Project acronym 3SPIN
Project Three Dimensional Spintronics
Researcher (PI) Russell Paul Cowburn
Host Institution (HI) THE CHANCELLOR MASTERS AND SCHOLARSOF THE UNIVERSITY OF CAMBRIDGE
Call Details Advanced Grant (AdG), PE3, ERC-2009-AdG
Summary Spintronics, in which both the spin and the charge of the electron are used, is one of the most exciting new disciplines to emerge from nanoscience. The 3SPIN project seeks to open a new research front within spintronics: namely 3-dimensional spintronics, in which magnetic nanostructures are formed into a 3-dimensional interacting network of unrivalled density and hence technological benefit. 3SPIN will explore early-stage science that could underpin 3-dimensional metallic spintronics. The thesis of the project is: that by careful control of the constituent nanostructure properties, a 3-dimensional medium can be created in which a large number of topological solitons can exist. Although hardly studied at all to date, these solitons should be stable at room temperature, extremely compact and easy to manipulate and propagate. This makes them potentially ideal candidates to form the basis of a new spintronics in which the soliton is the basic transport vector instead of electrical current. ¬3.5M of funding is requested to form a new team of 5 researchers who, over a period of 60 months, will perform computer simulations and experimental studies of solitons in 3-dimensional networks of magnetic nanostructures and develop a laboratory demonstrator 3-dimensional memory device using solitons to represent and store data. A high performance electron beam lithography system (cost 1M¬) will be purchased to allow state-of-the-art magnetic nanostructures to be fabricated with perfect control over their magnetic properties, thus allowing the ideal conditions for solitons to be created and controllably manipulated. Outputs from the project will be a complete understanding of the properties of these new objects and a road map charting the next steps for research in the field.
Summary
Spintronics, in which both the spin and the charge of the electron are used, is one of the most exciting new disciplines to emerge from nanoscience. The 3SPIN project seeks to open a new research front within spintronics: namely 3-dimensional spintronics, in which magnetic nanostructures are formed into a 3-dimensional interacting network of unrivalled density and hence technological benefit. 3SPIN will explore early-stage science that could underpin 3-dimensional metallic spintronics. The thesis of the project is: that by careful control of the constituent nanostructure properties, a 3-dimensional medium can be created in which a large number of topological solitons can exist. Although hardly studied at all to date, these solitons should be stable at room temperature, extremely compact and easy to manipulate and propagate. This makes them potentially ideal candidates to form the basis of a new spintronics in which the soliton is the basic transport vector instead of electrical current. ¬3.5M of funding is requested to form a new team of 5 researchers who, over a period of 60 months, will perform computer simulations and experimental studies of solitons in 3-dimensional networks of magnetic nanostructures and develop a laboratory demonstrator 3-dimensional memory device using solitons to represent and store data. A high performance electron beam lithography system (cost 1M¬) will be purchased to allow state-of-the-art magnetic nanostructures to be fabricated with perfect control over their magnetic properties, thus allowing the ideal conditions for solitons to be created and controllably manipulated. Outputs from the project will be a complete understanding of the properties of these new objects and a road map charting the next steps for research in the field.
Max ERC Funding
2 799 996 €
Duration
Start date: 2010-03-01, End date: 2016-02-29
Project acronym ADEQUATE
Project Advanced optoelectronic Devices with Enhanced QUAntum efficiency at THz frEquencies
Researcher (PI) Carlo Sirtori
Host Institution (HI) UNIVERSITE PARIS DIDEROT - PARIS 7
Call Details Advanced Grant (AdG), PE3, ERC-2009-AdG
Summary The aim of this project is the realisation of efficient mid-infrared and THz optoelectronic emitters. This work is motivated by the fact that the spontaneous emission in this frequency range is characterized by an extremely long lifetime when compared to non-radiative processes, giving rise to devices with very low quantum efficiency. To this end we want to develop hybrid light-matter systems, already well known in quantum optics, within optoelectronics devices, that will be driven by electrical injection. With this project we want to extend the field of optoelectronics by introducing some of the concepts of quantum optic, particularly the light-matter strong coupling, into semiconductor devices. More precisely this project aims at the implementation of novel optoelectronic emitters operating in the strong coupling regime between an intersubband excitation of a two-dimensional electron gas and a microcavity photonic mode. The quasiparticles issued from this coupling are called intersubband polaritons. The major difficulties and challenges of this project, do not lay in the observation of these quantum effects, but in their exploitation for a specific function, in particular an efficient electrical to optical conversion. To obtain efficient quantum emitters in the THz frequency range we will follow two different approaches: - In the first case we will try to exploit the additional characteristic time of the system introduced by the light-matter interaction in the strong (or ultra-strong) coupling regime. - The second approach will exploit the fact that, under certain conditions, intersubband polaritons have a bosonic character; as a consequence they can undergo stimulated scattering, giving rise to polaritons lasers as it has been shown for excitonic polaritons.
