Project acronym BATMAN
Project Development of Quantitative Metrologies to Guide Lithium Ion Battery Manufacturing
Researcher (PI) Vanessa Wood
Host Institution (HI) EIDGENOESSISCHE TECHNISCHE HOCHSCHULE ZUERICH
Call Details Starting Grant (StG), PE8, ERC-2015-STG
Summary Lithium ion batteries offer tremendous potential as an enabling technology for sustainable transportation and development. However, their widespread usage as the energy storage solution for electric mobility and grid-level integration of renewables is impeded by the fact that current state-of-the-art lithium ion batteries have energy densities that are too small, charge- and discharge rates that are too low, and costs that are too high. Highly publicized instances of catastrophic failure of lithium ion batteries raise questions of safety. Understanding the limitations to battery performance and origins of the degradation and failure is highly complex due to the difficulties in studying interrelated processes that take place at different length and time scales in a corrosive environment. In the project, we will (1) develop and implement quantitative methods to study the complex interrelations between structure and electrochemistry occurring at the nano-, micron-, and milli-scales in lithium ion battery active materials and electrodes, (2) conduct systematic experimental studies with our new techniques to understand the origins of performance limitations and to develop design guidelines for achieving high performance and safe batteries, and (3) investigate economically viable engineering solutions based on these guidelines to achieve high performance and safe lithium ion batteries.
Summary
Lithium ion batteries offer tremendous potential as an enabling technology for sustainable transportation and development. However, their widespread usage as the energy storage solution for electric mobility and grid-level integration of renewables is impeded by the fact that current state-of-the-art lithium ion batteries have energy densities that are too small, charge- and discharge rates that are too low, and costs that are too high. Highly publicized instances of catastrophic failure of lithium ion batteries raise questions of safety. Understanding the limitations to battery performance and origins of the degradation and failure is highly complex due to the difficulties in studying interrelated processes that take place at different length and time scales in a corrosive environment. In the project, we will (1) develop and implement quantitative methods to study the complex interrelations between structure and electrochemistry occurring at the nano-, micron-, and milli-scales in lithium ion battery active materials and electrodes, (2) conduct systematic experimental studies with our new techniques to understand the origins of performance limitations and to develop design guidelines for achieving high performance and safe batteries, and (3) investigate economically viable engineering solutions based on these guidelines to achieve high performance and safe lithium ion batteries.
Max ERC Funding
1 500 000 €
Duration
Start date: 2016-05-01, End date: 2021-04-30
Project acronym CapBed
Project Engineered Capillary Beds for Successful Prevascularization of Tissue Engineering Constructs
Researcher (PI) Rogério Pedro Lemos de Sousa Pirraco
Host Institution (HI) UNIVERSIDADE DO MINHO
Call Details Starting Grant (StG), PE8, ERC-2018-STG
Summary The demand for donated organs vastly outnumbers the supply, leading each year to the death of thousands of people and the suffering of millions more. Engineered tissues and organs following Tissue Engineering approaches are a possible solution to this problem. However, a prevascularization solution to irrigate complex engineered tissues and assure their survival after transplantation is currently elusive. In the human body, complex organs and tissues irrigation is achieved by a network of blood vessels termed capillary bed which suggests such a structure is needed in engineered tissues. Previous approaches to engineer capillary beds reached different levels of success but none yielded a fully functional one due to the inability in simultaneously addressing key elements such as correct angiogenic cell populations, a suitable matrix and dynamic conditions that mimic blood flow.
