Project acronym AMETIST
Project Advanced III-V Materials and Processes Enabling Ultrahigh-efficiency ( 50%) Photovoltaics
Researcher (PI) Mircea Dorel GUINA
Host Institution (HI) TAMPEREEN KORKEAKOULUSAATIO SR
Country Finland
Call Details Advanced Grant (AdG), PE8, ERC-2015-AdG
Summary Compound semiconductor solar cells are providing the highest photovoltaic conversion efficiency, yet their performance lacks far behind the theoretical potential. This is a position we will challenge by engineering advanced III-V optoelectronics materials and heterostructures for better utilization of the solar spectrum, enabling efficiencies approaching practical limits. The work is strongly motivated by the global need for renewable energy sources. To this end, AMETIST framework is based on three vectors of excellence in: i) material science and epitaxial processes, ii) advanced solar cells exploiting nanophotonics concepts, and iii) new device fabrication technologies.
Novel heterostructures (e.g. GaInNAsSb, GaNAsBi), providing absorption in a broad spectral range from 0.7 eV to 1.4 eV, will be synthesized and monolithically integrated in tandem cells with up to 8-junctions. Nanophotonic methods for light-trapping, spectral and spatial control of solar radiation will be developed to further enhance the absorption. To ensure a high long-term impact, the project will validate the use of state-of-the-art molecular-beam-epitaxy processes for fabrication of economically viable ultra-high efficiency solar cells. The ultimate efficiency target is to reach a level of 55%. This would enable to generate renewable/ecological/sustainable energy at a levelized production cost below ~7 ¢/kWh, comparable or cheaper than fossil fuels. The work will also bring a new breath of developments for more efficient space photovoltaic systems.
AMETIST will leverage the leading position of the applicant in topical technology areas relevant for the project (i.e. epitaxy of III-N/Bi-V alloys and key achievements concerning GaInNAsSb-based tandem solar cells). Thus it renders a unique opportunity to capitalize on the group expertize and position Europe at the forefront in the global competition for demonstrating more efficient and economically viable photovoltaic technologies.
Summary
Compound semiconductor solar cells are providing the highest photovoltaic conversion efficiency, yet their performance lacks far behind the theoretical potential. This is a position we will challenge by engineering advanced III-V optoelectronics materials and heterostructures for better utilization of the solar spectrum, enabling efficiencies approaching practical limits. The work is strongly motivated by the global need for renewable energy sources. To this end, AMETIST framework is based on three vectors of excellence in: i) material science and epitaxial processes, ii) advanced solar cells exploiting nanophotonics concepts, and iii) new device fabrication technologies.
Novel heterostructures (e.g. GaInNAsSb, GaNAsBi), providing absorption in a broad spectral range from 0.7 eV to 1.4 eV, will be synthesized and monolithically integrated in tandem cells with up to 8-junctions. Nanophotonic methods for light-trapping, spectral and spatial control of solar radiation will be developed to further enhance the absorption. To ensure a high long-term impact, the project will validate the use of state-of-the-art molecular-beam-epitaxy processes for fabrication of economically viable ultra-high efficiency solar cells. The ultimate efficiency target is to reach a level of 55%. This would enable to generate renewable/ecological/sustainable energy at a levelized production cost below ~7 ¢/kWh, comparable or cheaper than fossil fuels. The work will also bring a new breath of developments for more efficient space photovoltaic systems.
AMETIST will leverage the leading position of the applicant in topical technology areas relevant for the project (i.e. epitaxy of III-N/Bi-V alloys and key achievements concerning GaInNAsSb-based tandem solar cells). Thus it renders a unique opportunity to capitalize on the group expertize and position Europe at the forefront in the global competition for demonstrating more efficient and economically viable photovoltaic technologies.
Max ERC Funding
2 492 719 €
Duration
Start date: 2017-01-01, End date: 2021-12-31
Project acronym AQUAMS
Project Analysis of quantum many-body systems
Researcher (PI) Robert Seiringer
Host Institution (HI) INSTITUTE OF SCIENCE AND TECHNOLOGY AUSTRIA
Country Austria
Call Details Advanced Grant (AdG), PE1, ERC-2015-AdG
Summary The main focus of this project is the mathematical analysis of many-body quantum systems, in particular, interacting quantum gases at low temperature. The recent experimental advances in studying ultra-cold atomic gases have led to renewed interest in these systems. They display a rich variety of quantum phenomena, including, e.g., Bose–Einstein condensation and superfluidity, which makes them interesting both from a physical and a mathematical point of view.
