Project acronym AFRODITE
Project Advanced Fluid Research On Drag reduction In Turbulence Experiments
Researcher (PI) Jens Henrik Mikael Fransson
Host Institution (HI) KUNGLIGA TEKNISKA HOEGSKOLAN
Call Details Starting Grant (StG), PE8, ERC-2010-StG_20091028
Summary A hot topic in today's debate on global warming is drag reduction in aeronautics. The most beneficial concept for drag reduction is to maintain the major portion of the airfoil laminar. Estimations show that the potential drag reduction can be as much as 15%, which would give a significant reduction of NOx and CO emissions in the atmosphere considering that the number of aircraft take offs, only in the EU, is over 19 million per year. An important element for successful flow control, which can lead to a reduced aerodynamic drag, is enhanced physical understanding of the transition to turbulence process.
In previous wind tunnel measurements we have shown that roughness elements can be used to sensibly delay transition to turbulence. The result is revolutionary, since the common belief has been that surface roughness causes earlier transition and in turn increases the drag, and is a proof of concept of the passive control method per se. The beauty with a passive control technique is that no external energy has to be added to the flow system in order to perform the control, instead one uses the existing energy in the flow.
In this project proposal, AFRODITE, we will take this passive control method to the next level by making it twofold, more persistent and more robust. Transition prevention is the goal rather than transition delay and the method will be extended to simultaneously control separation, which is another unwanted flow phenomenon especially during airplane take offs. AFRODITE will be a catalyst for innovative research, which will lead to a cleaner sky.
Summary
A hot topic in today's debate on global warming is drag reduction in aeronautics. The most beneficial concept for drag reduction is to maintain the major portion of the airfoil laminar. Estimations show that the potential drag reduction can be as much as 15%, which would give a significant reduction of NOx and CO emissions in the atmosphere considering that the number of aircraft take offs, only in the EU, is over 19 million per year. An important element for successful flow control, which can lead to a reduced aerodynamic drag, is enhanced physical understanding of the transition to turbulence process.
In previous wind tunnel measurements we have shown that roughness elements can be used to sensibly delay transition to turbulence. The result is revolutionary, since the common belief has been that surface roughness causes earlier transition and in turn increases the drag, and is a proof of concept of the passive control method per se. The beauty with a passive control technique is that no external energy has to be added to the flow system in order to perform the control, instead one uses the existing energy in the flow.
In this project proposal, AFRODITE, we will take this passive control method to the next level by making it twofold, more persistent and more robust. Transition prevention is the goal rather than transition delay and the method will be extended to simultaneously control separation, which is another unwanted flow phenomenon especially during airplane take offs. AFRODITE will be a catalyst for innovative research, which will lead to a cleaner sky.
Max ERC Funding
1 418 399 €
Duration
Start date: 2010-11-01, End date: 2015-10-31
Project acronym ALMA
Project Attosecond Control of Light and Matter
Researcher (PI) Anne L'huillier
Host Institution (HI) LUNDS UNIVERSITET
Call Details Advanced Grant (AdG), PE2, ERC-2008-AdG
Summary Attosecond light pulses are generated when an intense laser interacts with a gas target. These pulses are not only short, enabling the study of electronic processes at their natural time scale, but also coherent. The vision of this proposal is to extend temporal coherent control concepts to a completely new regime of time and energy, combining (i) ultrashort pulses (ii) broadband excitation (iii) high photon energy, allowing scientists to reach not only valence but also inner shells in atoms and molecules, and, when needed, (iv) high spatial resolution. We want to explore how elementary electronic processes in atoms, molecules and more complex systems can be controlled by using well designed sequences of attosecond pulses. The research project proposed is organized into four parts: 1. Attosecond control of light leading to controlled sequences of attosecond pulses We will develop techniques to generate sequences of attosecond pulses with a variable number of pulses and controlled carrier-envelope-phase variation between consecutive pulses. 2. Attosecond control of electronic processes in atoms and molecules We will investigate the dynamics and coherence of phenomena induced by attosecond excitation of electron wave packets in various systems and we will explore how they can be controlled by a controlled sequence of ultrashort pulses. 3. Intense attosecond sources to reach the nonlinear regime We will optimize attosecond light sources in a systematic way, including amplification of the radiation by injecting a free electron laser. This will open up the possibility to develop nonlinear measurement and control schemes. 4. Attosecond control in more complex systems, including high spatial resolution We will develop ultrafast microscopy techniques, in order to obtain meaningful temporal information in surface and solid state physics. Two directions will be explored, digital in line microscopic holography and photoemission electron microscopy.
