation portable and wearable short-range wireless communicating devices with low power consumption.
Summary
The HEROIC project aims at filling the gap between the currently low operation frequencies of printed, organic flexible electronics and the high-frequency regime, by demonstrating polymer-based field-effect transistors with maximum operation frequencies of 1 GHz and complementary integrated logic circuits switching in the 10-100 MHz range, fabricated by means of printing and direct-writing scalable processes in order to retain low temperature manufacturability of cost-effective large area electronics on plastic. The recent development of semiconducting polymers with mobilities in the range of 1 to 10 cm^2/Vs, and even higher in the case of aligned films, suggests that suitably downscaled printed polymer transistors with operation frequencies in the GHz regime, at least three orders of magnitude higher than current printed polymer devices, are achievable, by addressing in a holistic approach the specific challenges set in the HEROIC trans-disciplinary research programme: (i)development of scalable high resolution processes for the patterning of functional inks, where printing will be combined with direct-writing techniques such as fs-laser machining, both in an additive and subtractive approach; (ii)development of printable nanoscale hybrid dielectrics with high specific capacitance, where low-k polymer buffer materials will be combined with solution processable high-k dielectrics, such as insulating metal oxides; (iii)improvement of the control of charge injection and transport in printed polymer and hybrid semiconductors, where high-mobility 1-D and 2-D structures are included in polymer films; (iv)development of advanced printed and direct-written transistors architectures with low parasitic capacitances for high-speed operation. HEROIC will radically advance and expand the applicability of polymer-based printed electronics, thus making it suitable for next generation portable and wearable short-range wireless communicating devices with low power consumption.
Max ERC Funding
1 608 125 €
Duration
Start date: 2015-04-01, End date: 2020-03-31
Project acronym IDEal reSCUE
Project Integrated DEsign and control of Sustainable CommUnities during Emergencies
Researcher (PI) Gian Paolo Cimellaro
Host Institution (HI) POLITECNICO DI TORINO
Call Details Starting Grant (StG), PE8, ERC-2014-STG
Summary Integrated DEsign and control of Sustainable CommUnities during Emergencies
Summary
Integrated DEsign and control of Sustainable CommUnities during Emergencies
Max ERC Funding
1 271 138 €
Duration
Start date: 2015-11-01, End date: 2020-10-31
Project acronym INTHERM
Project Design, manufacturing and control of INterfaces in THERMally conductive polymer nanocomposites
Researcher (PI) Alberto Fina
Host Institution (HI) POLITECNICO DI TORINO
Call Details Starting Grant (StG), PE8, ERC-2014-STG
Summary This proposal addresses the design, manufacturing and control of interfaces in thermally conductive polymer/graphene nanocomposites.
In particular, the strong reduction of thermal resistance associated to the contacts between conductive particles in a percolating network throughout the polymer matrix is targeted, to overcome the present bottleneck for heat transfer in nanocomposites.
The project includes the investigation of novel chemical modifications of nanoparticles to behave as thermal bridges between adjacent particles, advanced characterization methods for particle/particle interfaces and controlled processing methods for the preparations of nanocomposites with superior thermal conductivity.
The results of this project will contribute to the fundamental understanding of heat transfer in complex solids, while success in mastering interfacial properties would open the way to a new generation of advanced materials coupling high thermal conductivity with low density, ease of processing, toughness and corrosion resistance.
Summary
This proposal addresses the design, manufacturing and control of interfaces in thermally conductive polymer/graphene nanocomposites.
In particular, the strong reduction of thermal resistance associated to the contacts between conductive particles in a percolating network throughout the polymer matrix is targeted, to overcome the present bottleneck for heat transfer in nanocomposites.
The project includes the investigation of novel chemical modifications of nanoparticles to behave as thermal bridges between adjacent particles, advanced characterization methods for particle/particle interfaces and controlled processing methods for the preparations of nanocomposites with superior thermal conductivity.
The results of this project will contribute to the fundamental understanding of heat transfer in complex solids, while success in mastering interfacial properties would open the way to a new generation of advanced materials coupling high thermal conductivity with low density, ease of processing, toughness and corrosion resistance.