The goal of this project is the development of new mathematical tools for dealing with complex problems in many-body quantum systems. New mathematical methods lead to different points of view and thus increase our understanding of physical systems. From the point of view of mathematical physics, there has been significant progress in the last few years in understanding the interesting phenomena occurring in quantum gases, and the goal of this project is to investigate some of the key issues that remain unsolved. Due to the complex nature of the problems, new mathematical ideas
and methods will have to be developed for this purpose. One of the main question addressed in this proposal is the validity of the Bogoliubov approximation for the excitation spectrum of many-body quantum systems. While its accuracy has been
successfully shown for the ground state energy of various models, its predictions concerning the excitation spectrum have so far only been verified in the Hartree limit, an extreme form of a mean-field limit where the interaction among the particles is very weak and ranges over the whole system. The central part of this project is concerned with the extension of these results to the case of short-range interactions. Apart from being mathematically much more challenging, the short-range case is the
one most relevant for the description of actual physical systems. Hence progress along these lines can be expected to yield valuable insight into the complex behavior of these many-body quantum systems.
Summary
The main focus of this project is the mathematical analysis of many-body quantum systems, in particular, interacting quantum gases at low temperature. The recent experimental advances in studying ultra-cold atomic gases have led to renewed interest in these systems. They display a rich variety of quantum phenomena, including, e.g., Bose–Einstein condensation and superfluidity, which makes them interesting both from a physical and a mathematical point of view.
The goal of this project is the development of new mathematical tools for dealing with complex problems in many-body quantum systems. New mathematical methods lead to different points of view and thus increase our understanding of physical systems. From the point of view of mathematical physics, there has been significant progress in the last few years in understanding the interesting phenomena occurring in quantum gases, and the goal of this project is to investigate some of the key issues that remain unsolved. Due to the complex nature of the problems, new mathematical ideas
and methods will have to be developed for this purpose. One of the main question addressed in this proposal is the validity of the Bogoliubov approximation for the excitation spectrum of many-body quantum systems. While its accuracy has been
successfully shown for the ground state energy of various models, its predictions concerning the excitation spectrum have so far only been verified in the Hartree limit, an extreme form of a mean-field limit where the interaction among the particles is very weak and ranges over the whole system. The central part of this project is concerned with the extension of these results to the case of short-range interactions. Apart from being mathematically much more challenging, the short-range case is the
one most relevant for the description of actual physical systems. Hence progress along these lines can be expected to yield valuable insight into the complex behavior of these many-body quantum systems.
Max ERC Funding
1 497 755 €
Duration
Start date: 2016-10-01, End date: 2021-09-30
Project acronym CGCglasmaQGP
Project The nonlinear high energy regime of Quantum Chromodynamics
Researcher (PI) Tuomas Veli Valtteri Lappi
Host Institution (HI) JYVASKYLAN YLIOPISTO
Country Finland
Call Details Consolidator Grant (CoG), PE2, ERC-2015-CoG
Summary "This proposal concentrates on Quantum Chromodynamics (QCD) in its least well understood "final frontier": the high energy limit. The aim is to treat the formation of quark gluon plasma in relativistic nuclear collisions together with other high energy processes in a consistent QCD framework. This project is topical now in order to fully understand the results from the maturing LHC heavy ion program. The high energy regime is characterized by a high density of gluons, whose nonlinear interactions are beyond the reach of simple perturbative calculations. High energy particles also propagate nearly on the light cone, unaccessible to Euclidean lattice calculations. The nonlinear interactions at high density lead to the phenomenon of gluon saturation. The emergence of the "saturation scale", a semihard typical transverse momentum, enables a weak coupling expansion around a nonperturbatively large color field. This project aims to make progress both in collider phenomenology and in more conceptual aspects of nonabelian gauge field dynamics at high energy density:
1. Significant advances towards higher order accuracy will be made in cross section calculations for processes where a dilute probe collides with the strong color field of a high energy nucleus.
2. The quantum fluctuations around the strong color fields in the initial stages of a relativistic heavy ion collision will be analyzed with a new numerical method based on an explicit linearization of the equations of motion, maintaining a well defined weak coupling limit.