Summary
Attosecond light pulses are generated when an intense laser interacts with a gas target. These pulses are not only short, enabling the study of electronic processes at their natural time scale, but also coherent. The vision of this proposal is to extend temporal coherent control concepts to a completely new regime of time and energy, combining (i) ultrashort pulses (ii) broadband excitation (iii) high photon energy, allowing scientists to reach not only valence but also inner shells in atoms and molecules, and, when needed, (iv) high spatial resolution. We want to explore how elementary electronic processes in atoms, molecules and more complex systems can be controlled by using well designed sequences of attosecond pulses. The research project proposed is organized into four parts: 1. Attosecond control of light leading to controlled sequences of attosecond pulses We will develop techniques to generate sequences of attosecond pulses with a variable number of pulses and controlled carrier-envelope-phase variation between consecutive pulses. 2. Attosecond control of electronic processes in atoms and molecules We will investigate the dynamics and coherence of phenomena induced by attosecond excitation of electron wave packets in various systems and we will explore how they can be controlled by a controlled sequence of ultrashort pulses. 3. Intense attosecond sources to reach the nonlinear regime We will optimize attosecond light sources in a systematic way, including amplification of the radiation by injecting a free electron laser. This will open up the possibility to develop nonlinear measurement and control schemes. 4. Attosecond control in more complex systems, including high spatial resolution We will develop ultrafast microscopy techniques, in order to obtain meaningful temporal information in surface and solid state physics. Two directions will be explored, digital in line microscopic holography and photoemission electron microscopy.
Max ERC Funding
2 250 000 €
Duration
Start date: 2008-12-01, End date: 2013-11-30
Project acronym ALPAM
Project Atomic-Level Physics of Advanced Materials
Researcher (PI) Börje Johansson
Host Institution (HI) KUNGLIGA TEKNISKA HOEGSKOLAN
Call Details Advanced Grant (AdG), PE5, ERC-2008-AdG
Summary Most of the technological materials have been developed by very expensive and cumbersome trial and error methods. On the other hand, computer based theoretical design of advanced materials is an area where rapid and extensive developments are taking place. Within my group new theoretical tools have now been established which are extremely well suited to the study of complex materials. In this approach basic quantum mechanical theories are used to describe fundamental properties of alloys and compounds. The utilization of such calculations to investigate possible optimizations of certain key properties represents a major departure from the traditional design philosophy. The purpose of my project is to build up a new competence in the field of computer-aided simulations of advanced materials. The main goal will be to achieve a deep understanding of the behaviour of complex metallic systems under equilibrium and non-equilibrium conditions at the atomic level by studying their electronic, magnetic and atomic structure using the most modern and advanced computational methods. This will enable us to establish a set of materials parameters and composition-structure-property relations that are needed for materials optimization.
The research will be focused on fundamental technological properties related to defects in advanced metallic alloys (high-performance steels, superalloys, and refractory, energy related and geochemical materials) and alloy phases (solid solutions, intermetallic compounds), which will be studied by means of parameter free atomistic simulations combined with continuum modelling. As a first example, we will study the Fe-Cr system, which is of great interest to industry as well as in connection to nuclear waste. The Fe-Cr-Ni system will form another large group of materials under the aegis of this project. Special emphasis will also be placed on those Fe-alloys which exist under extreme conditions and are possible candidates for the Earth core.
