Project acronym ComplexiTE
Project An integrated multidisciplinary tissue engineering approach combining novel high-throughput screening and advanced methodologies to create complex biomaterials-stem cells constructs
Researcher (PI) Rui Luis Goncalves Dos Reis
Host Institution (HI) UNIVERSIDADE DO MINHO
Country Portugal
Call Details Advanced Grant (AdG), PE8, ERC-2012-ADG_20120216
Summary New developments on tissue engineering strategies should realize the complexity of tissue remodelling and the inter-dependency of many variables associated to stem cells and biomaterials interactions. ComplexiTE proposes an integrated approach to address such multiple factors in which different innovative methodologies are implemented, aiming at developing tissue-like substitutes with enhanced in vivo functionality. Several ground-breaking advances are expected to be achieved, including: i) improved methodologies for isolation and expansion of sub-populations of stem cells derived from not so explored sources such as adipose tissue and amniotic fluid; ii) radically new methods to monitor human stem cells behaviour in vivo; iii) new macromolecules isolated from renewable resources, especially from marine origin; iv) combinations of liquid volumes mingling biomaterials and distinct stem cells, generating hydrogel beads upon adequate cross-linking reactions; v) optimised culture of the produced beads in adequate 3D bioreactors and a novel selection method to sort the beads that show a (pre-defined) positive biological reading; vi) random 3D arrays validated by identifying the natural polymers and cells composing the positive beads; v) 2D arrays of selected hydrogel spots for brand new in vivo tests, in which each spot of the implanted chip may be evaluated within the living animal using adequate imaging methods; vi) new porous scaffolds of the best combinations formed by particles agglomeration or fiber-based rapid-prototyping. The ultimate goal of this proposal is to develop breakthrough research specifically focused on the above mentioned key issues and radically innovative approaches to produce and scale-up new tissue engineering strategies that are both industrially and clinically relevant, by mastering the inherent complexity associated to the correct selection among a great number of combinations of possible biomaterials, stem cells and culturing conditions.
Summary
New developments on tissue engineering strategies should realize the complexity of tissue remodelling and the inter-dependency of many variables associated to stem cells and biomaterials interactions. ComplexiTE proposes an integrated approach to address such multiple factors in which different innovative methodologies are implemented, aiming at developing tissue-like substitutes with enhanced in vivo functionality. Several ground-breaking advances are expected to be achieved, including: i) improved methodologies for isolation and expansion of sub-populations of stem cells derived from not so explored sources such as adipose tissue and amniotic fluid; ii) radically new methods to monitor human stem cells behaviour in vivo; iii) new macromolecules isolated from renewable resources, especially from marine origin; iv) combinations of liquid volumes mingling biomaterials and distinct stem cells, generating hydrogel beads upon adequate cross-linking reactions; v) optimised culture of the produced beads in adequate 3D bioreactors and a novel selection method to sort the beads that show a (pre-defined) positive biological reading; vi) random 3D arrays validated by identifying the natural polymers and cells composing the positive beads; v) 2D arrays of selected hydrogel spots for brand new in vivo tests, in which each spot of the implanted chip may be evaluated within the living animal using adequate imaging methods; vi) new porous scaffolds of the best combinations formed by particles agglomeration or fiber-based rapid-prototyping. The ultimate goal of this proposal is to develop breakthrough research specifically focused on the above mentioned key issues and radically innovative approaches to produce and scale-up new tissue engineering strategies that are both industrially and clinically relevant, by mastering the inherent complexity associated to the correct selection among a great number of combinations of possible biomaterials, stem cells and culturing conditions.