3. Initial conditions for fluid dynamical descriptions of the quark gluon plasma phase in heavy ion collisions will be obtained from a constrained QCD calculation.
We propose to achieve these goals with modern analytical and numerical methods, on which the P.I. is a leading expert. This project would represent a leap in the field towards better quantitative first principles understanding of QCD in a new kinematical domain."
Summary
"This proposal concentrates on Quantum Chromodynamics (QCD) in its least well understood "final frontier": the high energy limit. The aim is to treat the formation of quark gluon plasma in relativistic nuclear collisions together with other high energy processes in a consistent QCD framework. This project is topical now in order to fully understand the results from the maturing LHC heavy ion program. The high energy regime is characterized by a high density of gluons, whose nonlinear interactions are beyond the reach of simple perturbative calculations. High energy particles also propagate nearly on the light cone, unaccessible to Euclidean lattice calculations. The nonlinear interactions at high density lead to the phenomenon of gluon saturation. The emergence of the "saturation scale", a semihard typical transverse momentum, enables a weak coupling expansion around a nonperturbatively large color field. This project aims to make progress both in collider phenomenology and in more conceptual aspects of nonabelian gauge field dynamics at high energy density:
1. Significant advances towards higher order accuracy will be made in cross section calculations for processes where a dilute probe collides with the strong color field of a high energy nucleus.
2. The quantum fluctuations around the strong color fields in the initial stages of a relativistic heavy ion collision will be analyzed with a new numerical method based on an explicit linearization of the equations of motion, maintaining a well defined weak coupling limit.
3. Initial conditions for fluid dynamical descriptions of the quark gluon plasma phase in heavy ion collisions will be obtained from a constrained QCD calculation.
We propose to achieve these goals with modern analytical and numerical methods, on which the P.I. is a leading expert. This project would represent a leap in the field towards better quantitative first principles understanding of QCD in a new kinematical domain."
Max ERC Funding
1 935 000 €
Duration
Start date: 2016-10-01, End date: 2021-09-30
Project acronym CROSSLOCATIONS
Project Crosslocations in the Mediterranean: rethinking the socio-cultural dynamics of relative positioning
Researcher (PI) Sarah Francesca Green
Host Institution (HI) HELSINGIN YLIOPISTO
Country Finland
Call Details Advanced Grant (AdG), SH5, ERC-2015-AdG
Summary The Mediterranean, a key socio-cultural, economic and political crossroads, has shifted its relative position recently, with profound effects for relations between the peoples associated with its diverse parts. Crosslocations is a groundbreaking theoretical approach that goes beyond current borders research to analyse the significance of the changes in relations between places and peoples that this involves. It does this through explaining shifts in the relative positioning of the Mediterranean’s many locations – i.e. the changing values of where people are rather than who they are. Approaches focusing on people’s identities, statecraft or networks do not provide a way to research how the relative value of ‘being somewhere in particular’ is changing and diversifying.
The approach builds on the idea that in socio-cultural terms, location is a form of political, social, economic, and technical relative positioning, involving diverse scales that calibrate relative values (here called ‘locating regimes’). This means locations are both multiple and historically variable, so different types of location may overlap in the same geographical space, particularly in crossroads regions such as the Mediterranean. The dynamics between them alter relations between places, significantly affecting people’s daily lives, including their life chances, wellbeing, environmental, social and political conditions and status.
The project will first research the locating regimes crossing the Mediterranean region (border regimes, infrastructures; digital technologies; fiscal, financial and trading systems; environmental policies; and social and religious structures); then intensively ethnographically study the socio-cultural dynamics of relative positioning that these regimes generate in selected parts of the Mediterranean region. Through explaining the dynamics of relative location, Crosslocations will transform our understanding of trans-local, socio-cultural relations and separations.
Summary
The Mediterranean, a key socio-cultural, economic and political crossroads, has shifted its relative position recently, with profound effects for relations between the peoples associated with its diverse parts. Crosslocations is a groundbreaking theoretical approach that goes beyond current borders research to analyse the significance of the changes in relations between places and peoples that this involves. It does this through explaining shifts in the relative positioning of the Mediterranean’s many locations – i.e. the changing values of where people are rather than who they are. Approaches focusing on people’s identities, statecraft or networks do not provide a way to research how the relative value of ‘being somewhere in particular’ is changing and diversifying.