Summary
The aim of this project is the realisation of efficient mid-infrared and THz optoelectronic emitters. This work is motivated by the fact that the spontaneous emission in this frequency range is characterized by an extremely long lifetime when compared to non-radiative processes, giving rise to devices with very low quantum efficiency. To this end we want to develop hybrid light-matter systems, already well known in quantum optics, within optoelectronics devices, that will be driven by electrical injection. With this project we want to extend the field of optoelectronics by introducing some of the concepts of quantum optic, particularly the light-matter strong coupling, into semiconductor devices. More precisely this project aims at the implementation of novel optoelectronic emitters operating in the strong coupling regime between an intersubband excitation of a two-dimensional electron gas and a microcavity photonic mode. The quasiparticles issued from this coupling are called intersubband polaritons. The major difficulties and challenges of this project, do not lay in the observation of these quantum effects, but in their exploitation for a specific function, in particular an efficient electrical to optical conversion. To obtain efficient quantum emitters in the THz frequency range we will follow two different approaches: - In the first case we will try to exploit the additional characteristic time of the system introduced by the light-matter interaction in the strong (or ultra-strong) coupling regime. - The second approach will exploit the fact that, under certain conditions, intersubband polaritons have a bosonic character; as a consequence they can undergo stimulated scattering, giving rise to polaritons lasers as it has been shown for excitonic polaritons.
Max ERC Funding
1 761 000 €
Duration
Start date: 2010-05-01, End date: 2015-04-30
Project acronym ASD
Project Atomistic Spin-Dynamics; Methodology and Applications
Researcher (PI) Olof Ragnar Eriksson
Host Institution (HI) UPPSALA UNIVERSITET
Call Details Advanced Grant (AdG), PE3, ERC-2009-AdG
Summary Our aim is to provide a theoretical framework for studies of dynamical aspects of magnetic materials and magnetisation reversal, which has potential for applications for magnetic data storage and magnetic memory devices. The project focuses on developing and using an atomistic spin dynamics simulation method. Our goal is to identify novel materials and device geometries with improved performance. The scientific questions which will be addressed concern the understanding of the fundamental temporal limit of magnetisation switching and reversal, and the mechanisms which govern this limit. The methodological developments concern the ability to, from first principles theory, calculate the interatomic exchange parameters of materials in general, in particular for correlated electron materials, via the use of dynamical mean-field theory. The theoretical development also involves an atomistic spin dynamics simulation method, which once it has been established, will be released as a public software package. The proposed theoretical research will be intimately connected to world-leading experimental efforts, especially in Europe where a leading activity in experimental studies of magnetisation dynamics has been established. The ambition with this project is to become world-leading in the theory of simulating spin-dynamics phenomena, and to promote education and training of young researchers. To achieve our goals we will build up an open and lively environment, where the advances in the theoretical knowledge of spin-dynamics phenomena will be used to address important questions in information technology. In this environment the next generation research leaders will be fostered and trained, thus ensuring that the society of tomorrow is equipped with the scientific competence to tackle the challenges of our future.