Max ERC Funding
2 320 000 €
Duration
Start date: 2013-05-01, End date: 2018-04-30
Project acronym DropletControl
Project Controlling the orientation of molecules inside liquid helium nanodroplets
Researcher (PI) Henrik Stapelfeldt
Host Institution (HI) AARHUS UNIVERSITET
Country Denmark
Call Details Advanced Grant (AdG), PE2, ERC-2012-ADG_20120216
Summary In this project I will develop and exploit experimental methods, based on short and intense laser pulses, to control the spatial orientation of molecules dissolved in liquid helium nanodroplets. This idea is, so far, completely unexplored but it has the potential to open a multitude of new opportunities in physics and chemistry. The main objectives are:
1) Complete control and real time monitoring of molecular rotation inside liquid helium droplets, exploring superfluidity of the droplets, the possible formation of quantum vortices, and rotational dephasing due to interaction of the dissolved molecules with the He solvent.
2) Ultrafast imaging of molecules undergoing chemical reaction dynamics inside liquid helium droplets, exploring rapid energy dissipation from reacting molecules to the helium solvent, transition between mirror forms of chiral molecules, strong laser field processes in He-solvated molecules, and structure determination of non crystalizable proteins by electron or x-ray diffraction.
I will achieve the objectives by combining liquid helium droplet technology, ultrafast laser pulse methods and advanced electron and ion imaging detection. The experiments will both rely on existing apparatus in my laboratories and on new vacuum and laser equipment to be set up during the project.
The ability to control how molecules are turned in space is of fundamental importance because interactions of molecules with other molecules, atoms or radiation depend on their spatial orientation. For isolated molecules in the gas phase laser based methods, developed over the past 12 years, now enable very refined and precise control over the spatial orientation of molecules. By contrast, orientational control of molecules in solution has not been demonstrated despite the potential of being able to do so is enormous, notably because most chemistry occurs in a solvent rather than in a gas of isolated molecules.
Summary
In this project I will develop and exploit experimental methods, based on short and intense laser pulses, to control the spatial orientation of molecules dissolved in liquid helium nanodroplets. This idea is, so far, completely unexplored but it has the potential to open a multitude of new opportunities in physics and chemistry. The main objectives are:
1) Complete control and real time monitoring of molecular rotation inside liquid helium droplets, exploring superfluidity of the droplets, the possible formation of quantum vortices, and rotational dephasing due to interaction of the dissolved molecules with the He solvent.
2) Ultrafast imaging of molecules undergoing chemical reaction dynamics inside liquid helium droplets, exploring rapid energy dissipation from reacting molecules to the helium solvent, transition between mirror forms of chiral molecules, strong laser field processes in He-solvated molecules, and structure determination of non crystalizable proteins by electron or x-ray diffraction.
I will achieve the objectives by combining liquid helium droplet technology, ultrafast laser pulse methods and advanced electron and ion imaging detection. The experiments will both rely on existing apparatus in my laboratories and on new vacuum and laser equipment to be set up during the project.
The ability to control how molecules are turned in space is of fundamental importance because interactions of molecules with other molecules, atoms or radiation depend on their spatial orientation. For isolated molecules in the gas phase laser based methods, developed over the past 12 years, now enable very refined and precise control over the spatial orientation of molecules. By contrast, orientational control of molecules in solution has not been demonstrated despite the potential of being able to do so is enormous, notably because most chemistry occurs in a solvent rather than in a gas of isolated molecules.