Summary
Most of the technological materials have been developed by very expensive and cumbersome trial and error methods. On the other hand, computer based theoretical design of advanced materials is an area where rapid and extensive developments are taking place. Within my group new theoretical tools have now been established which are extremely well suited to the study of complex materials. In this approach basic quantum mechanical theories are used to describe fundamental properties of alloys and compounds. The utilization of such calculations to investigate possible optimizations of certain key properties represents a major departure from the traditional design philosophy. The purpose of my project is to build up a new competence in the field of computer-aided simulations of advanced materials. The main goal will be to achieve a deep understanding of the behaviour of complex metallic systems under equilibrium and non-equilibrium conditions at the atomic level by studying their electronic, magnetic and atomic structure using the most modern and advanced computational methods. This will enable us to establish a set of materials parameters and composition-structure-property relations that are needed for materials optimization.
The research will be focused on fundamental technological properties related to defects in advanced metallic alloys (high-performance steels, superalloys, and refractory, energy related and geochemical materials) and alloy phases (solid solutions, intermetallic compounds), which will be studied by means of parameter free atomistic simulations combined with continuum modelling. As a first example, we will study the Fe-Cr system, which is of great interest to industry as well as in connection to nuclear waste. The Fe-Cr-Ni system will form another large group of materials under the aegis of this project. Special emphasis will also be placed on those Fe-alloys which exist under extreme conditions and are possible candidates for the Earth core.
Max ERC Funding
2 000 000 €
Duration
Start date: 2009-03-01, End date: 2014-02-28
Project acronym AMIMOS
Project Agile MIMO Systems for Communications, Biomedicine, and Defense
Researcher (PI) Bjorn Ottersten
Host Institution (HI) KUNGLIGA TEKNISKA HOEGSKOLAN
Call Details Advanced Grant (AdG), PE7, ERC-2008-AdG
Summary This proposal targets the emerging frontier research field of multiple-input multiple-output (MIMO) systems along with several innovative and somewhat unconventional applications of such systems. The use of arrays of transmitters and receivers will have a profound impact on future medical imaging/therapy systems, radar systems, and radio communication networks. Multiple transmitters provide a tremendous versatility and allow waveforms to be adapted temporally and spatially to environmental conditions. This is useful for individually tailored illumination of human tissue in biomedical imaging or ultrasound therapy. In radar systems, multiple transmit beams can be formed simultaneously via separate waveform designs allowing accurate target classification. In a wireless communication system, multiple communication signals can be directed to one or more users at the same time on the same frequency carrier. In addition, multiple receivers can be used in the above applications to provide increased detection performance, interference rejection, and improved estimation accuracy. The joint modelling, analysis, and design of these multidimensional transmit and receive schemes form the core of this research proposal. Ultimately, our research aims at developing the fundamental tools that will allow the design of wireless communication systems with an order-of-magnitude higher capacity at a lower cost than today; of ultrasound therapy systems maximizing delivered power while reducing treatment duration and unwanted illumination; and of distributed aperture multi-beam radars allowing more effective target location, identification, and classification. Europe has several successful industries that are active in biomedical imaging/therapy, radar systems, and wireless communications. The future success of these sectors critically depends on the ability to innovate and integrate new technology.
Summary
This proposal targets the emerging frontier research field of multiple-input multiple-output (MIMO) systems along with several innovative and somewhat unconventional applications of such systems. The use of arrays of transmitters and receivers will have a profound impact on future medical imaging/therapy systems, radar systems, and radio communication networks. Multiple transmitters provide a tremendous versatility and allow waveforms to be adapted temporally and spatially to environmental conditions. This is useful for individually tailored illumination of human tissue in biomedical imaging or ultrasound therapy. In radar systems, multiple transmit beams can be formed simultaneously via separate waveform designs allowing accurate target classification. In a wireless communication system, multiple communication signals can be directed to one or more users at the same time on the same frequency carrier. In addition, multiple receivers can be used in the above applications to provide increased detection performance, interference rejection, and improved estimation accuracy. The joint modelling, analysis, and design of these multidimensional transmit and receive schemes form the core of this research proposal. Ultimately, our research aims at developing the fundamental tools that will allow the design of wireless communication systems with an order-of-magnitude higher capacity at a lower cost than today; of ultrasound therapy systems maximizing delivered power while reducing treatment duration and unwanted illumination; and of distributed aperture multi-beam radars allowing more effective target location, identification, and classification. Europe has several successful industries that are active in biomedical imaging/therapy, radar systems, and wireless communications. The future success of these sectors critically depends on the ability to innovate and integrate new technology.