Summary
Our aim is to provide a theoretical framework for studies of dynamical aspects of magnetic materials and magnetisation reversal, which has potential for applications for magnetic data storage and magnetic memory devices. The project focuses on developing and using an atomistic spin dynamics simulation method. Our goal is to identify novel materials and device geometries with improved performance. The scientific questions which will be addressed concern the understanding of the fundamental temporal limit of magnetisation switching and reversal, and the mechanisms which govern this limit. The methodological developments concern the ability to, from first principles theory, calculate the interatomic exchange parameters of materials in general, in particular for correlated electron materials, via the use of dynamical mean-field theory. The theoretical development also involves an atomistic spin dynamics simulation method, which once it has been established, will be released as a public software package. The proposed theoretical research will be intimately connected to world-leading experimental efforts, especially in Europe where a leading activity in experimental studies of magnetisation dynamics has been established. The ambition with this project is to become world-leading in the theory of simulating spin-dynamics phenomena, and to promote education and training of young researchers. To achieve our goals we will build up an open and lively environment, where the advances in the theoretical knowledge of spin-dynamics phenomena will be used to address important questions in information technology. In this environment the next generation research leaders will be fostered and trained, thus ensuring that the society of tomorrow is equipped with the scientific competence to tackle the challenges of our future.
Max ERC Funding
2 130 000 €
Duration
Start date: 2010-01-01, End date: 2014-12-31
Project acronym ATMOFLEX
Project Turbulent Transport in the Atmosphere: Fluctuations and Extreme Events
Researcher (PI) Jérémie Bec
Host Institution (HI) CENTRE NATIONAL DE LA RECHERCHE SCIENTIFIQUE CNRS
Call Details Starting Grant (StG), PE3, ERC-2009-StG
Summary A major part of the physical and chemical processes occurring in the atmosphere involves the turbulent transport of tiny particles. Current studies and models use a formulation in terms of mean fields, where the strong variations in the dynamical and statistical properties of the particles are neglected and where the underlying fluctuations of the fluid flow velocity are oversimplified. Devising an accurate understanding of the influence of air turbulence and of the extreme fluctuations that it generates in the dispersed phase remains a challenging issue. This project aims at coordinating and integrating theoretical, numerical, experimental, and observational efforts to develop a new statistical understanding of the role of fluctuations in atmospheric transport processes. The proposed work will cover individual as well as collective behaviors and will provide a systematic and unified description of targeted specific processes involving suspended drops or particles: the dispersion of pollutants from a source, the growth by condensation and coagulation of droplets and ice crystals in clouds, the scavenging, settling and re-suspension of aerosols, and the radiative and climatic effects of particles. The proposed approach is based on the use of tools borrowed from statistical physics and field theory, and from the theory of large deviations and of random dynamical systems in order to design new observables that will be simultaneously tractable analytically in simplified models and of relevance for the quantitative handling of such physical mechanisms. One of the outcomes will be to provide a new framework for improving and refining the methods used in meteorology and atmospheric sciences and to answer the long-standing question of the effects of suspended particles onto climate.
Summary
A major part of the physical and chemical processes occurring in the atmosphere involves the turbulent transport of tiny particles. Current studies and models use a formulation in terms of mean fields, where the strong variations in the dynamical and statistical properties of the particles are neglected and where the underlying fluctuations of the fluid flow velocity are oversimplified. Devising an accurate understanding of the influence of air turbulence and of the extreme fluctuations that it generates in the dispersed phase remains a challenging issue. This project aims at coordinating and integrating theoretical, numerical, experimental, and observational efforts to develop a new statistical understanding of the role of fluctuations in atmospheric transport processes. The proposed work will cover individual as well as collective behaviors and will provide a systematic and unified description of targeted specific processes involving suspended drops or particles: the dispersion of pollutants from a source, the growth by condensation and coagulation of droplets and ice crystals in clouds, the scavenging, settling and re-suspension of aerosols, and the radiative and climatic effects of particles. The proposed approach is based on the use of tools borrowed from statistical physics and field theory, and from the theory of large deviations and of random dynamical systems in order to design new observables that will be simultaneously tractable analytically in simplified models and of relevance for the quantitative handling of such physical mechanisms. One of the outcomes will be to provide a new framework for improving and refining the methods used in meteorology and atmospheric sciences and to answer the long-standing question of the effects of suspended particles onto climate.