Max ERC Funding
2 409 773 €
Duration
Start date: 2013-05-01, End date: 2018-04-30
Project acronym HARMONY
Project "Harmonic identification, mitigation and control in power electronics based power systems"
Researcher (PI) Frede Blaabjerg
Host Institution (HI) AALBORG UNIVERSITET
Country Denmark
Call Details Advanced Grant (AdG), PE7, ERC-2012-ADG_20120216
Summary "Global electrical energy consumption is still increasing which demands that power capacity and power transmission capabilities must be doubled within 20 years. Today 40 % of the global energy consumption is processed by electricity in 2040 this may be up to 70 %. Electrical power production is changing from conventional, fossil based sources to renewable power resources. Highly efficient and sustainable power electronics in power generation, power transmission/distribution and end-user applications are introduced to ensure more efficient use of electricity. Traditional centralized electricity production with unidirectional power flows in transmission and distribution system will be replaced by the operation and control of intelligent distribution systems which are much more based on power electronics systems and having bidirectional power flow. Such large scale expansion of power electronics usage will change the characteristic of the power system by introducing more harmonics from generation, from the efficient load systems all resulting in a larger risk of instability and more losses in the future power system. The projects goal is to obtain “Harmony” between the renewable energy sources, the future power system and the loads in order to keep stability at all levels seen from a harmonic point of view. The project establishes the necessary theories, models and methods to identify harmonic problems in a power electronic based power system, a theoretical and hardware platform to enable control of harmonics and mitigate them, and develops on-line methods to monitor the harmonic state of the power system. The outcomes are new tools for identifying stability problems in power electronics based power systems and new control methods for reducing the harmonic presence and reduce the overall instability risks. Further, new design methods for active and passive filters in renewable energy systems, in the power system and in the power electronics based loads will be developed"
Summary
"Global electrical energy consumption is still increasing which demands that power capacity and power transmission capabilities must be doubled within 20 years. Today 40 % of the global energy consumption is processed by electricity in 2040 this may be up to 70 %. Electrical power production is changing from conventional, fossil based sources to renewable power resources. Highly efficient and sustainable power electronics in power generation, power transmission/distribution and end-user applications are introduced to ensure more efficient use of electricity. Traditional centralized electricity production with unidirectional power flows in transmission and distribution system will be replaced by the operation and control of intelligent distribution systems which are much more based on power electronics systems and having bidirectional power flow. Such large scale expansion of power electronics usage will change the characteristic of the power system by introducing more harmonics from generation, from the efficient load systems all resulting in a larger risk of instability and more losses in the future power system. The projects goal is to obtain “Harmony” between the renewable energy sources, the future power system and the loads in order to keep stability at all levels seen from a harmonic point of view. The project establishes the necessary theories, models and methods to identify harmonic problems in a power electronic based power system, a theoretical and hardware platform to enable control of harmonics and mitigate them, and develops on-line methods to monitor the harmonic state of the power system. The outcomes are new tools for identifying stability problems in power electronics based power systems and new control methods for reducing the harmonic presence and reduce the overall instability risks. Further, new design methods for active and passive filters in renewable energy systems, in the power system and in the power electronics based loads will be developed"
Max ERC Funding
2 500 000 €
Duration
Start date: 2013-03-01, End date: 2018-02-28
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 LOBENA
Project Long Beamtime Experiments for Nuclear Astrophysics
Researcher (PI) Hans Otto Uldall Fynbo
Host Institution (HI) AARHUS UNIVERSITET
Country Denmark
Call Details Starting Grant (StG), PE2, ERC-2012-StG_20111012
Summary The goal of LOBENA is to measure key properties needed for understanding nuclear processes in the Cosmos. Nuclear Astrophysics plays a key role in our quest to understand the origin and distribution of the chemical elements in our galaxy. Nuclear processes are crucial for understanding the energy production in the universe and are essential for describing the creation of chemical elements from the ashes of the Big Bang. Uncertainties in the nuclear physics can therefore influence our understanding of many astrophysical processes, both those involving stable stellar burning phases and explosive phenomena such as X-ray bursts, gamma-ray bursts and supernovae.
In LOBENA (LOng Beamtime Experiments for Nuclear Astrophysics) I will initiate a series of studies in Nuclear Astrophysics, which have in common the need for long beam times and the use of complete kinematics detection of several particles emitted in reactions. The core of the project will focus on the systems 8Be, 12C and 16O where today key open questions of great importance remain to answered. These questions can be addressed by reactions induced by low energy (<5MeV) beams of protons and 3He on light targets such as 6,7Li, 9Be, 10,11B and 19F using a newly developed complete kinematics detection procedure. The department of Physics and Astronomy in Aarhus provides a unique scene for doing these measurements since it provides accelerators where long beam time can be guarantied. LOBENA will also include complimentary experiments at international user facilities such as ISOLDE (CERN), KVI (Groningen), JYFL and (Jyväskylä).