The approach builds on the idea that in socio-cultural terms, location is a form of political, social, economic, and technical relative positioning, involving diverse scales that calibrate relative values (here called ‘locating regimes’). This means locations are both multiple and historically variable, so different types of location may overlap in the same geographical space, particularly in crossroads regions such as the Mediterranean. The dynamics between them alter relations between places, significantly affecting people’s daily lives, including their life chances, wellbeing, environmental, social and political conditions and status.
The project will first research the locating regimes crossing the Mediterranean region (border regimes, infrastructures; digital technologies; fiscal, financial and trading systems; environmental policies; and social and religious structures); then intensively ethnographically study the socio-cultural dynamics of relative positioning that these regimes generate in selected parts of the Mediterranean region. Through explaining the dynamics of relative location, Crosslocations will transform our understanding of trans-local, socio-cultural relations and separations.
Max ERC Funding
2 433 234 €
Duration
Start date: 2016-09-01, End date: 2021-08-31
Project acronym DAMOCLES
Project Simulating Non-Equilibrium Dynamics of Atmospheric Multicomponent Clusters
Researcher (PI) Hanna Vehkamaeki
Host Institution (HI) HELSINGIN YLIOPISTO
Country Finland
Call Details Advanced Grant (AdG), PE10, ERC-2015-AdG
Summary Atmospheric aerosol particles play a key role in regulating the climate, and particulate matter is responsible for most of the 7 million deaths per year attributed to air pollution. Lack of understanding of aerosol processes, especially the formation of ice crystals and secondary particles from condensable trace gases, hampers the development of air quality modelling, and remains one of the major uncertainties in predicting climate.
The purpose of this project is to achieve a comprehensive understanding of atmospheric nanocluster and ice crystal formation based on fundamental physico-chemical principles. We will use a wide palette of theoretical methods including quantum chemistry, reaction kinetics, continuum solvent models, molecular dynamics, Monte Carlo simulations, Markov chain Monte Carlo methods, computational fluid dynamics, cluster kinetic and thermodynamic models. We will study non-equilibrium effects and kinetic barriers in atmospheric clustering, and use these to build cluster distribution models with genuine predictive capacity.
Chemical ionization mass spectrometers can, unlike any other instruments, detect the elemental composition of many of the smallest clusters at ambient low concentrations. However, the charging process and the environment inside the instrument change the composition of the clusters in hitherto unquantifiable ways. We will solve this problem by building an accurate model for the fate of clusters inside mass spectrometers, which will vastly improve the amount and quality of information that can be extracted from mass spectrometric measurements in atmospheric science and elsewhere.
DAMOCLES will produce reliable and consistent models for secondary aerosol and ice particle formation and growth. This will lead to improved predictions of aerosol concentrations and size distributions, leading to improved air quality forecasting, more accurate estimates of aerosol indirect climate forcing and other aerosol-cloud-climate interactions.
Summary
Atmospheric aerosol particles play a key role in regulating the climate, and particulate matter is responsible for most of the 7 million deaths per year attributed to air pollution. Lack of understanding of aerosol processes, especially the formation of ice crystals and secondary particles from condensable trace gases, hampers the development of air quality modelling, and remains one of the major uncertainties in predicting climate.
The purpose of this project is to achieve a comprehensive understanding of atmospheric nanocluster and ice crystal formation based on fundamental physico-chemical principles. We will use a wide palette of theoretical methods including quantum chemistry, reaction kinetics, continuum solvent models, molecular dynamics, Monte Carlo simulations, Markov chain Monte Carlo methods, computational fluid dynamics, cluster kinetic and thermodynamic models. We will study non-equilibrium effects and kinetic barriers in atmospheric clustering, and use these to build cluster distribution models with genuine predictive capacity.
Chemical ionization mass spectrometers can, unlike any other instruments, detect the elemental composition of many of the smallest clusters at ambient low concentrations. However, the charging process and the environment inside the instrument change the composition of the clusters in hitherto unquantifiable ways. We will solve this problem by building an accurate model for the fate of clusters inside mass spectrometers, which will vastly improve the amount and quality of information that can be extracted from mass spectrometric measurements in atmospheric science and elsewhere.
