Project acronym 3DNANOMECH
Project Three-dimensional molecular resolution mapping of soft matter-liquid interfaces
Researcher (PI) Ricardo Garcia
Host Institution (HI) AGENCIA ESTATAL CONSEJO SUPERIOR DEINVESTIGACIONES CIENTIFICAS
Country Spain
Call Details Advanced Grant (AdG), PE4, ERC-2013-ADG
Summary Optical, electron and probe microscopes are enabling tools for discoveries and knowledge generation in nanoscale sicence and technology. High resolution –nanoscale or molecular-, noninvasive and label-free imaging of three-dimensional soft matter-liquid interfaces has not been achieved by any microscopy method.
Force microscopy (AFM) is considered the second most relevant advance in materials science since 1960. Despite its impressive range of applications, the technique has some key limitations. Force microscopy has not three dimensional depth. What lies above or in the subsurface is not readily characterized.
3DNanoMech proposes to design, build and operate a high speed force-based method for the three-dimensional characterization soft matter-liquid interfaces (3D AFM). The microscope will combine a detection method based on force perturbations, adaptive algorithms, high speed piezo actuators and quantitative-oriented multifrequency approaches. The development of the microscope cannot be separated from its applications: imaging the error-free DNA repair and to understand the relationship existing between the nanomechanical properties and the malignancy of cancer cells. Those problems encompass the different spatial –molecular-nano-mesoscopic- and time –milli to seconds- scales of the instrument.
In short, 3DNanoMech aims to image, map and measure with picoNewton, millisecond and angstrom resolution soft matter surfaces and interfaces in liquid. The long-term vision of 3DNanoMech is to replace models or computer animations of bimolecular-liquid interfaces by real time, molecular resolution maps of properties and processes.
Summary
Optical, electron and probe microscopes are enabling tools for discoveries and knowledge generation in nanoscale sicence and technology. High resolution –nanoscale or molecular-, noninvasive and label-free imaging of three-dimensional soft matter-liquid interfaces has not been achieved by any microscopy method.
Force microscopy (AFM) is considered the second most relevant advance in materials science since 1960. Despite its impressive range of applications, the technique has some key limitations. Force microscopy has not three dimensional depth. What lies above or in the subsurface is not readily characterized.
3DNanoMech proposes to design, build and operate a high speed force-based method for the three-dimensional characterization soft matter-liquid interfaces (3D AFM). The microscope will combine a detection method based on force perturbations, adaptive algorithms, high speed piezo actuators and quantitative-oriented multifrequency approaches. The development of the microscope cannot be separated from its applications: imaging the error-free DNA repair and to understand the relationship existing between the nanomechanical properties and the malignancy of cancer cells. Those problems encompass the different spatial –molecular-nano-mesoscopic- and time –milli to seconds- scales of the instrument.
In short, 3DNanoMech aims to image, map and measure with picoNewton, millisecond and angstrom resolution soft matter surfaces and interfaces in liquid. The long-term vision of 3DNanoMech is to replace models or computer animations of bimolecular-liquid interfaces by real time, molecular resolution maps of properties and processes.
Max ERC Funding
2 499 928 €
Duration
Start date: 2014-02-01, End date: 2019-01-31
Project acronym ADAPT
Project Life in a cold climate: the adaptation of cereals to new environments and the establishment of agriculture in Europe
Researcher (PI) Terence Austen Brown
Host Institution (HI) THE UNIVERSITY OF MANCHESTER
Country United Kingdom
Call Details Advanced Grant (AdG), SH6, ERC-2013-ADG
Summary "This project explores the concept of agricultural spread as analogous to enforced climate change and asks how cereals adapted to new environments when agriculture was introduced into Europe. Archaeologists have long recognized that the ecological pressures placed on crops would have had an impact on the spread and subsequent development of agriculture, but previously there has been no means of directly assessing the scale and nature of this impact. Recent work that I have directed has shown how such a study could be carried out, and the purpose of this project is to exploit these breakthroughs with the goal of assessing the influence of environmental adaptation on the spread of agriculture, its adoption as the primary subsistence strategy, and the subsequent establishment of farming in different parts of Europe. This will correct the current imbalance between our understanding of the human and environmental dimensions to the domestication of Europe. I will use methods from population genomics to identify loci within the barley and wheat genomes that have undergone selection since the beginning of cereal cultivation in Europe. I will then use ecological modelling to identify those loci whose patterns of selection are associated with ecogeographical variables and hence represent adaptations to local environmental conditions. I will assign dates to the periods when adaptations occurred by sequencing ancient DNA from archaeobotanical assemblages and by computer methods that enable the temporal order of adaptations to be deduced. I will then synthesise the information on environmental adaptations with dating evidence for the spread of agriculture in Europe, which reveals pauses that might be linked to environmental adaptation, with demographic data that indicate regions where Neolithic populations declined, possibly due to inadequate crop productivity, and with an archaeobotanical database showing changes in the prevalence of individual cereals in different regions."