Max ERC Funding
1 872 720 €
Duration
Start date: 2009-01-01, End date: 2013-12-31
Project acronym APPROXNP
Project Approximation of NP-hard optimization problems
Researcher (PI) Johan Håstad
Host Institution (HI) KUNGLIGA TEKNISKA HOEGSKOLAN
Call Details Advanced Grant (AdG), PE6, ERC-2008-AdG
Summary The proposed project aims to create a center of excellence that aims at understanding the approximability of NP-hard optimization problems. In particular, for central problems like vertex cover, coloring of graphs, and various constraint satisfaction problems we want to study upper and lower bounds on how well they can be approximated in polynomial time. Many existing strong results are based on what is known as the Unique Games Conjecture (UGC) and a significant part of the project will be devoted to studying this conjecture. We expect that a major step needed to be taken in this process is to further develop the understanding of Boolean functions on the Boolean hypercube. We anticipate that the tools needed for this will come in the form of harmonic analysis which in its turn will rely on the corresponding results in the analysis of functions over the domain of real numbers.
Summary
The proposed project aims to create a center of excellence that aims at understanding the approximability of NP-hard optimization problems. In particular, for central problems like vertex cover, coloring of graphs, and various constraint satisfaction problems we want to study upper and lower bounds on how well they can be approximated in polynomial time. Many existing strong results are based on what is known as the Unique Games Conjecture (UGC) and a significant part of the project will be devoted to studying this conjecture. We expect that a major step needed to be taken in this process is to further develop the understanding of Boolean functions on the Boolean hypercube. We anticipate that the tools needed for this will come in the form of harmonic analysis which in its turn will rely on the corresponding results in the analysis of functions over the domain of real numbers.
Max ERC Funding
2 376 000 €
Duration
Start date: 2009-01-01, End date: 2014-12-31
Project acronym AXION
Project Axions: From Heaven to Earth
Researcher (PI) Frank Wilczek
Host Institution (HI) STOCKHOLMS UNIVERSITET
Call Details Advanced Grant (AdG), PE2, ERC-2016-ADG
Summary Axions are hypothetical particles whose existence would solve two major problems: the strong P, T problem (a major blemish on the standard model); and the dark matter problem. It is a most important goal to either observe or rule out the existence of a cosmic axion background. It appears that decisive observations may be possible, but only after orchestrating insight from specialities ranging from quantum field theory and astrophysical modeling to ultra-low noise quantum measurement theory. Detailed predictions for the magnitude and structure of the cosmic axion background depend on cosmological and astrophysical modeling, which can be constrained by theoretical insight and numerical simulation. In parallel, we must optimize strategies for extracting accessible signals from that very weakly interacting source.
While the existence of axions as fundamental particles remains hypothetical, the equations governing how axions interact with electromagnetic fields also govern (with different parameters) how certain materials interact with electromagnetic fields. Thus those materials embody “emergent” axions. The equations have remarkable properties, which one can test in these materials, and possibly put to practical use.
Closely related to axions, mathematically, are anyons. Anyons are particle-like excitations that elude the familiar classification into bosons and fermions. Theoretical and numerical studies indicate that they are common emergent features of highly entangled states of matter in two dimensions. Recent work suggests the existence of states of matter, both natural and engineered, in which anyon dynamics is both important and experimentally accessible. Since the equations for anyons and axions are remarkably similar, and both have common, deep roots in symmetry and topology, it will be fruitful to consider them together.
Summary
Axions are hypothetical particles whose existence would solve two major problems: the strong P, T problem (a major blemish on the standard model); and the dark matter problem. It is a most important goal to either observe or rule out the existence of a cosmic axion background. It appears that decisive observations may be possible, but only after orchestrating insight from specialities ranging from quantum field theory and astrophysical modeling to ultra-low noise quantum measurement theory. Detailed predictions for the magnitude and structure of the cosmic axion background depend on cosmological and astrophysical modeling, which can be constrained by theoretical insight and numerical simulation. In parallel, we must optimize strategies for extracting accessible signals from that very weakly interacting source.