With this ERC starting grant proposal I wish to start up my own group around Nuclear Astrophysics experiments in house and at international user facilities. With two Post Doc.s and a Ph.D. I will be much better able to fully exploit the scientific potential of the proposed research, which will also help to consolidate my own research career and give me more independence.
Summary
The goal of LOBENA is to measure key properties needed for understanding nuclear processes in the Cosmos. Nuclear Astrophysics plays a key role in our quest to understand the origin and distribution of the chemical elements in our galaxy. Nuclear processes are crucial for understanding the energy production in the universe and are essential for describing the creation of chemical elements from the ashes of the Big Bang. Uncertainties in the nuclear physics can therefore influence our understanding of many astrophysical processes, both those involving stable stellar burning phases and explosive phenomena such as X-ray bursts, gamma-ray bursts and supernovae.
In LOBENA (LOng Beamtime Experiments for Nuclear Astrophysics) I will initiate a series of studies in Nuclear Astrophysics, which have in common the need for long beam times and the use of complete kinematics detection of several particles emitted in reactions. The core of the project will focus on the systems 8Be, 12C and 16O where today key open questions of great importance remain to answered. These questions can be addressed by reactions induced by low energy (<5MeV) beams of protons and 3He on light targets such as 6,7Li, 9Be, 10,11B and 19F using a newly developed complete kinematics detection procedure. The department of Physics and Astronomy in Aarhus provides a unique scene for doing these measurements since it provides accelerators where long beam time can be guarantied. LOBENA will also include complimentary experiments at international user facilities such as ISOLDE (CERN), KVI (Groningen), JYFL and (Jyväskylä).
With this ERC starting grant proposal I wish to start up my own group around Nuclear Astrophysics experiments in house and at international user facilities. With two Post Doc.s and a Ph.D. I will be much better able to fully exploit the scientific potential of the proposed research, which will also help to consolidate my own research career and give me more independence.
Max ERC Funding
1 476 075 €
Duration
Start date: 2012-11-01, End date: 2018-10-31
Project acronym NanoTrigger
Project Triggerable nanomaterials to modulate cell activity
Researcher (PI) Lino Da Silva Ferreira
Host Institution (HI) CENTRO DE NEUROCIENCIAS E BIOLOGIACELULAR ASSOCIACAO
Country Portugal
Call Details Starting Grant (StG), PE8, ERC-2012-StG_20111012
Summary The advent of molecular reprogramming and the associated opportunities for personalised and therapeutic medicine requires the development of novel systems for on-demand delivery of reprogramming factors into cells in order to modulate their activity/identity. Such triggerable systems should allow precise control of the timing, duration, magnitude and spatial release of the reprogramming factors. Furthermore, the system should allow this control even in vivo, using non-invasive means. The present project aims at developing triggerable systems able to release efficiently reprogramming factors on demand. The potential of this technology will be tested in two settings: (i) in the reprogramming of somatic cells in vitro, and (ii) in the improvement of hematopoietic stem cell engraftment in vivo, at the bone marrow. The proposed research involves a team formed by engineers, chemists, biologists and is highly multidisciplinary in nature encompassing elements of engineering, chemistry, system biology, stem cell technology and nanomedicine.