Summary
"This project explores the concept of agricultural spread as analogous to enforced climate change and asks how cereals adapted to new environments when agriculture was introduced into Europe. Archaeologists have long recognized that the ecological pressures placed on crops would have had an impact on the spread and subsequent development of agriculture, but previously there has been no means of directly assessing the scale and nature of this impact. Recent work that I have directed has shown how such a study could be carried out, and the purpose of this project is to exploit these breakthroughs with the goal of assessing the influence of environmental adaptation on the spread of agriculture, its adoption as the primary subsistence strategy, and the subsequent establishment of farming in different parts of Europe. This will correct the current imbalance between our understanding of the human and environmental dimensions to the domestication of Europe. I will use methods from population genomics to identify loci within the barley and wheat genomes that have undergone selection since the beginning of cereal cultivation in Europe. I will then use ecological modelling to identify those loci whose patterns of selection are associated with ecogeographical variables and hence represent adaptations to local environmental conditions. I will assign dates to the periods when adaptations occurred by sequencing ancient DNA from archaeobotanical assemblages and by computer methods that enable the temporal order of adaptations to be deduced. I will then synthesise the information on environmental adaptations with dating evidence for the spread of agriculture in Europe, which reveals pauses that might be linked to environmental adaptation, with demographic data that indicate regions where Neolithic populations declined, possibly due to inadequate crop productivity, and with an archaeobotanical database showing changes in the prevalence of individual cereals in different regions."
Max ERC Funding
2 492 964 €
Duration
Start date: 2014-02-01, End date: 2019-01-31
Project acronym AFMIDMOA
Project "Applying Fundamental Mathematics in Discrete Mathematics, Optimization, and Algorithmics"
Researcher (PI) Alexander Schrijver
Host Institution (HI) UNIVERSITEIT VAN AMSTERDAM
Country Netherlands
Call Details Advanced Grant (AdG), PE1, ERC-2013-ADG
Summary "This proposal aims at strengthening the connections between more fundamentally oriented areas of mathematics like algebra, geometry, analysis, and topology, and the more applied oriented and more recently emerging disciplines of discrete mathematics, optimization, and algorithmics.
The overall goal of the project is to obtain, with methods from fundamental mathematics, new effective tools to unravel the complexity of structures like graphs, networks, codes, knots, polynomials, and tensors, and to get a grip on such complex structures by new efficient characterizations, sharper bounds, and faster algorithms.
In the last few years, there have been several new developments where methods from representation theory, invariant theory, algebraic geometry, measure theory, functional analysis, and topology found new applications in discrete mathematics and optimization, both theoretically and algorithmically. Among the typical application areas are networks, coding, routing, timetabling, statistical and quantum physics, and computer science.
The project focuses in particular on:
A. Understanding partition functions with invariant theory and algebraic geometry
B. Graph limits, regularity, Hilbert spaces, and low rank approximation of polynomials
C. Reducing complexity in optimization by exploiting symmetry with representation theory
D. Reducing complexity in discrete optimization by homotopy and cohomology
These research modules are interconnected by themes like symmetry, regularity, and complexity, and by common methods from algebra, analysis, geometry, and topology."
Summary
"This proposal aims at strengthening the connections between more fundamentally oriented areas of mathematics like algebra, geometry, analysis, and topology, and the more applied oriented and more recently emerging disciplines of discrete mathematics, optimization, and algorithmics.