While the existence of axions as fundamental particles remains hypothetical, the equations governing how axions interact with electromagnetic fields also govern (with different parameters) how certain materials interact with electromagnetic fields. Thus those materials embody “emergent” axions. The equations have remarkable properties, which one can test in these materials, and possibly put to practical use.
Closely related to axions, mathematically, are anyons. Anyons are particle-like excitations that elude the familiar classification into bosons and fermions. Theoretical and numerical studies indicate that they are common emergent features of highly entangled states of matter in two dimensions. Recent work suggests the existence of states of matter, both natural and engineered, in which anyon dynamics is both important and experimentally accessible. Since the equations for anyons and axions are remarkably similar, and both have common, deep roots in symmetry and topology, it will be fruitful to consider them together.
Max ERC Funding
2 324 391 €
Duration
Start date: 2017-09-01, End date: 2022-08-31
Project acronym CC-MEM
Project Coordination and Composability: The Keys to Efficient Memory System Design
Researcher (PI) David BLACK-SCHAFFER
Host Institution (HI) UPPSALA UNIVERSITET
Call Details Starting Grant (StG), PE6, ERC-2016-STG
Summary Computer systems today are power limited. As a result, efficiency gains can be translated into performance. Over the past decade we have been so effective at making computation more efficient that we are now at the point where we spend as much energy moving data (from memory to cache to processor) as we do computing the results. And this trend is only becoming worse as we demand more bandwidth for more powerful processors. To improve performance we need to revisit the way we design memory systems from an energy-first perspective, both at the hardware level and by coordinating data movement between hardware and software.
CC-MEM will address memory system efficiency by redesigning low-level hardware and high-level hardware/software integration for energy efficiency. The key novelty is in developing a framework for creating efficient memory systems. This framework will enable researchers and designers to compose solutions to different memory system problems (through a shared exchange of metadata) and coordinate them towards high-level system efficiency goals (through a shared policy framework). Central to this framework is a bilateral exchange of metadata and policy between hardware and software components. This novel communication will open new challenges and opportunities for fine-grained optimizations, system-level efficiency metrics, and more effective divisions of responsibility between hardware and software components.
CC-MEM will change how researchers and designers approach memory system design from today’s ad hoc development of local solutions to one wherein disparate components can be integrated (composed) and driven (coordinated) by system-level metrics. As a result, we will be able to more intelligently manage data, leading to dramatically lower memory system energy and increased performance, and open new possibilities for hardware and software optimizations.
Summary
Computer systems today are power limited. As a result, efficiency gains can be translated into performance. Over the past decade we have been so effective at making computation more efficient that we are now at the point where we spend as much energy moving data (from memory to cache to processor) as we do computing the results. And this trend is only becoming worse as we demand more bandwidth for more powerful processors. To improve performance we need to revisit the way we design memory systems from an energy-first perspective, both at the hardware level and by coordinating data movement between hardware and software.
CC-MEM will address memory system efficiency by redesigning low-level hardware and high-level hardware/software integration for energy efficiency. The key novelty is in developing a framework for creating efficient memory systems. This framework will enable researchers and designers to compose solutions to different memory system problems (through a shared exchange of metadata) and coordinate them towards high-level system efficiency goals (through a shared policy framework). Central to this framework is a bilateral exchange of metadata and policy between hardware and software components. This novel communication will open new challenges and opportunities for fine-grained optimizations, system-level efficiency metrics, and more effective divisions of responsibility between hardware and software components.
CC-MEM will change how researchers and designers approach memory system design from today’s ad hoc development of local solutions to one wherein disparate components can be integrated (composed) and driven (coordinated) by system-level metrics. As a result, we will be able to more intelligently manage data, leading to dramatically lower memory system energy and increased performance, and open new possibilities for hardware and software optimizations.