DAMOCLES will produce reliable and consistent models for secondary aerosol and ice particle formation and growth. This will lead to improved predictions of aerosol concentrations and size distributions, leading to improved air quality forecasting, more accurate estimates of aerosol indirect climate forcing and other aerosol-cloud-climate interactions.
Max ERC Funding
2 390 450 €
Duration
Start date: 2016-06-01, End date: 2021-05-31
Project acronym HUNAYNNET
Project Transmission of Classical Scientific and Philosophical Literature from Greek into Syriac and Arabic
Researcher (PI) Grigory Kessel
Host Institution (HI) OESTERREICHISCHE AKADEMIE DER WISSENSCHAFTEN
Country Austria
Call Details Starting Grant (StG), SH5, ERC-2015-STG
Summary It is often taken for granted that the Greek-Arabic translation movement (8th-10th c.) that made the whole bulk of Classical Greek scientific and philosophical literature available in Arabic (and that was later handed over to Europe in Latin translations) owes much to the preceding period in the history of transmission of this scientific and philosophical literature, namely translations into the Syriac language that were implemented by Aramaic-speaking Syriac Christians. The problem of continuity between the two periods however has not been tackled thoroughly in scholarship and thus the actual impact of the Syriac translations on later methods of translation has so far not been measured and assessed. One feasible solution to this problem in our understanding of the background to the Greek-Arabic translation movement is to implement a comprehensive comparison of Syriac and Arabic translations by means of lexicographical analysis. This project offers a research tool capable of allowing this comparison. It will combine methods of online lexicography and of corpus linguistics with the aim of presenting in a systematic and rationalized way the lexical data from the entire corpus of Syriac scientific and philosophical translations, comparing and analyzing its terminology and translation techniques, first, with the extant Greek originals and, secondly, with Arabic versions. The lexicographic database will be an effective instrument providing definite data for the study of Syriac and Arabic translations and their close connections. It will reveal how the Syriac translations along with underlying methods and tools that were put to use for the first time ever by Syriac Christians eventually determined the prosperity of the Islamic sciences. Fully endorsing a principle of open access the database creates a new instrument for a study of the history of the transmission of Greek scientific literature in Antiquity and the Middle Ages.
Summary
It is often taken for granted that the Greek-Arabic translation movement (8th-10th c.) that made the whole bulk of Classical Greek scientific and philosophical literature available in Arabic (and that was later handed over to Europe in Latin translations) owes much to the preceding period in the history of transmission of this scientific and philosophical literature, namely translations into the Syriac language that were implemented by Aramaic-speaking Syriac Christians. The problem of continuity between the two periods however has not been tackled thoroughly in scholarship and thus the actual impact of the Syriac translations on later methods of translation has so far not been measured and assessed. One feasible solution to this problem in our understanding of the background to the Greek-Arabic translation movement is to implement a comprehensive comparison of Syriac and Arabic translations by means of lexicographical analysis. This project offers a research tool capable of allowing this comparison. It will combine methods of online lexicography and of corpus linguistics with the aim of presenting in a systematic and rationalized way the lexical data from the entire corpus of Syriac scientific and philosophical translations, comparing and analyzing its terminology and translation techniques, first, with the extant Greek originals and, secondly, with Arabic versions. The lexicographic database will be an effective instrument providing definite data for the study of Syriac and Arabic translations and their close connections. It will reveal how the Syriac translations along with underlying methods and tools that were put to use for the first time ever by Syriac Christians eventually determined the prosperity of the Islamic sciences. Fully endorsing a principle of open access the database creates a new instrument for a study of the history of the transmission of Greek scientific literature in Antiquity and the Middle Ages.
Max ERC Funding
1 498 452 €
Duration
Start date: 2016-05-01, End date: 2021-04-30
Project acronym InPairs
Project In Silico Pair Plasmas: from ultra intense lasers to relativistic astrophysics in the laboratory
Researcher (PI) LuIs Miguel DE OLIVEIRA E SILVA
Host Institution (HI) INSTITUTO SUPERIOR TECNICO
Country Portugal
Call Details Advanced Grant (AdG), PE2, ERC-2015-AdG
Summary How do extreme electromagnetic fields modify the dynamics of matter? Will quantum electrodynamics effects be important at the focus of an ultra intense laser? How are the magnetospheres of compact stellar remnants formed, and can we capture the physics of these environments in the laboratory? These are all longstanding questions with an overarching connection to extreme plasma physics.