Max ERC Funding
1 200 000 €
Duration
Start date: 2009-11-01, End date: 2014-10-31
Project acronym ATOMAG
Project From Attosecond Magnetism towards Ultrafast Spin Photonics
Researcher (PI) Jean-Yves Bigot
Host Institution (HI) CENTRE NATIONAL DE LA RECHERCHE SCIENTIFIQUE CNRS
Call Details Advanced Grant (AdG), PE3, ERC-2009-AdG
Summary We propose to investigate a new frontier in Physics: the study of Magnetic systems using attosecond laser pulses. The main disciplines concerned are: Ultrafast laser sciences, Magnetism and Spin-Photonics, Relativistic Quantum Electrodynamics. Three issues of modern magnetism are addressed. 1. How fast can one modify and control the magnetization of a magnetic system ? 2. What is the role and essence of the coherent interaction between light and spins ? 3. How far spin-photonics can bring us to the real world of data acquisition and storage ? - We want first to provide solid ground experiments, unravelling the mechanisms involved in the demagnetization induced by laser pulses in a variety of magnetic materials (ferromagnetic nanostructures, aggregates and molecular magnets). We will explore the ultrafast magnetization dynamics of magnets using an attosecond laser source. - Second we want to explore how the photon field interacts with the spins. We will investigate the dynamical regime when the potential of the atoms is dressed by the Coulomb potential induced by the laser field. A strong support from the relativistic Quantum Electro-Dynamics is necessary towards that goal. - Third, even though our general approach is fundamental, we want to provide a benchmark of what is realistically possible in ultrafast spin-photonics, breaking the conventional thought that spin photonics is hard to implement at the application level. We will realize ultimate devices combining magneto-optical microscopy with the conventional magnetic recording. This new field will raise the interest of a number of competitive laboratories at the international level. Due to the overlapping disciplines the project also carries a large amount of educational impact both fundamental and applied.
Summary
We propose to investigate a new frontier in Physics: the study of Magnetic systems using attosecond laser pulses. The main disciplines concerned are: Ultrafast laser sciences, Magnetism and Spin-Photonics, Relativistic Quantum Electrodynamics. Three issues of modern magnetism are addressed. 1. How fast can one modify and control the magnetization of a magnetic system ? 2. What is the role and essence of the coherent interaction between light and spins ? 3. How far spin-photonics can bring us to the real world of data acquisition and storage ? - We want first to provide solid ground experiments, unravelling the mechanisms involved in the demagnetization induced by laser pulses in a variety of magnetic materials (ferromagnetic nanostructures, aggregates and molecular magnets). We will explore the ultrafast magnetization dynamics of magnets using an attosecond laser source. - Second we want to explore how the photon field interacts with the spins. We will investigate the dynamical regime when the potential of the atoms is dressed by the Coulomb potential induced by the laser field. A strong support from the relativistic Quantum Electro-Dynamics is necessary towards that goal. - Third, even though our general approach is fundamental, we want to provide a benchmark of what is realistically possible in ultrafast spin-photonics, breaking the conventional thought that spin photonics is hard to implement at the application level. We will realize ultimate devices combining magneto-optical microscopy with the conventional magnetic recording. This new field will raise the interest of a number of competitive laboratories at the international level. Due to the overlapping disciplines the project also carries a large amount of educational impact both fundamental and applied.
Max ERC Funding
2 492 561 €
Duration
Start date: 2010-05-01, End date: 2015-04-30
Project acronym BIOCOMPLEX
Project Physical Aspects of the Evolution of Biological Complexity
Researcher (PI) Raymond Ethan Goldstein
Host Institution (HI) THE CHANCELLOR MASTERS AND SCHOLARSOF THE UNIVERSITY OF CAMBRIDGE
Call Details Advanced Grant (AdG), PE3, ERC-2009-AdG
Summary One of the most fundamental issues in evolutionary biology is the nature of transitions from single cell organisms to multicellular ones, with accompanying cellular differentiation and specialization. Not surprisingly for microscopic life in fluid environments, many of the relevant physical considerations involve diffusion, mixing, and sensing, for the efficient exchange of nutrients and metabolites with the environment is one of the most basic features of life. This proposal describes a combination of experimental and theoretical research aimed at some of the key mysteries surrounding transport and sensing by and in complex, multicellular organisms, and the implications of those findings for the explanation of driving forces behind transitions to multicellularity. There are two main components of the research. The first involves studies of single and multicellular algae which serves as model systems for allometric scaling laws in evolution. Of particular importance are the synchronization dynamics of the eukaryotic flagella that provide motility, enhance nutrient transport, and allow phototaxis in these organisms. The second thrust involves investigation of the ubiquitous phenomenon of cytoplasmic streaming in aquatic and terrestrial plants. Despite decades of research, there is no clear consensus on the metabolic role of this persistent circulation of the fluid contents of cell. Building on recent theoretical developmnts we will study its implications for internal transport and mixing, homeostasis, and development in large cells. In each case, state-of-the art experimental methods from physics, fluid dynamics, and cell biology will be used in combination with advanced theoretical methods for the study of the stochastic nonlinear PDEs that form the natural description of these systems.