CapBed aims at proposing a new technology to fabricate in vitro capillary beds that include a vascular axis that can be anastomosed with a patient circulation. Such capillary beds could be used as prime tools to prevascularize in vitro engineered tissues and provide fast perfusion of those after transplantation to a patient. Cutting edge techniques will be for the first time integrated in a disruptive approach to address the requirements listed above. Angiogenic cell sheets of human Adipose-derived Stromal Vascular fraction cells will provide the cell populations that integrate the capillaries and manage its intricate formation, as well as the collagen required to build the matrix that will hold the capillary beds. Innovative fabrication technologies such as 3D printing and laser photoablation will be used for the fabrication of the micropatterned matrix that will allow fluid flow through microfluidics. The resulting functional capillary beds can be used with virtually every tissue engineering strategy rendering the proposed strategy with massive economical, scientific and medical potential
Summary
The demand for donated organs vastly outnumbers the supply, leading each year to the death of thousands of people and the suffering of millions more. Engineered tissues and organs following Tissue Engineering approaches are a possible solution to this problem. However, a prevascularization solution to irrigate complex engineered tissues and assure their survival after transplantation is currently elusive. In the human body, complex organs and tissues irrigation is achieved by a network of blood vessels termed capillary bed which suggests such a structure is needed in engineered tissues. Previous approaches to engineer capillary beds reached different levels of success but none yielded a fully functional one due to the inability in simultaneously addressing key elements such as correct angiogenic cell populations, a suitable matrix and dynamic conditions that mimic blood flow.
CapBed aims at proposing a new technology to fabricate in vitro capillary beds that include a vascular axis that can be anastomosed with a patient circulation. Such capillary beds could be used as prime tools to prevascularize in vitro engineered tissues and provide fast perfusion of those after transplantation to a patient. Cutting edge techniques will be for the first time integrated in a disruptive approach to address the requirements listed above. Angiogenic cell sheets of human Adipose-derived Stromal Vascular fraction cells will provide the cell populations that integrate the capillaries and manage its intricate formation, as well as the collagen required to build the matrix that will hold the capillary beds. Innovative fabrication technologies such as 3D printing and laser photoablation will be used for the fabrication of the micropatterned matrix that will allow fluid flow through microfluidics. The resulting functional capillary beds can be used with virtually every tissue engineering strategy rendering the proposed strategy with massive economical, scientific and medical potential
Max ERC Funding
1 499 940 €
Duration
Start date: 2018-11-01, End date: 2023-10-31
Project acronym CATACOAT
Project Nanostructured catalyst overcoats for renewable chemical production from biomass
Researcher (PI) Jeremy Scott LUTERBACHER
Host Institution (HI) ECOLE POLYTECHNIQUE FEDERALE DE LAUSANNE
Call Details Starting Grant (StG), PE8, ERC-2017-STG
Summary In the CATACOAT project, we will develop layer-by-layer solution-processed catalyst overcoating methods, which will result in catalysts that have both targeted and broad impacts. We will produce highly active, stable and selective catalysts for the upgrading of lignin – the largest natural source of aromatic chemicals – into commodity chemicals, which will have an important targeted impact. The broader impact of our work will lie in the production of catalytic materials with unprecedented control over the active site architecture.
There is an urgent need to provide these cheap, stable, selective, and highly active catalysts for renewable molecule production. Thanks to its availability and relatively low cost, lignocellulosic biomass is an attractive source of renewable carbon. However, unlike petroleum, biomass-derived molecules are highly oxygenated, and often produced in dilute-aqueous streams. Heterogeneous catalysts – the workhorses of the petrochemical industry – are sensitive to water and contain many metals that easily sinter and leach in liquid-phase conditions. The production of renewable chemicals from biomass, especially valuable aromatics, often requires expensive platinum group metals and suffers from low selectivity.
Catalyst overcoating presents a potential solution to this problem. Recent breakthroughs using catalyst overcoating with atomic layer deposition (ALD) showed that base metal catalysts can be stabilized against sintering and leaching in liquid phase conditions. However, ALD creates dramatic drops in activity due to excessive coverage, and forms an overcoat that cannot be tuned.
Our materials will feature the controlled placement of metal sites (including single atoms), several oxide sites, and even molecular imprints with sub-nanometer precision within highly accessible nanocavities. We anticipate that such materials will create unprecedented opportunities for reducing cost and increasing sustainability in the chemical industry and beyond.