Electron-positron pair plasmas are pervasive in all these scenarios. Highly nonlinear phenomena such as QED processes, magnetogenesis, radiation, field dynamics in complex geometries, and particle acceleration, are all linked with the collective dynamics of pair plasmas through mechanisms that remain poorly understood.
Building on our state-of-the-art models, on the availability of enormous computational power, and on our recent transformative discoveries on ab initio modelling of plasmas under extreme conditions, the time is ripe to answer these questions in silico. InPairs aims to understand the multidimensional dynamics of electron-positron plasmas under extreme laboratory and astrophysical fields, to determine the signatures of the radiative processes on pair plasmas, and to identify the physics of the magnetospheres of compact stellar remnants, focusing on the electrodynamics of pulsars, that can be mimicked in laboratory experiments using ultra high intensity lasers and charged particle beams.
This proposal relies on massively parallel simulations to bridge the gap, for the first time, between the pair plasma creation mechanisms, the collective multidimensional microphysics, and their global dynamics in complex geometries associated with laboratory and astrophysical systems. Emphasis will be given to detectable signatures e.g. radiation and accelerated particles, with the ultimate goal of solving some of the central questions in extreme plasma physics, thus opening new connections between computational studies, laboratory experiments, and relativistic plasma astrophysics.
Summary
How do extreme electromagnetic fields modify the dynamics of matter? Will quantum electrodynamics effects be important at the focus of an ultra intense laser? How are the magnetospheres of compact stellar remnants formed, and can we capture the physics of these environments in the laboratory? These are all longstanding questions with an overarching connection to extreme plasma physics.
Electron-positron pair plasmas are pervasive in all these scenarios. Highly nonlinear phenomena such as QED processes, magnetogenesis, radiation, field dynamics in complex geometries, and particle acceleration, are all linked with the collective dynamics of pair plasmas through mechanisms that remain poorly understood.
Building on our state-of-the-art models, on the availability of enormous computational power, and on our recent transformative discoveries on ab initio modelling of plasmas under extreme conditions, the time is ripe to answer these questions in silico. InPairs aims to understand the multidimensional dynamics of electron-positron plasmas under extreme laboratory and astrophysical fields, to determine the signatures of the radiative processes on pair plasmas, and to identify the physics of the magnetospheres of compact stellar remnants, focusing on the electrodynamics of pulsars, that can be mimicked in laboratory experiments using ultra high intensity lasers and charged particle beams.
This proposal relies on massively parallel simulations to bridge the gap, for the first time, between the pair plasma creation mechanisms, the collective multidimensional microphysics, and their global dynamics in complex geometries associated with laboratory and astrophysical systems. Emphasis will be given to detectable signatures e.g. radiation and accelerated particles, with the ultimate goal of solving some of the central questions in extreme plasma physics, thus opening new connections between computational studies, laboratory experiments, and relativistic plasma astrophysics.
Max ERC Funding
1 951 124 €
Duration
Start date: 2016-09-01, End date: 2021-08-31
Project acronym RESPONSIVENESS
Project The Microfoundations of Authoritarian Responsiveness: E-Participation, Social Unrest and Public Policy in China
Researcher (PI) Christian Goebel
Host Institution (HI) UNIVERSITAT WIEN
Country Austria
Call Details Starting Grant (StG), SH2, ERC-2015-STG
Summary "China’s success story of the past three decades is seen as an anomaly. Market-based reforms have generated an economic system that can hardly be described as socialist anymore, but the Communist Party of China remains in power. Although social unrest is on the rise, the CCP enjoys the consent of the overwhelming majority of its people. Most agree that China’s economic performance is the key to solving this apparent puzzle, but how can extraordinary high rates of public support be maintained in a country where income inequality is so extreme?
We believe that the answer to this question lies in the responsiveness of China’s authoritarian one-party regime to popular demands and grievances, a capability that has so far been attributed only to democratic regimes. We further believe that the rapid improvement of e-participation, the opportunity to evaluate public services on the Internet, has greatly facilitated regime responsiveness - China’s score in the United Nations e-participation index is higher than the European average. We suggest, however, that as the government increasingly calibrates public policy towards satisfying the demand of China’s netizens, the ""technologically illiterate"" are forced to express their demands in public protests and other forms of social unrest.