Max ERC Funding
1 404 132 €
Duration
Start date: 2015-03-01, End date: 2020-02-29
Project acronym Learn
Project Learning From Failing and Passing Executions At the Speed of Internet
Researcher (PI) Leonardo Mariani
Host Institution (HI) UNIVERSITA' DEGLI STUDI DI MILANO-BICOCCA
Call Details Consolidator Grant (CoG), PE6, ERC-2014-CoG
Summary Modern software systems must be extremely flexible and easily adaptable to different user needs and environments. However, this flexibility also introduces relevant quality issues. These problems are so common that is sufficient browsing the Web to find millions of reports about failures observed after updates and incompatibilities caused by the interaction of a newly installed component with the existing components.
The impact of problems introduced by end-users can be dramatic because end-users can easily modify applications, like developers do, but end-users have neither the knowledge nor the skill of developers, and they cannot debug and fix the problems that they unintentionally introduce. It is thus necessary to timely develop novel solutions that can increase the reliability of the moderns systems, which can be extended and adapted by end-users, with the capability to automatically address problems that are unknown at development-time.
The Learn project aims to produce innovative solutions for the development of systems that can work around the problems introduced by end-users when modifying their applications. The three key elements introduced by Learn to automatically produce a (temporary) fix for the software are: (1) the definition of the InternetLearn infrastructure, which is a network infrastructure that enables communication between every individual instance of a same program running at different end-users’ sites, thus augmenting each application with the capability to access a huge amount of information collected in-the-field from other sites; (2) the definition of analysis techniques that can learn the characteristics of successful and failed runs by monitoring executions in the field from a number of instances running at many end-user sites; and (3) the definition of techniques for the automatic generation and actuation of temporary fixes on an Internet (World) scale.
Summary
Modern software systems must be extremely flexible and easily adaptable to different user needs and environments. However, this flexibility also introduces relevant quality issues. These problems are so common that is sufficient browsing the Web to find millions of reports about failures observed after updates and incompatibilities caused by the interaction of a newly installed component with the existing components.
The impact of problems introduced by end-users can be dramatic because end-users can easily modify applications, like developers do, but end-users have neither the knowledge nor the skill of developers, and they cannot debug and fix the problems that they unintentionally introduce. It is thus necessary to timely develop novel solutions that can increase the reliability of the moderns systems, which can be extended and adapted by end-users, with the capability to automatically address problems that are unknown at development-time.
The Learn project aims to produce innovative solutions for the development of systems that can work around the problems introduced by end-users when modifying their applications. The three key elements introduced by Learn to automatically produce a (temporary) fix for the software are: (1) the definition of the InternetLearn infrastructure, which is a network infrastructure that enables communication between every individual instance of a same program running at different end-users’ sites, thus augmenting each application with the capability to access a huge amount of information collected in-the-field from other sites; (2) the definition of analysis techniques that can learn the characteristics of successful and failed runs by monitoring executions in the field from a number of instances running at many end-user sites; and (3) the definition of techniques for the automatic generation and actuation of temporary fixes on an Internet (World) scale.
Max ERC Funding
1 141 875 €
Duration
Start date: 2015-10-01, End date: 2019-09-30
Project acronym MEMOIRS
Project Children of Empires and European Postmemories
Researcher (PI) Maria Margarida DE SA CALAFATE RIBEIRO
Host Institution (HI) CENTRO DE ESTUDOS SOCIAIS
Call Details Consolidator Grant (CoG), SH5, ERC-2014-CoG
Summary MEMOIRS focuses on the intergenerational memories of the children and grandchildren of those involved in the decolonization processes of colonies held by France, Portugal and Belgium. Through interviews of this second and third generation, and a comparative analysis of the cultures influenced by the postmemory of the colonial wars and the end of empire, Europe's postcolonial heritage will be reinterrogated, and a new understanding of the contemporary continent will be developed. At the heart of the project is a desire to comprehend the effects of Europe's postimperial diversity through postmemories of colonial praxis.
The project is interdisciplinary, bringing together specialists from literary and cultural studies, history, sociology and migration studies. MEMOIRS aims to maximize the impact of its findings through broad web, open-access publications and an itinerant artistic exhibit that captures multiple aspects of the representations of postmemory, and fosters a meaningful North-South dialogue.