Summary
In the CATACOAT project, we will develop layer-by-layer solution-processed catalyst overcoating methods, which will result in catalysts that have both targeted and broad impacts. We will produce highly active, stable and selective catalysts for the upgrading of lignin – the largest natural source of aromatic chemicals – into commodity chemicals, which will have an important targeted impact. The broader impact of our work will lie in the production of catalytic materials with unprecedented control over the active site architecture.
There is an urgent need to provide these cheap, stable, selective, and highly active catalysts for renewable molecule production. Thanks to its availability and relatively low cost, lignocellulosic biomass is an attractive source of renewable carbon. However, unlike petroleum, biomass-derived molecules are highly oxygenated, and often produced in dilute-aqueous streams. Heterogeneous catalysts – the workhorses of the petrochemical industry – are sensitive to water and contain many metals that easily sinter and leach in liquid-phase conditions. The production of renewable chemicals from biomass, especially valuable aromatics, often requires expensive platinum group metals and suffers from low selectivity.
Catalyst overcoating presents a potential solution to this problem. Recent breakthroughs using catalyst overcoating with atomic layer deposition (ALD) showed that base metal catalysts can be stabilized against sintering and leaching in liquid phase conditions. However, ALD creates dramatic drops in activity due to excessive coverage, and forms an overcoat that cannot be tuned.
Our materials will feature the controlled placement of metal sites (including single atoms), several oxide sites, and even molecular imprints with sub-nanometer precision within highly accessible nanocavities. We anticipate that such materials will create unprecedented opportunities for reducing cost and increasing sustainability in the chemical industry and beyond.
Max ERC Funding
1 785 195 €
Duration
Start date: 2017-12-01, End date: 2022-11-30
Project acronym CEMOS
Project Crystal Engineering for Molecular Organic Semiconductors
Researcher (PI) Kevin Sivula
Host Institution (HI) ECOLE POLYTECHNIQUE FEDERALE DE LAUSANNE
Call Details Starting Grant (StG), PE8, ERC-2013-StG
Summary "The urgent need to develop inexpensive and ubiquitous solar energy conversion cannot be overstated. Solution processed organic semiconductors can enable this goal as they support drastically less expensive fabrication techniques compared to traditional semiconductors. Molecular organic semiconductors (MOSs) offer many advantages to their more-common pi-conjugated polymer counterparts, however a clear and fundamental challenge to enable the goal of high performance solution-processable molecular organic semiconductor devices is to develop the ability to control the crystal packing, crystalline domain size, and mixing ability (for multicomponent blends) in the thin-film device geometry. The CEMOS project will accomplish this by pioneering innovative methods of “bottom-up” crystal engineering for organic semiconductors. We will employ specifically tailored molecules designed to leverage both thermodynamic and kinetic aspects of molecular organic semiconductor systems to direct and control crystalline packing, promote crystallite nucleation, compatibilize disparate phases, and plasticize inelastic materials. We will demonstrate that our new classes of materials can enable the tuning of the charge carrier transport and morphology in MOS thin films, and we will evaluate their performance in actual thin-film transistor (TFT) and organic photovoltaic (OPV) devices. Our highly interdisciplinary approach, combining material synthesis and device fabrication/evaluation, will not only lead to improvements in the performance and stability of OPVs and TFTs but will also give deep insights into how the crystalline packing—independent from the molecular structure—affects the optoelectronic properties. The success of CEMOS will rapidly advance the performance of MOS devices by enabling reproducible and tuneable performance comparable to traditional semiconductors—but at radically lower processing costs."