The proposed project sheds light on the intended and unintended consequences of enhanced e-participation in China by exploring which social interests China’s rulers incorporate into public policy making, and how these decisions influence the propensity of particular social groups to voice their demands by either participating online or taking to the streets. By exploring the “complex system” in which online complaints, social unrest and public policy interact, the project provides insights into the micro-foundations of regime responsiveness in China. It thereby increases our knowledge of how the CCP seeks to defer the antagonism that prompted the revolutions in Egypt, Tunisia and Syria."
Summary
"China’s success story of the past three decades is seen as an anomaly. Market-based reforms have generated an economic system that can hardly be described as socialist anymore, but the Communist Party of China remains in power. Although social unrest is on the rise, the CCP enjoys the consent of the overwhelming majority of its people. Most agree that China’s economic performance is the key to solving this apparent puzzle, but how can extraordinary high rates of public support be maintained in a country where income inequality is so extreme?
We believe that the answer to this question lies in the responsiveness of China’s authoritarian one-party regime to popular demands and grievances, a capability that has so far been attributed only to democratic regimes. We further believe that the rapid improvement of e-participation, the opportunity to evaluate public services on the Internet, has greatly facilitated regime responsiveness - China’s score in the United Nations e-participation index is higher than the European average. We suggest, however, that as the government increasingly calibrates public policy towards satisfying the demand of China’s netizens, the ""technologically illiterate"" are forced to express their demands in public protests and other forms of social unrest.
The proposed project sheds light on the intended and unintended consequences of enhanced e-participation in China by exploring which social interests China’s rulers incorporate into public policy making, and how these decisions influence the propensity of particular social groups to voice their demands by either participating online or taking to the streets. By exploring the “complex system” in which online complaints, social unrest and public policy interact, the project provides insights into the micro-foundations of regime responsiveness in China. It thereby increases our knowledge of how the CCP seeks to defer the antagonism that prompted the revolutions in Egypt, Tunisia and Syria."
Max ERC Funding
1 292 440 €
Duration
Start date: 2016-05-01, End date: 2021-10-31
Project acronym SCATAPNUT
Project Scattering and tapping on soft-hard-open nuts
Researcher (PI) Notburga Gierlinger
Host Institution (HI) UNIVERSITAET FUER BODENKULTUR WIEN
Country Austria
Call Details Consolidator Grant (CoG), PE4, ERC-2015-CoG
Summary Seeds enclosed in maternal tissue are an important evolutionary plant development as they protect the embryo in many different environments. The protecting coverings are very heterogeneous in structure and origin due to different seed dispersal strategies and environments designed for. The ones having hard outer coverings are commonly called nuts and their shells have recently become of interest for biomimetic research as they represent hard and tough lightweight structures with biological and environmental resistance.
Biological materials are optimized at numerous length scales. To unravel the design principles on the micro- and nano scale and their assembly are a big challenge in biomimetic research. Thus the objectives of this project are threefold: 1) develop in-situ methods for in-depth characterization at the micro- and nano level, 2) reveal the heterogeneity and common design principles by investigating different species and 3) follow development (soft), maturation (hard) and germination (open).
By measuring the inelastic scattering of laser light (RAMAN microscopy), tapping with a tip (Atomic force microscopy AFM, pulsed force mode) and combining both (Scanning near field optical microscopy-SNOM, Tip enhanced Raman spectroscopy-TERS) sophisticated applications for imaging natural packaging structures will be developed. This will enable us to gain new insights into micro- and nanochemistry as well as nanomechanics in the context of tissue and cell organization. Furthermore in-depth knowledge on the developmental processes of cell assembly, maturation and germination will be obtained. This will lead to a better understanding of the underlying design principles, which is important in order to extract structure-function relationships and identify features that contribute e.g. to the high strength and cracking resistance and longevity. Such information is important for biology (agriculture) and will give new input in intelligent biomimetic material design.
Summary
Seeds enclosed in maternal tissue are an important evolutionary plant development as they protect the embryo in many different environments. The protecting coverings are very heterogeneous in structure and origin due to different seed dispersal strategies and environments designed for. The ones having hard outer coverings are commonly called nuts and their shells have recently become of interest for biomimetic research as they represent hard and tough lightweight structures with biological and environmental resistance.