The overall goal of the project is to obtain, with methods from fundamental mathematics, new effective tools to unravel the complexity of structures like graphs, networks, codes, knots, polynomials, and tensors, and to get a grip on such complex structures by new efficient characterizations, sharper bounds, and faster algorithms.
In the last few years, there have been several new developments where methods from representation theory, invariant theory, algebraic geometry, measure theory, functional analysis, and topology found new applications in discrete mathematics and optimization, both theoretically and algorithmically. Among the typical application areas are networks, coding, routing, timetabling, statistical and quantum physics, and computer science.
The project focuses in particular on:
A. Understanding partition functions with invariant theory and algebraic geometry
B. Graph limits, regularity, Hilbert spaces, and low rank approximation of polynomials
C. Reducing complexity in optimization by exploiting symmetry with representation theory
D. Reducing complexity in discrete optimization by homotopy and cohomology
These research modules are interconnected by themes like symmetry, regularity, and complexity, and by common methods from algebra, analysis, geometry, and topology."
Max ERC Funding
2 001 598 €
Duration
Start date: 2014-01-01, End date: 2018-12-31
Project acronym BREAD
Project Breaking the curse of dimensionality: numerical challenges in high dimensional analysis and simulation
Researcher (PI) Albert Cohen
Host Institution (HI) UNIVERSITE PIERRE ET MARIE CURIE - PARIS 6
Country France
Call Details Advanced Grant (AdG), PE1, ERC-2013-ADG
Summary "This project is concerned with problems that involve a very large number of variables, and whose efficient numerical treatment is challenged by the so-called curse of dimensionality, meaning that computational complexity increases exponentially in the variable dimension.
The PI intend to establish in his host institution a scientific leadership on the mathematical understanding and numerical treatment of these problems, and to contribute to the development of this area of research through international collaborations, organization of workshops and research schools, and training of postdocs and PhD students.
High dimensional problems are ubiquitous in an increasing number of areas of scientific computing, among which statistical or active learning theory, parametric and stochastic partial differential equations, parameter optimization in numerical codes. There is a high demand from the industrial world of efficient numerical methods for treating such problems.
The practical success of various numerical algorithms, that have been developed in recent years in these application areas, is often limited to moderate dimensional setting.
In addition, these developments tend to be, as a rule, rather problem specific and not always founded on a solid mathematical analysis.
The central scientific objectives of this project are therefore: (i) to identify fundamental mathematical principles behind overcoming the curse of dimensionality, (ii) to understand how these principles enter in relevant instances of the above applications, and (iii) based on the these principles beyond particular problem classes, to develop broadly applicable numerical strategies that benefit from such mechanisms.
The performances of these strategies should be provably independent of the variable dimension, and in that sense break the curse of dimensionality. They will be tested on both synthetic benchmark tests and real world problems coming from the afore-mentioned applications."
Summary
"This project is concerned with problems that involve a very large number of variables, and whose efficient numerical treatment is challenged by the so-called curse of dimensionality, meaning that computational complexity increases exponentially in the variable dimension.
The PI intend to establish in his host institution a scientific leadership on the mathematical understanding and numerical treatment of these problems, and to contribute to the development of this area of research through international collaborations, organization of workshops and research schools, and training of postdocs and PhD students.
High dimensional problems are ubiquitous in an increasing number of areas of scientific computing, among which statistical or active learning theory, parametric and stochastic partial differential equations, parameter optimization in numerical codes. There is a high demand from the industrial world of efficient numerical methods for treating such problems.
The practical success of various numerical algorithms, that have been developed in recent years in these application areas, is often limited to moderate dimensional setting.
In addition, these developments tend to be, as a rule, rather problem specific and not always founded on a solid mathematical analysis.
The central scientific objectives of this project are therefore: (i) to identify fundamental mathematical principles behind overcoming the curse of dimensionality, (ii) to understand how these principles enter in relevant instances of the above applications, and (iii) based on the these principles beyond particular problem classes, to develop broadly applicable numerical strategies that benefit from such mechanisms.