Summary
"The urgent need to develop inexpensive and ubiquitous solar energy conversion cannot be overstated. Solution processed organic semiconductors can enable this goal as they support drastically less expensive fabrication techniques compared to traditional semiconductors. Molecular organic semiconductors (MOSs) offer many advantages to their more-common pi-conjugated polymer counterparts, however a clear and fundamental challenge to enable the goal of high performance solution-processable molecular organic semiconductor devices is to develop the ability to control the crystal packing, crystalline domain size, and mixing ability (for multicomponent blends) in the thin-film device geometry. The CEMOS project will accomplish this by pioneering innovative methods of “bottom-up” crystal engineering for organic semiconductors. We will employ specifically tailored molecules designed to leverage both thermodynamic and kinetic aspects of molecular organic semiconductor systems to direct and control crystalline packing, promote crystallite nucleation, compatibilize disparate phases, and plasticize inelastic materials. We will demonstrate that our new classes of materials can enable the tuning of the charge carrier transport and morphology in MOS thin films, and we will evaluate their performance in actual thin-film transistor (TFT) and organic photovoltaic (OPV) devices. Our highly interdisciplinary approach, combining material synthesis and device fabrication/evaluation, will not only lead to improvements in the performance and stability of OPVs and TFTs but will also give deep insights into how the crystalline packing—independent from the molecular structure—affects the optoelectronic properties. The success of CEMOS will rapidly advance the performance of MOS devices by enabling reproducible and tuneable performance comparable to traditional semiconductors—but at radically lower processing costs."
Max ERC Funding
1 477 472 €
Duration
Start date: 2014-01-01, End date: 2018-12-31
Project acronym ELASTIC-TURBULENCE
Project Purely-elastic flow instabilities and transition to elastic turbulence in microscale flows of complex fluids
Researcher (PI) Manuel António Moreira Alves
Host Institution (HI) UNIVERSIDADE DO PORTO
Call Details Starting Grant (StG), PE8, ERC-2012-StG_20111012
Summary Flows of complex fluids, such as many biological fluids and most synthetic fluids, are common in our daily life and are very important from an industrial perspective. Because of their inherent nonlinearity, the flow of complex viscoelastic fluids often leads to counterintuitive and complex behaviour and, above critical conditions, can prompt flow instabilities even under low Reynolds number conditions which are entirely absent in the corresponding Newtonian fluid flows.
The primary goal of this project is to substantially expand the frontiers of our current knowledge regarding the mechanisms that lead to the development of such purely-elastic flow instabilities, and ultimately to understand the transition to so-called “elastic turbulence”, a turbulent-like phenomenon which can arise even under inertialess flow conditions. This is an extremely challenging problem, and to significantly advance our knowledge in such important flows these instabilities will be investigated in a combined manner encompassing experiments, theory and numerical simulations. Such a holistic approach will enable us to understand the underlying mechanisms of those instabilities and to develop accurate criteria for their prediction far in advance of what we could achieve with either approach separately. A deep understanding of the mechanisms generating elastic instabilities and subsequent transition to elastic turbulence is crucial from a fundamental point of view and for many important practical applications involving engineered complex fluids, such as the design of microfluidic mixers for efficient operation under inertialess flow conditions, or the development of highly efficient micron-sized energy management and mass transfer systems.
This research proposal will create a solid basis for the establishment of an internationally-leading research group led by the PI studying flow instabilities and elastic turbulence in complex fluid flows.
Summary
Flows of complex fluids, such as many biological fluids and most synthetic fluids, are common in our daily life and are very important from an industrial perspective. Because of their inherent nonlinearity, the flow of complex viscoelastic fluids often leads to counterintuitive and complex behaviour and, above critical conditions, can prompt flow instabilities even under low Reynolds number conditions which are entirely absent in the corresponding Newtonian fluid flows.
The primary goal of this project is to substantially expand the frontiers of our current knowledge regarding the mechanisms that lead to the development of such purely-elastic flow instabilities, and ultimately to understand the transition to so-called “elastic turbulence”, a turbulent-like phenomenon which can arise even under inertialess flow conditions. This is an extremely challenging problem, and to significantly advance our knowledge in such important flows these instabilities will be investigated in a combined manner encompassing experiments, theory and numerical simulations. Such a holistic approach will enable us to understand the underlying mechanisms of those instabilities and to develop accurate criteria for their prediction far in advance of what we could achieve with either approach separately. A deep understanding of the mechanisms generating elastic instabilities and subsequent transition to elastic turbulence is crucial from a fundamental point of view and for many important practical applications involving engineered complex fluids, such as the design of microfluidic mixers for efficient operation under inertialess flow conditions, or the development of highly efficient micron-sized energy management and mass transfer systems.