Summary
One of the most fundamental issues in evolutionary biology is the nature of transitions from single cell organisms to multicellular ones, with accompanying cellular differentiation and specialization. Not surprisingly for microscopic life in fluid environments, many of the relevant physical considerations involve diffusion, mixing, and sensing, for the efficient exchange of nutrients and metabolites with the environment is one of the most basic features of life. This proposal describes a combination of experimental and theoretical research aimed at some of the key mysteries surrounding transport and sensing by and in complex, multicellular organisms, and the implications of those findings for the explanation of driving forces behind transitions to multicellularity. There are two main components of the research. The first involves studies of single and multicellular algae which serves as model systems for allometric scaling laws in evolution. Of particular importance are the synchronization dynamics of the eukaryotic flagella that provide motility, enhance nutrient transport, and allow phototaxis in these organisms. The second thrust involves investigation of the ubiquitous phenomenon of cytoplasmic streaming in aquatic and terrestrial plants. Despite decades of research, there is no clear consensus on the metabolic role of this persistent circulation of the fluid contents of cell. Building on recent theoretical developmnts we will study its implications for internal transport and mixing, homeostasis, and development in large cells. In each case, state-of-the art experimental methods from physics, fluid dynamics, and cell biology will be used in combination with advanced theoretical methods for the study of the stochastic nonlinear PDEs that form the natural description of these systems.
Max ERC Funding
2 500 000 €
Duration
Start date: 2010-01-01, End date: 2015-12-31
Project acronym FLATRONICS
Project Electronic devices based on nanolayers
Researcher (PI) Andras Kis
Host Institution (HI) ECOLE POLYTECHNIQUE FEDERALE DE LAUSANNE
Call Details Starting Grant (StG), PE3, ERC-2009-StG
Summary The main objective of this research proposal is to explore the electrical properties of nanoscale devices and circuits based on nanolayers. Nanolayers cover a wide span of possible electronic properties, ranging from semiconducting to superconducting. The possibility to form electrical circuits by varying their geometry offers rich research and practical opportunities. Together with graphene, nanolayers could form the material library for future nanoelectronics where different materials could be mixed and matched to different functionalities.
Summary
The main objective of this research proposal is to explore the electrical properties of nanoscale devices and circuits based on nanolayers. Nanolayers cover a wide span of possible electronic properties, ranging from semiconducting to superconducting. The possibility to form electrical circuits by varying their geometry offers rich research and practical opportunities. Together with graphene, nanolayers could form the material library for future nanoelectronics where different materials could be mixed and matched to different functionalities.
Max ERC Funding
1 799 996 €
Duration
Start date: 2009-09-01, End date: 2014-08-31
Project acronym HEATTRONICS
Project Mesoscopic heattronics: thermal and nonequilibrium effects and fluctuations in nanoelectronics
Researcher (PI) Tero Tapio Heikkilä
Host Institution (HI) JYVASKYLAN YLIOPISTO
Call Details Starting Grant (StG), PE3, ERC-2009-StG
Summary Few systems in nature are entirely in equilibrium. Out of equilibrium, there are heat currents, and different degrees of freedom or parts of studied systems may be described by entirely different temperatures if the concept of temperature is at all well defined. In this project we will study the emergence of the subsystem temperatures in different types of small electronic systems, and the physical phenomena associated with those temperatures. Our emphasis is on the mesoscopic effects, residing between the microscopic world of individual atoms and electrons, and the macroscopic everyday world. In particular, we will research thermometry methods, different types of relaxation, magnitudes of fluctuations and effects at high frequencies. We will explore these effects in a wide variety of systems: normal metals and superconductors, carbon nanostructures, nanoelectromechanical and spintronic systems. Besides contributing to the understanding of the fundamental properties of electronic systems, our studies are directly relevant for the development of thermal sensors and electron refrigerators. The improved understanding of the thermal phenomena will also benefit the study of almost any type of a nonlinear phenomenon in electronics, for example the research of solid-state realizations of quantum computing or the race towards quantum limited mass and force detection.