The performances of these strategies should be provably independent of the variable dimension, and in that sense break the curse of dimensionality. They will be tested on both synthetic benchmark tests and real world problems coming from the afore-mentioned applications."
Max ERC Funding
1 848 000 €
Duration
Start date: 2014-01-01, End date: 2018-12-31
Project acronym ChemNav
Project Magnetic sensing by molecules, birds, and devices
Researcher (PI) Peter John Hore
Host Institution (HI) THE CHANCELLOR, MASTERS AND SCHOLARS OF THE UNIVERSITY OF OXFORD
Country United Kingdom
Call Details Advanced Grant (AdG), PE4, ERC-2013-ADG
Summary The sensory mechanisms that allow birds to perceive the direction of the Earth’s magnetic field for the purpose of navigation are only now beginning to be understood. One of the two leading hypotheses is founded on magnetically sensitive photochemical reactions in the retina. It is thought that transient photo-induced radical pairs in cryptochrome, a blue-light photoreceptor protein, act as the primary magnetic sensor. Experimental and theoretical support for this mechanism has been accumulating over the last few years, qualifying chemical magnetoreception for a place in the emerging field of Quantum Biology.
In this proposal, we aim to determine the detailed principles of efficient chemical sensing of weak magnetic fields, to elucidate the biophysics of animal compass magnetoreception, and to explore the possibilities of magnetic sensing technologies inspired by the coherent dynamics of entangled electron spins in cryptochrome-based radical pairs.
We will:
(a) Establish the fundamental structural, kinetic, dynamic and magnetic properties that allow efficient chemical sensing of Earth-strength magnetic fields in cryptochromes.
(b) Devise new, sensitive forms of optical spectroscopy for this purpose.
(c) Design, construct and iteratively refine non-natural proteins (maquettes) as versatile model systems for testing and optimising molecular magnetoreceptors.
(d) Characterise the spin dynamics and magnetic sensitivity of maquette magnetoreceptors using specialised magnetic resonance and optical spectroscopic techniques.
(e) Develop efficient and accurate methods for simulating the coherent spin dynamics of realistic radical pairs in order to interpret experimental data, guide the implementation of new experiments, test concepts of magnetoreceptor function, and guide the design of efficient sensors.
(f) Explore the feasibility of electronically addressable, organic semiconductor sensors inspired by radical pair magnetoreception.
Summary
The sensory mechanisms that allow birds to perceive the direction of the Earth’s magnetic field for the purpose of navigation are only now beginning to be understood. One of the two leading hypotheses is founded on magnetically sensitive photochemical reactions in the retina. It is thought that transient photo-induced radical pairs in cryptochrome, a blue-light photoreceptor protein, act as the primary magnetic sensor. Experimental and theoretical support for this mechanism has been accumulating over the last few years, qualifying chemical magnetoreception for a place in the emerging field of Quantum Biology.
In this proposal, we aim to determine the detailed principles of efficient chemical sensing of weak magnetic fields, to elucidate the biophysics of animal compass magnetoreception, and to explore the possibilities of magnetic sensing technologies inspired by the coherent dynamics of entangled electron spins in cryptochrome-based radical pairs.
We will:
(a) Establish the fundamental structural, kinetic, dynamic and magnetic properties that allow efficient chemical sensing of Earth-strength magnetic fields in cryptochromes.
(b) Devise new, sensitive forms of optical spectroscopy for this purpose.
(c) Design, construct and iteratively refine non-natural proteins (maquettes) as versatile model systems for testing and optimising molecular magnetoreceptors.
(d) Characterise the spin dynamics and magnetic sensitivity of maquette magnetoreceptors using specialised magnetic resonance and optical spectroscopic techniques.
(e) Develop efficient and accurate methods for simulating the coherent spin dynamics of realistic radical pairs in order to interpret experimental data, guide the implementation of new experiments, test concepts of magnetoreceptor function, and guide the design of efficient sensors.
(f) Explore the feasibility of electronically addressable, organic semiconductor sensors inspired by radical pair magnetoreception.