This research proposal will create a solid basis for the establishment of an internationally-leading research group led by the PI studying flow instabilities and elastic turbulence in complex fluid flows.
Max ERC Funding
994 110 €
Duration
Start date: 2012-10-01, End date: 2018-01-31
Project acronym ELECTROCHEMBOTS
Project MAGNETOELECTRIC CHEMONANOROBOTICS FOR CHEMICAL AND BIOMEDICAL APPLICATIONS
Researcher (PI) Salvador Pané Vidal
Host Institution (HI) EIDGENOESSISCHE TECHNISCHE HOCHSCHULE ZUERICH
Call Details Starting Grant (StG), PE8, ERC-2013-StG
Summary "The ability to generate electric fields at small scales is becoming increasingly important in many fields of research including plasmonics-based sensing, micro- and nanofabrication, microfluidics and spintronics. The localized generation of electrical fields at extremely small scales has the potential to revolutionize conventional methods of electrically stimulating cells. The objective of this proposal is the development of miniaturized untethered devices capable of delivering electric currents to cells for the stimulation of their vital functions. To this end, we propose the construction of micro- and nanoscale magnetoelectric structures that can be triggered using external magnetic fields. These small devices will consist of composite hybrid structures containing piezoelectric and magnetostrictive layers. By applying an oscillating magnetic field in the presence of a DC bias field, the magnetostrictive element will deform, thereby generating stress in a piezoelectric shell, which in turn will become electrically polarized. Small devices capable of wirelessly generating electric fields offer an innovative way of studying the electrical and electrochemical stimulation of cells. For example, by concentrating electric fields at specific locations in a cell, the behavior of protein membrane components such as cell adhesion molecules or transport proteins can be altered to modulate the stiction of proliferating cells or ion channel gating kinetics."
Summary
"The ability to generate electric fields at small scales is becoming increasingly important in many fields of research including plasmonics-based sensing, micro- and nanofabrication, microfluidics and spintronics. The localized generation of electrical fields at extremely small scales has the potential to revolutionize conventional methods of electrically stimulating cells. The objective of this proposal is the development of miniaturized untethered devices capable of delivering electric currents to cells for the stimulation of their vital functions. To this end, we propose the construction of micro- and nanoscale magnetoelectric structures that can be triggered using external magnetic fields. These small devices will consist of composite hybrid structures containing piezoelectric and magnetostrictive layers. By applying an oscillating magnetic field in the presence of a DC bias field, the magnetostrictive element will deform, thereby generating stress in a piezoelectric shell, which in turn will become electrically polarized. Small devices capable of wirelessly generating electric fields offer an innovative way of studying the electrical and electrochemical stimulation of cells. For example, by concentrating electric fields at specific locations in a cell, the behavior of protein membrane components such as cell adhesion molecules or transport proteins can be altered to modulate the stiction of proliferating cells or ion channel gating kinetics."
Max ERC Funding
1 491 701 €
Duration
Start date: 2013-09-01, End date: 2018-08-31
Project acronym GALATEA
Project Tailoring Material Properties Using Femtosecond Lasers: A New Paradigm for Highly Integrated Micro-/Nano- Scale Systems
Researcher (PI) Yves, Jérôme Bellouard
Host Institution (HI) ECOLE POLYTECHNIQUE FEDERALE DE LAUSANNE
Call Details Starting Grant (StG), PE8, ERC-2012-StG_20111012
Summary Using recent progress in laser technology and in particular in the field of ultra-fast lasers, we are getting close to accomplish the alchemist dream of transforming materials. Compact lasers can generate pulses with ultra-high peak powers in the Tera-Watt or even Peta-Watt ranges. These high-power pulses lead to a radically different laser-matter interaction than the one obtained with conventional lasers. Non-linear multi-photons processes are observed; they open new and exciting opportunities to tailor the matter in its intimate structure with sub-wavelength spatial resolutions and in the three dimensions.