Summary
The advent of molecular reprogramming and the associated opportunities for personalised and therapeutic medicine requires the development of novel systems for on-demand delivery of reprogramming factors into cells in order to modulate their activity/identity. Such triggerable systems should allow precise control of the timing, duration, magnitude and spatial release of the reprogramming factors. Furthermore, the system should allow this control even in vivo, using non-invasive means. The present project aims at developing triggerable systems able to release efficiently reprogramming factors on demand. The potential of this technology will be tested in two settings: (i) in the reprogramming of somatic cells in vitro, and (ii) in the improvement of hematopoietic stem cell engraftment in vivo, at the bone marrow. The proposed research involves a team formed by engineers, chemists, biologists and is highly multidisciplinary in nature encompassing elements of engineering, chemistry, system biology, stem cell technology and nanomedicine.
Max ERC Funding
1 699 320 €
Duration
Start date: 2012-11-01, End date: 2017-10-31
Project acronym QIOS
Project Quantum Interfaces and Open Systems
Researcher (PI) Anders Soerensen
Host Institution (HI) KOBENHAVNS UNIVERSITET
Country Denmark
Call Details Starting Grant (StG), PE2, ERC-2012-StG_20111012
Summary "Researchers have strived to obtain control of a variety of different quantum systems, each characterized by their own distinct advantages: quantum optical systems offer excellent isolation from the environment while solid state systems allow for integrated micro-fabricated devices. At the same time nuclear spins in molecules can remain decoupled from the environment even under rather harsh conditions, and this is the basis of NMR experiments. Given these distinct advantages it is very fruitful to investigate hybrid devices merging the advantages of each of the systems. To do this it is essential to develop quantum interfaces to connect the different systems. By their very nature such quantum interfaces exchange information with their environment and are therefore open quantum systems.
In this project I wish to establish a strong theoretical quantum optics group which can guide and inspire the experiments towards breaking new grounds for open quantum systems and making quantum interfaces between distinct physical systems. The objective is to develop concrete proposals for how to experimentally control and exploit the interaction of quantum systems with their surroundings and for how this can be used for quantum interfaces.
The work in this project is particularly relevant for applications in quantum information processing, where the current challenge is to take the field from proof-of-principle demonstrations to truly scalable devices. Such challenge demands new interdisciplinary theoretical ideas for hybrid devices. This proposal addresses several key challenges for quantum information processing: scalable multimode quantum repeaters based on hybrid approaches, entanglement enabled quantum metrology, photonic engineering based on surface plasmons, dissipative preparation of entangled states, and phonon engineering for quantum dots. In addition applications towards nuclear spin cooling to improve NMR experiments as well as ultra cold atoms will be explored."
Summary
"Researchers have strived to obtain control of a variety of different quantum systems, each characterized by their own distinct advantages: quantum optical systems offer excellent isolation from the environment while solid state systems allow for integrated micro-fabricated devices. At the same time nuclear spins in molecules can remain decoupled from the environment even under rather harsh conditions, and this is the basis of NMR experiments. Given these distinct advantages it is very fruitful to investigate hybrid devices merging the advantages of each of the systems. To do this it is essential to develop quantum interfaces to connect the different systems. By their very nature such quantum interfaces exchange information with their environment and are therefore open quantum systems.
In this project I wish to establish a strong theoretical quantum optics group which can guide and inspire the experiments towards breaking new grounds for open quantum systems and making quantum interfaces between distinct physical systems. The objective is to develop concrete proposals for how to experimentally control and exploit the interaction of quantum systems with their surroundings and for how this can be used for quantum interfaces.
The work in this project is particularly relevant for applications in quantum information processing, where the current challenge is to take the field from proof-of-principle demonstrations to truly scalable devices. Such challenge demands new interdisciplinary theoretical ideas for hybrid devices. This proposal addresses several key challenges for quantum information processing: scalable multimode quantum repeaters based on hybrid approaches, entanglement enabled quantum metrology, photonic engineering based on surface plasmons, dissipative preparation of entangled states, and phonon engineering for quantum dots. In addition applications towards nuclear spin cooling to improve NMR experiments as well as ultra cold atoms will be explored."
Max ERC Funding
1 431 542 €
Duration
Start date: 2012-10-01, End date: 2017-09-30
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