Summary
MEMOIRS focuses on the intergenerational memories of the children and grandchildren of those involved in the decolonization processes of colonies held by France, Portugal and Belgium. Through interviews of this second and third generation, and a comparative analysis of the cultures influenced by the postmemory of the colonial wars and the end of empire, Europe's postcolonial heritage will be reinterrogated, and a new understanding of the contemporary continent will be developed. At the heart of the project is a desire to comprehend the effects of Europe's postimperial diversity through postmemories of colonial praxis.
The project is interdisciplinary, bringing together specialists from literary and cultural studies, history, sociology and migration studies. MEMOIRS aims to maximize the impact of its findings through broad web, open-access publications and an itinerant artistic exhibit that captures multiple aspects of the representations of postmemory, and fosters a meaningful North-South dialogue.
Max ERC Funding
1 982 475 €
Duration
Start date: 2015-11-01, End date: 2020-10-31
Project acronym NEW_FUN
Project New era of printed paper electronics based on advanced functional cellulose
Researcher (PI) Luis Miguel Nunes Pereira
Host Institution (HI) NOVA ID FCT - ASSOCIACAO PARA A INOVACAO E DESENVOLVIMENTO DA FCT
Call Details Starting Grant (StG), PE8, ERC-2014-STG
Summary Fully recyclable and low cost electronic goods are still far from reality. My interest is in creating environmental friendly advanced functional materials and processes able to result in new class of paper based electronic products. This represents a reborn of the paper millenary industry for a plethora of low cost, recyclable and disposable electronics, putting Europe in the front line of a new era of consumer electronics.
While the vision of the proposal is a very ambitious one, my ground-breaking research work to date related with oxide based transistors on paper (from which I am one of the co-inventors) has contributed to the basic technological breakthroughs needed to create the key elements to establish a new era of paper electronics. Field effect transistors (FETs), memory and CMOS devices, with excellent electronic performance and using paper as substrate and dielectric have resulted from my recent work. What I am proposing now is to reinvent the concept of paper electronics. In NEW_FUN I want to develop a completely new and disruptive approach where functionalized cellulose fibers will be used not only as dielectric but also as semiconductor and conductor able to coexist in a multilayer paper structure. That is, assembling paper that can have different functionalities locally, on each face or even along its entire thickness/bulk. This way issues such as failure under bending, mechanical robustness and stability can be minimized. Doing so, electronic and electrochemical devices can be produced not only on paper but also from paper. The outputs of NEW_FUN will open the door to turn paper into a real electronic material making possible disposable/recyclable electronic products, such as smart labels/packages (e.g. food and medicine industry), sensors for air quality control (car, house and industry environments); disposable electronic devices such as bio-detection platforms, lab-on-paper systems, among others.
Summary
Fully recyclable and low cost electronic goods are still far from reality. My interest is in creating environmental friendly advanced functional materials and processes able to result in new class of paper based electronic products. This represents a reborn of the paper millenary industry for a plethora of low cost, recyclable and disposable electronics, putting Europe in the front line of a new era of consumer electronics.
While the vision of the proposal is a very ambitious one, my ground-breaking research work to date related with oxide based transistors on paper (from which I am one of the co-inventors) has contributed to the basic technological breakthroughs needed to create the key elements to establish a new era of paper electronics. Field effect transistors (FETs), memory and CMOS devices, with excellent electronic performance and using paper as substrate and dielectric have resulted from my recent work. What I am proposing now is to reinvent the concept of paper electronics. In NEW_FUN I want to develop a completely new and disruptive approach where functionalized cellulose fibers will be used not only as dielectric but also as semiconductor and conductor able to coexist in a multilayer paper structure. That is, assembling paper that can have different functionalities locally, on each face or even along its entire thickness/bulk. This way issues such as failure under bending, mechanical robustness and stability can be minimized. Doing so, electronic and electrochemical devices can be produced not only on paper but also from paper. The outputs of NEW_FUN will open the door to turn paper into a real electronic material making possible disposable/recyclable electronic products, such as smart labels/packages (e.g. food and medicine industry), sensors for air quality control (car, house and industry environments); disposable electronic devices such as bio-detection platforms, lab-on-paper systems, among others.
Max ERC Funding
1 429 719 €
Duration
Start date: 2015-09-01, End date: 2020-08-31