This project is aiming at exploring the use of these ultrafast lasers to locally tailor the physical properties of glass materials. More specifically, our objective is to create polymorphs embedded in bulk structures and to demonstrate their use as means to introduce new functionalities in the material.
The long-term objective is to develop the scientific understanding and technological know-how to create three-dimensional objects with nanoscale features where optics, fluidics and micromechanical elements as well as active functions are integrated in a single monolithic piece of glass and to do so using a single process.
This is a multidisciplinary research that pushes the frontier of our current knowledge of femtosecond laser interaction with glass to demonstrate a novel design platform for future micro-/nano- systems.
Summary
Using recent progress in laser technology and in particular in the field of ultra-fast lasers, we are getting close to accomplish the alchemist dream of transforming materials. Compact lasers can generate pulses with ultra-high peak powers in the Tera-Watt or even Peta-Watt ranges. These high-power pulses lead to a radically different laser-matter interaction than the one obtained with conventional lasers. Non-linear multi-photons processes are observed; they open new and exciting opportunities to tailor the matter in its intimate structure with sub-wavelength spatial resolutions and in the three dimensions.
This project is aiming at exploring the use of these ultrafast lasers to locally tailor the physical properties of glass materials. More specifically, our objective is to create polymorphs embedded in bulk structures and to demonstrate their use as means to introduce new functionalities in the material.
The long-term objective is to develop the scientific understanding and technological know-how to create three-dimensional objects with nanoscale features where optics, fluidics and micromechanical elements as well as active functions are integrated in a single monolithic piece of glass and to do so using a single process.
This is a multidisciplinary research that pushes the frontier of our current knowledge of femtosecond laser interaction with glass to demonstrate a novel design platform for future micro-/nano- systems.
Max ERC Funding
1 757 396 €
Duration
Start date: 2012-12-01, End date: 2017-11-30
Project acronym IgYPurTech
Project IgY Technology: A Purification Platform using Ionic-Liquid-Based Aqueous Biphasic Systems
Researcher (PI) Mara Guadalupe Freire Martins
Host Institution (HI) UNIVERSIDADE DE AVEIRO
Call Details Starting Grant (StG), PE8, ERC-2013-StG
Summary With the emergence of antibiotic-resistant pathogens the development of antigen-specific antibodies for use in passive immunotherapy is, nowadays, a major concern in human society. Despite the most focused mammal antibodies, antibodies obtained from egg yolk of immunized hens, immunoglobulin Y (IgY), are an alternative option that can be obtained in higher titres by non-stressful and non-invasive methods. This large amount of available antibodies opens the door for a new kind of cheaper biopharmaceuticals. However, the production cost of high-quality IgY for large-scale applications remains higher than other drug therapies due to the lack of an efficient purification method. The search of new purification platforms is thus a vital demand to which liquid-liquid extraction using aqueous biphasic systems (ABS) could be the answer. Besides the conventional polymer-based systems, highly viscous and with a limited polarity/affinity range, a recent type of ABS composed of ionic liquids (ILs) may be employed. ILs are usually classified as “green solvents” due to their negligible vapour pressure. Yet, the major advantage of IL-based ABS relies on the possibility of tailoring their phases’ polarities aiming at extracting a target biomolecule. A proper manipulation of the system constituents and respective composition allows the pre-concentration, complete extraction, or purification of the most diverse biomolecules.
This research project addresses the development of a new technique for the extraction and purification of IgY from egg yolk using IL-based ABS. The proposed plan contemplates the optimization of purification systems at the laboratory scale and their use in countercurrent chromatography to achieve a simple, cost-effective and scalable process. The success of this project and its scalability to an industrial level certainly will allow the production of cheaper antibodies with a long-term impact in human healthcare.