Summary
Few systems in nature are entirely in equilibrium. Out of equilibrium, there are heat currents, and different degrees of freedom or parts of studied systems may be described by entirely different temperatures if the concept of temperature is at all well defined. In this project we will study the emergence of the subsystem temperatures in different types of small electronic systems, and the physical phenomena associated with those temperatures. Our emphasis is on the mesoscopic effects, residing between the microscopic world of individual atoms and electrons, and the macroscopic everyday world. In particular, we will research thermometry methods, different types of relaxation, magnitudes of fluctuations and effects at high frequencies. We will explore these effects in a wide variety of systems: normal metals and superconductors, carbon nanostructures, nanoelectromechanical and spintronic systems. Besides contributing to the understanding of the fundamental properties of electronic systems, our studies are directly relevant for the development of thermal sensors and electron refrigerators. The improved understanding of the thermal phenomena will also benefit the study of almost any type of a nonlinear phenomenon in electronics, for example the research of solid-state realizations of quantum computing or the race towards quantum limited mass and force detection.
Max ERC Funding
1 322 371 €
Duration
Start date: 2010-01-01, End date: 2015-12-31
Project acronym HI-ONE
Project Hybrid Inorganic-Organic NanoElectronics
Researcher (PI) Wilfred Gerard Van Der Wiel
Host Institution (HI) UNIVERSITEIT TWENTE
Call Details Starting Grant (StG), PE3, ERC-2009-StG
Summary This project aims at combining inorganic and organic materials in hybrid nanoelectronic structures for addressing a set of key problems in solid-state physics: (1) the magnetic ordering of 2D spin systems and their interaction with conduction electrons, (2) the coherent transport properties of organic molecules, and (3) reliable electronic characterization of single nanostructures. For all objectives we will integrate top-down and bottom-up (self-assembly) techniques, benefitting from strong collaborations with leading chemistry groups. For Objective 1, we will apply self-assembled monolayers of organic paramagnetic molecules on various substrates. This geometry offers great tunability for the nature, density and ordering of spins, and for their interaction with underlying electrons. We will study (many-body) phenomena that lie at the very heart of solid-state physics: the Kondo effect, RKKY interaction, spin glasses and the 2D Ising/Heisenberg model, addressing open questions concerning the extension of the Kondo cloud, RKKY-Kondo competition, and the relevance for high-Tc superconductivity. For Objective 2, molecular monolayers are inserted in an electron interferometer, allowing a systematic study of molecular charge coherence. We will study how coherence depends on the molecule s characteristics, such as length and chemical composition. For Objective 3 we will attach single nanostructures (quantum dots) by an innovative self-assembly method to highly-conductive, selectively metallized DNA molecules, bridging the gap between nano and micro. A crucial advantage compared to conventional (top-down) nanocontacting schemes is the high control and reproducibility afforded by sequence-specificity of DNA hybridization, enabling a wide range of fascinating experiments.
Summary
This project aims at combining inorganic and organic materials in hybrid nanoelectronic structures for addressing a set of key problems in solid-state physics: (1) the magnetic ordering of 2D spin systems and their interaction with conduction electrons, (2) the coherent transport properties of organic molecules, and (3) reliable electronic characterization of single nanostructures. For all objectives we will integrate top-down and bottom-up (self-assembly) techniques, benefitting from strong collaborations with leading chemistry groups. For Objective 1, we will apply self-assembled monolayers of organic paramagnetic molecules on various substrates. This geometry offers great tunability for the nature, density and ordering of spins, and for their interaction with underlying electrons. We will study (many-body) phenomena that lie at the very heart of solid-state physics: the Kondo effect, RKKY interaction, spin glasses and the 2D Ising/Heisenberg model, addressing open questions concerning the extension of the Kondo cloud, RKKY-Kondo competition, and the relevance for high-Tc superconductivity. For Objective 2, molecular monolayers are inserted in an electron interferometer, allowing a systematic study of molecular charge coherence. We will study how coherence depends on the molecule s characteristics, such as length and chemical composition. For Objective 3 we will attach single nanostructures (quantum dots) by an innovative self-assembly method to highly-conductive, selectively metallized DNA molecules, bridging the gap between nano and micro. A crucial advantage compared to conventional (top-down) nanocontacting schemes is the high control and reproducibility afforded by sequence-specificity of DNA hybridization, enabling a wide range of fascinating experiments.