Max ERC Funding
1 610 000 €
Duration
Start date: 2017-03-01, End date: 2022-02-28
Project acronym COOPNET
Project Cooperative Situational Awareness for Wireless Networks
Researcher (PI) Henk Wymeersch
Host Institution (HI) CHALMERS TEKNISKA HOEGSKOLA AB
Call Details Starting Grant (StG), PE7, ERC-2010-StG_20091028
Summary Devices in wireless networks are no longer used only for communicating binary information, but also for navigation and to sense their surroundings. We are currently approaching fundamental limitations in terms of communication throughput, position information availability and accuracy, and decision making based on sensory data. The goal of this proposal is to understand how the cooperative nature of future wireless networks can be leveraged to perform timekeeping, positioning, communication, and decision making, so as to obtain orders of magnitude performance improvements compared to current architectures.
Our research will have implications in many fields and will comprise fundamental theoretical contributions as well as a cooperative wireless testbed. The fundamental contributions will lead to a deep understanding of cooperative wireless networks and will enable new pervasive applications which currently cannot be supported. The testbed will be used to validate the research, and will serve as a kernel for other researchers worldwide to advance knowledge on cooperative networks. Our work will build on and consolidate knowledge currently dispersed in different scientific disciplines and communities (such as communication theory, sensor networks, distributed estimation and detection, environmental monitoring, control theory, positioning and timekeeping, distributed optimization). It will give a new thrust to research within those communities and forge relations between them.
Summary
Devices in wireless networks are no longer used only for communicating binary information, but also for navigation and to sense their surroundings. We are currently approaching fundamental limitations in terms of communication throughput, position information availability and accuracy, and decision making based on sensory data. The goal of this proposal is to understand how the cooperative nature of future wireless networks can be leveraged to perform timekeeping, positioning, communication, and decision making, so as to obtain orders of magnitude performance improvements compared to current architectures.
Our research will have implications in many fields and will comprise fundamental theoretical contributions as well as a cooperative wireless testbed. The fundamental contributions will lead to a deep understanding of cooperative wireless networks and will enable new pervasive applications which currently cannot be supported. The testbed will be used to validate the research, and will serve as a kernel for other researchers worldwide to advance knowledge on cooperative networks. Our work will build on and consolidate knowledge currently dispersed in different scientific disciplines and communities (such as communication theory, sensor networks, distributed estimation and detection, environmental monitoring, control theory, positioning and timekeeping, distributed optimization). It will give a new thrust to research within those communities and forge relations between them.
Max ERC Funding
1 500 000 €
Duration
Start date: 2011-05-01, End date: 2016-04-30
Project acronym DisDyn
Project Distributed and Dynamic Graph Algorithms and Complexity
Researcher (PI) Danupon NA NONGKAI
Host Institution (HI) KUNGLIGA TEKNISKA HOEGSKOLAN
Call Details Starting Grant (StG), PE6, ERC-2016-STG
Summary This project aims to (i) resolve challenging graph problems in distributed and dynamic settings, with a focus on connectivity problems (such as computing edge connectivity and distances), and (ii) on the way develop a systematic approach to attack problems in these settings, by thoroughly exploring relevant algorithmic and complexity-theoretic landscapes. Tasks include
- building a hierarchy of intermediate computational models so that designing algorithms and proving lower bounds can be done in several intermediate steps,
- explaining the limits of algorithms by proving conditional lower bounds based on old and new reasonable conjectures, and
- connecting techniques in the two settings to generate new insights that are unlikely to emerge from the isolated viewpoint of a single field.
The project will take advantage from and contribute to the developments in many young fields in theoretical computer science, such as fine-grained complexity and sublinear algorithms. Resolving one of the connectivity problems will already be a groundbreaking result. However, given the approach, it is likely that one breakthrough will lead to many others.
Summary
This project aims to (i) resolve challenging graph problems in distributed and dynamic settings, with a focus on connectivity problems (such as computing edge connectivity and distances), and (ii) on the way develop a systematic approach to attack problems in these settings, by thoroughly exploring relevant algorithmic and complexity-theoretic landscapes. Tasks include
- building a hierarchy of intermediate computational models so that designing algorithms and proving lower bounds can be done in several intermediate steps,
- explaining the limits of algorithms by proving conditional lower bounds based on old and new reasonable conjectures, and
- connecting techniques in the two settings to generate new insights that are unlikely to emerge from the isolated viewpoint of a single field.