Biological materials are optimized at numerous length scales. To unravel the design principles on the micro- and nano scale and their assembly are a big challenge in biomimetic research. Thus the objectives of this project are threefold: 1) develop in-situ methods for in-depth characterization at the micro- and nano level, 2) reveal the heterogeneity and common design principles by investigating different species and 3) follow development (soft), maturation (hard) and germination (open).
By measuring the inelastic scattering of laser light (RAMAN microscopy), tapping with a tip (Atomic force microscopy AFM, pulsed force mode) and combining both (Scanning near field optical microscopy-SNOM, Tip enhanced Raman spectroscopy-TERS) sophisticated applications for imaging natural packaging structures will be developed. This will enable us to gain new insights into micro- and nanochemistry as well as nanomechanics in the context of tissue and cell organization. Furthermore in-depth knowledge on the developmental processes of cell assembly, maturation and germination will be obtained. This will lead to a better understanding of the underlying design principles, which is important in order to extract structure-function relationships and identify features that contribute e.g. to the high strength and cracking resistance and longevity. Such information is important for biology (agriculture) and will give new input in intelligent biomimetic material design.
Max ERC Funding
1 993 606 €
Duration
Start date: 2016-09-01, End date: 2021-08-31
Project acronym VINCAT
Project A Unified Approach to Redox-Neutral C-C Couplings: Exploiting Vinyl Cation Rearrangements
Researcher (PI) Nuno Xavier Dias Maulide
Host Institution (HI) UNIVERSITAT WIEN
Country Austria
Call Details Consolidator Grant (CoG), PE5, ERC-2015-CoG
Summary The preparation of complex molecular architectures employing multi-component reactions where the number of bond-forming events is maximised is a central goal of the discipline of Organic Synthesis. The contemporary, pressing need for sustainable chemical reactions has raised the demand for novel reaction families that explore the concept of redox-neutrality and proceed with the generation of minimal waste. In this proposal, I present a unified and conceptually novel approach to atom-economical C-C bond formation in challenging contexts without the need for transition metal promoters or reagents. To this end, I propose the innovative harvesting of the potential of vinyl cation intermediates as platforms for the deployment of nucleophilic entities capable of orchestrating rearrangement reactions. The combination of such high-energy intermediates, generated under mild conditions, with the power of carefully designed rearrangements leads to an array of useful new transformations. Furthermore, the very high atom-economy and simplicity of these reactions renders them not only sustainable and environmentally friendly but also highly appealing for large-scale applications. Additional approaches to enantioselective synthesis further enhance the methods proposed.
The paradigm proposed herein for the exploitation of vinyl cations will also open up new vistas in the centuries-old aldol reaction and in amination chemistry. This showcases the vast potential of these simple principles of chemical reactivity. The myriad of new reactions and new product families made possible by VINCAT will decisively enrich the toolbox of the synthetic practitioner.
Summary
The preparation of complex molecular architectures employing multi-component reactions where the number of bond-forming events is maximised is a central goal of the discipline of Organic Synthesis. The contemporary, pressing need for sustainable chemical reactions has raised the demand for novel reaction families that explore the concept of redox-neutrality and proceed with the generation of minimal waste. In this proposal, I present a unified and conceptually novel approach to atom-economical C-C bond formation in challenging contexts without the need for transition metal promoters or reagents. To this end, I propose the innovative harvesting of the potential of vinyl cation intermediates as platforms for the deployment of nucleophilic entities capable of orchestrating rearrangement reactions. The combination of such high-energy intermediates, generated under mild conditions, with the power of carefully designed rearrangements leads to an array of useful new transformations. Furthermore, the very high atom-economy and simplicity of these reactions renders them not only sustainable and environmentally friendly but also highly appealing for large-scale applications. Additional approaches to enantioselective synthesis further enhance the methods proposed.
The paradigm proposed herein for the exploitation of vinyl cations will also open up new vistas in the centuries-old aldol reaction and in amination chemistry. This showcases the vast potential of these simple principles of chemical reactivity. The myriad of new reactions and new product families made possible by VINCAT will decisively enrich the toolbox of the synthetic practitioner.
Max ERC Funding
1 940 025 €
Duration
Start date: 2017-01-01, End date: 2021-12-31