Max ERC Funding
1 750 000 €
Duration
Start date: 2009-12-01, End date: 2014-11-30
Project acronym HYBRIDQED
Project Hybrid Cavity Quantum Electrodynamics with Atoms and Circuits
Researcher (PI) Andreas Joachim Wallraff
Host Institution (HI) EIDGENOESSISCHE TECHNISCHE HOCHSCHULE ZUERICH
Call Details Starting Grant (StG), PE3, ERC-2009-StG
Summary We plan to investigate the strong coherent interaction of light and matter on the level of individual photons and atoms or atom-like systems. In particular, we will explore large dipole moment superconducting artificial atoms and natural Rydberg atoms interacting with radiation fields contained in quasi-one-dimensional on-chip microwave frequency resonators. In these resonators photons generate field strengths that exceed those in conventional mirror based resonators by orders of magnitude and they can also be stored for long times. This allows us to reach the strong coupling limit of cavity quantum electrodynamics (QED) using superconducting circuits, an approach known as circuit QED. In this project we will explore novel approaches to perform quantum optics experiments in circuits. We will develop techniques to generate and detect non-classical radiation fields using nonlinear resonators and chip-based interferometers. We will also further advance the circuit QED approach to quantum information processing. Our main goal is to develop an interface between circuit and atom based realizations of cavity QED. In particular, we will couple Rydberg atoms to on-chip resonators. To achieve this goal we will first investigate the interaction of ensembles of atoms in a beam with the coherent fields in a transmission line or a resonator. We will perform spectroscopy and we will investigate on-chip dispersive detection schemes for Rydberg atoms. We will also explore the interaction of Rydberg atoms with chip surfaces in dependence on materials, temperature and geometry. Experiments will be performed from 300 K down to millikelvin temperatures. We will realize and characterize on-chip traps for Rydberg atoms. Using trapped atoms we will explore their coherent dynamics. Finally, we aim at investigating the single atom and single photon limit. When realized, this system will be used to explore the first quantum coherent interface between atomic and solid state qubits.
Summary
We plan to investigate the strong coherent interaction of light and matter on the level of individual photons and atoms or atom-like systems. In particular, we will explore large dipole moment superconducting artificial atoms and natural Rydberg atoms interacting with radiation fields contained in quasi-one-dimensional on-chip microwave frequency resonators. In these resonators photons generate field strengths that exceed those in conventional mirror based resonators by orders of magnitude and they can also be stored for long times. This allows us to reach the strong coupling limit of cavity quantum electrodynamics (QED) using superconducting circuits, an approach known as circuit QED. In this project we will explore novel approaches to perform quantum optics experiments in circuits. We will develop techniques to generate and detect non-classical radiation fields using nonlinear resonators and chip-based interferometers. We will also further advance the circuit QED approach to quantum information processing. Our main goal is to develop an interface between circuit and atom based realizations of cavity QED. In particular, we will couple Rydberg atoms to on-chip resonators. To achieve this goal we will first investigate the interaction of ensembles of atoms in a beam with the coherent fields in a transmission line or a resonator. We will perform spectroscopy and we will investigate on-chip dispersive detection schemes for Rydberg atoms. We will also explore the interaction of Rydberg atoms with chip surfaces in dependence on materials, temperature and geometry. Experiments will be performed from 300 K down to millikelvin temperatures. We will realize and characterize on-chip traps for Rydberg atoms. Using trapped atoms we will explore their coherent dynamics. Finally, we aim at investigating the single atom and single photon limit. When realized, this system will be used to explore the first quantum coherent interface between atomic and solid state qubits.
Max ERC Funding
1 954 464 €
Duration
Start date: 2009-09-01, End date: 2014-08-31