Summary
With the emergence of antibiotic-resistant pathogens the development of antigen-specific antibodies for use in passive immunotherapy is, nowadays, a major concern in human society. Despite the most focused mammal antibodies, antibodies obtained from egg yolk of immunized hens, immunoglobulin Y (IgY), are an alternative option that can be obtained in higher titres by non-stressful and non-invasive methods. This large amount of available antibodies opens the door for a new kind of cheaper biopharmaceuticals. However, the production cost of high-quality IgY for large-scale applications remains higher than other drug therapies due to the lack of an efficient purification method. The search of new purification platforms is thus a vital demand to which liquid-liquid extraction using aqueous biphasic systems (ABS) could be the answer. Besides the conventional polymer-based systems, highly viscous and with a limited polarity/affinity range, a recent type of ABS composed of ionic liquids (ILs) may be employed. ILs are usually classified as “green solvents” due to their negligible vapour pressure. Yet, the major advantage of IL-based ABS relies on the possibility of tailoring their phases’ polarities aiming at extracting a target biomolecule. A proper manipulation of the system constituents and respective composition allows the pre-concentration, complete extraction, or purification of the most diverse biomolecules.
This research project addresses the development of a new technique for the extraction and purification of IgY from egg yolk using IL-based ABS. The proposed plan contemplates the optimization of purification systems at the laboratory scale and their use in countercurrent chromatography to achieve a simple, cost-effective and scalable process. The success of this project and its scalability to an industrial level certainly will allow the production of cheaper antibodies with a long-term impact in human healthcare.
Max ERC Funding
1 386 020 €
Duration
Start date: 2014-02-01, End date: 2019-01-31
Project acronym microCrysFact
Project Microfluidic Crystal Factories (μ-CrysFact): a breakthrough approach for crystal engineering
Researcher (PI) Jose Puigmartí Luis
Host Institution (HI) EIDGENOESSISCHE TECHNISCHE HOCHSCHULE ZUERICH
Call Details Starting Grant (StG), PE8, ERC-2015-STG
Summary To study and understand the aggregation, nucleation, and/or self-assembly processes of crystalline matter is of crucial importance for research and applications in many disciplines. For example, understanding the formation of crystalline amyloid fibres could lead to advances in the treatment and prevention of both Alzheimer’s and Parkinson’s diseases, whereas controlling the process of crystal formation can play a significant role in obtaining chemicals and materials that are important for industry as well as society as a whole (e.g., drugs, superconductors, polarizers and/or frequency modulators).
Despite the impressive progress made in molecular engineering during the last few decades, the quest for a general tool-box technology to study, control and monitor crystallisation processes as well as to isolate metastable states (dynamic capture) is still incomplete. That is because crystalline assemblies are frequently investigated in their equilibrium form, driving the system to its minimum energy state. This methodology limits the emergence of new chemicals and crystals with advanced functionalities, and thus hampers advances in the field of materials engineering.
µ-CrysFact will develop tool-box technologies where diffusion-limited and kinetically controlled environments will be achieved during crystallisation and where the isolation of non-equilibrium species will be facilitated by pushing crystallisation processes out of equilibrium. In addition, µ-CrysFact’s technologies will be used to localise, integrate and chemically treat crystals with the aim of honing their functionality. This unprecedented approach has the potential to lead to the discovery of new materials with advanced functions and unique properties, thus opening new horizons in materials engineering research.
Summary
To study and understand the aggregation, nucleation, and/or self-assembly processes of crystalline matter is of crucial importance for research and applications in many disciplines. For example, understanding the formation of crystalline amyloid fibres could lead to advances in the treatment and prevention of both Alzheimer’s and Parkinson’s diseases, whereas controlling the process of crystal formation can play a significant role in obtaining chemicals and materials that are important for industry as well as society as a whole (e.g., drugs, superconductors, polarizers and/or frequency modulators).
Despite the impressive progress made in molecular engineering during the last few decades, the quest for a general tool-box technology to study, control and monitor crystallisation processes as well as to isolate metastable states (dynamic capture) is still incomplete. That is because crystalline assemblies are frequently investigated in their equilibrium form, driving the system to its minimum energy state. This methodology limits the emergence of new chemicals and crystals with advanced functionalities, and thus hampers advances in the field of materials engineering.