The project will take advantage from and contribute to the developments in many young fields in theoretical computer science, such as fine-grained complexity and sublinear algorithms. Resolving one of the connectivity problems will already be a groundbreaking result. However, given the approach, it is likely that one breakthrough will lead to many others.
Max ERC Funding
1 500 000 €
Duration
Start date: 2017-02-01, End date: 2022-01-31
Project acronym ELECTRONOPERA
Project Electron dynamics to the Attosecond time scale and Angstrom length scale on low dimensional structures in Operation
Researcher (PI) Anders Mikkelsen
Host Institution (HI) LUNDS UNIVERSITET
Call Details Starting Grant (StG), PE3, ERC-2010-StG_20091028
Summary We will develop and use imaging techniques for direct probing of electron dynamics in low dimensional structures with orders of
magnitude improvements in time and spatial resolution. We will perform our measurements not only on static structures, but on
complex structures under operating conditions. Finally as our equipment can also probe structural properties from microns to
single atom defects we can directly correlate our observations of electron dynamics with knowledge of geometrical structure. We
hope to directly answer central questions in nanophysics on how complex geometric structure on several length-scales induces
new and surprising electron dynamics and thus properties in nanoscale objects.
The low dimensional semiconductors and metal (nano) structures studied will be chosen to have unique novel properties that will
have potential applications in IT, life-science and renewable energy.
To radically increase our diagnostics capabilities we will combine PhotoEmission Electron Microscopy and attosecond XUV/IR
laser technology to directly image surface electron dynamics with attosecond time resolution and nanometer lateral resolution.
Exploring a completely new realm in terms of timescale with nm resolution we will start with rather simple structure such as Au
nanoparticles and arrays nanoholes in ultrathin metal films, and gradually increase complexity.
As the first group in the world we have shown that atomic resolved structural and electrical measurements by Scanning Tunneling
Microscopy is possible on complex 1D semiconductors heterostructures. Importantly, our new method allows for direct studies of
nanowires in devices.
We can now measure atomic scale surface chemistry and surface electronic/geometric structure directly on operational/operating
nanoscale devices. This is important both from a technology point of view, and is an excellent playground for understanding the
fundamental interplay between electronic and structural properties.
Summary
We will develop and use imaging techniques for direct probing of electron dynamics in low dimensional structures with orders of
magnitude improvements in time and spatial resolution. We will perform our measurements not only on static structures, but on
complex structures under operating conditions. Finally as our equipment can also probe structural properties from microns to
single atom defects we can directly correlate our observations of electron dynamics with knowledge of geometrical structure. We
hope to directly answer central questions in nanophysics on how complex geometric structure on several length-scales induces
new and surprising electron dynamics and thus properties in nanoscale objects.
The low dimensional semiconductors and metal (nano) structures studied will be chosen to have unique novel properties that will
have potential applications in IT, life-science and renewable energy.
To radically increase our diagnostics capabilities we will combine PhotoEmission Electron Microscopy and attosecond XUV/IR
laser technology to directly image surface electron dynamics with attosecond time resolution and nanometer lateral resolution.
Exploring a completely new realm in terms of timescale with nm resolution we will start with rather simple structure such as Au
nanoparticles and arrays nanoholes in ultrathin metal films, and gradually increase complexity.
As the first group in the world we have shown that atomic resolved structural and electrical measurements by Scanning Tunneling
Microscopy is possible on complex 1D semiconductors heterostructures. Importantly, our new method allows for direct studies of
nanowires in devices.
We can now measure atomic scale surface chemistry and surface electronic/geometric structure directly on operational/operating
nanoscale devices. This is important both from a technology point of view, and is an excellent playground for understanding the
fundamental interplay between electronic and structural properties.
Max ERC Funding
1 419 120 €
Duration
Start date: 2010-10-01, End date: 2015-09-30