µ-CrysFact will develop tool-box technologies where diffusion-limited and kinetically controlled environments will be achieved during crystallisation and where the isolation of non-equilibrium species will be facilitated by pushing crystallisation processes out of equilibrium. In addition, µ-CrysFact’s technologies will be used to localise, integrate and chemically treat crystals with the aim of honing their functionality. This unprecedented approach has the potential to lead to the discovery of new materials with advanced functions and unique properties, thus opening new horizons in materials engineering research.
Max ERC Funding
1 814 128 €
Duration
Start date: 2016-09-01, End date: 2021-08-31
Project acronym MiniMasonryTesting
Project Seismic Testing of 3D Printed Miniature Masonry in a Geotechnical Centrifuge
Researcher (PI) Michalis VASSILIOU
Host Institution (HI) EIDGENOESSISCHE TECHNISCHE HOCHSCHULE ZUERICH
Call Details Starting Grant (StG), PE8, ERC-2018-STG
Summary Earthquakes are responsible for more than half of the human losses due to natural disasters. Masonry structures have been proven the most vulnerable both in the developing and in the developed world. Even though Masonry is one of the oldest building materials, our understanding of its behavior at the level of the structure (system level) is limited. Therefore, there is a need for extended shake table testing. But shake table tests are expensive and full-scale system-level testing of large buildings is only possible in a handful of shake tables in the globe – and at a huge cost.
We propose to take advantage of research developments in 3D printing and develop a method to perform system-level testing at a small scale using 3D printers and a geotechnical centrifuge (to preserve similitude). The key is to print materials with behavior controllable and similar to masonry. MiniMasonry testing proposes to control the properties of masonry via controlling the geometry of a 3D printed “meta”-mortar. The method will be developed via typical static masonry tests performed on the 3D printed parts. It will be further validated via comparing shaking table tests (in a centrifuge) of miniature structures to existing results of full-scale tests. The cost of the dynamic tests is expected to be so low, that multiple tests can be performed, so that existing numerical methods can be validated in the statistical sense. As a case study, the method will be applied to explore the behavior of a low-cost seismic isolation method that has been proposed for masonry structures in developing countries.
With the rapid evolution of 3D printing, it will be possible to scale-up the methods developed in MiniMasonryTesting, so that other Civil Engineering materials can be tested faster and cheaper than now. This is a game changer in structural testing, as it will enable researchers to test structures that up to now it was impossible or very expensive to test at a system level.
Summary
Earthquakes are responsible for more than half of the human losses due to natural disasters. Masonry structures have been proven the most vulnerable both in the developing and in the developed world. Even though Masonry is one of the oldest building materials, our understanding of its behavior at the level of the structure (system level) is limited. Therefore, there is a need for extended shake table testing. But shake table tests are expensive and full-scale system-level testing of large buildings is only possible in a handful of shake tables in the globe – and at a huge cost.
We propose to take advantage of research developments in 3D printing and develop a method to perform system-level testing at a small scale using 3D printers and a geotechnical centrifuge (to preserve similitude). The key is to print materials with behavior controllable and similar to masonry. MiniMasonry testing proposes to control the properties of masonry via controlling the geometry of a 3D printed “meta”-mortar. The method will be developed via typical static masonry tests performed on the 3D printed parts. It will be further validated via comparing shaking table tests (in a centrifuge) of miniature structures to existing results of full-scale tests. The cost of the dynamic tests is expected to be so low, that multiple tests can be performed, so that existing numerical methods can be validated in the statistical sense. As a case study, the method will be applied to explore the behavior of a low-cost seismic isolation method that has been proposed for masonry structures in developing countries.
With the rapid evolution of 3D printing, it will be possible to scale-up the methods developed in MiniMasonryTesting, so that other Civil Engineering materials can be tested faster and cheaper than now. This is a game changer in structural testing, as it will enable researchers to test structures that up to now it was impossible or very expensive to test at a system level.
Max ERC Funding
1 999 477 €
Duration
Start date: 2019-04-01, End date: 2024-03-31