Max ERC Funding
2 997 062 €
Duration
Start date: 2013-12-01, End date: 2018-11-30
Project acronym CISS
Project Chiral Induced Spin Selectivity
Researcher (PI) Ron Naaman
Host Institution (HI) WEIZMANN INSTITUTE OF SCIENCE
Country Israel
Call Details Advanced Grant (AdG), PE4, ERC-2013-ADG
Summary The overall objective is to fully understand the Chiral Induced Spin Selectivity (CISS) effect, which was discovered recently. It was found that the transmission or conduction of electrons through chiral molecules is spin dependent. The CISS effect is a change in the pradigm that assumed that any spin manipulation requiers magnetic materials or materials with high spin-orbit coupling. These unexpected new findings open new possibilities for applying chiral molecules in spintronics applications and may provide new insights on electron transfer processes in Biology.
The specific goals of the proposed research are
(i) To establish the parameters that affect the magnitude of the CISS effect.
(ii) To demonstrate spintronics devices (memory and transistors) that are based on the CISS effect.
(iii) To investigate the role of CISS in electron transfer in biology related systems.
The experiments will be performed applying a combination of experimental methods including photoelectron spectroscopy, single molecule conduction, light-induced electron transfer, and spin specific conduction through magneto-electric devices.
The project has a potential to have very large impact on various fields from Physics to Biology. It will result in the establishment of chiral organic molecules as a new substrate for wide range of spintronics related applications including magnetic memory, and in determining whether spins play a role in electron transfer processes in biology.
Summary
The overall objective is to fully understand the Chiral Induced Spin Selectivity (CISS) effect, which was discovered recently. It was found that the transmission or conduction of electrons through chiral molecules is spin dependent. The CISS effect is a change in the pradigm that assumed that any spin manipulation requiers magnetic materials or materials with high spin-orbit coupling. These unexpected new findings open new possibilities for applying chiral molecules in spintronics applications and may provide new insights on electron transfer processes in Biology.
The specific goals of the proposed research are
(i) To establish the parameters that affect the magnitude of the CISS effect.
(ii) To demonstrate spintronics devices (memory and transistors) that are based on the CISS effect.
(iii) To investigate the role of CISS in electron transfer in biology related systems.
The experiments will be performed applying a combination of experimental methods including photoelectron spectroscopy, single molecule conduction, light-induced electron transfer, and spin specific conduction through magneto-electric devices.
The project has a potential to have very large impact on various fields from Physics to Biology. It will result in the establishment of chiral organic molecules as a new substrate for wide range of spintronics related applications including magnetic memory, and in determining whether spins play a role in electron transfer processes in biology.
Max ERC Funding
2 499 998 €
Duration
Start date: 2013-10-01, End date: 2018-09-30
Project acronym COMPASP
Project Complex analysis and statistical physics
Researcher (PI) Stanislav Smirnov
Host Institution (HI) UNIVERSITE DE GENEVE
Country Switzerland
Call Details Advanced Grant (AdG), PE1, ERC-2013-ADG
Summary "The goal of this project is to achieve breakthroughs in a few fundamental questions in 2D statistical physics, using techniques from complex analysis, probability, dynamical systems, geometric measure theory and theoretical physics.
Over the last decade, we significantly expanded our understanding of 2D lattice models of statistical physics, their conformally invariant scaling limits and related random geometries. However, there seem to be serious obstacles, preventing further development and requiring novel ideas. We plan to attack those, in particular we intend to:
(A) Describe new scaling limits by Schramm’s SLE curves and their generalizations,
(B) Study discrete complex structures and use them to describe more 2D models,
(C) Describe the scaling limits of random planar graphs by the Liouville Quantum Gravity,
(D) Understand universality and lay framework for the Renormalization Group Formalism,
(E) Go beyond the current setup of spin models and SLEs.
These problems are known to be very difficult, but fundamental questions, which have the potential to lead to significant breakthroughs in our understanding of phase transitions, allowing for further progresses. In resolving them, we plan to exploit interactions of different subjects, and recent advances are encouraging."
Summary
"The goal of this project is to achieve breakthroughs in a few fundamental questions in 2D statistical physics, using techniques from complex analysis, probability, dynamical systems, geometric measure theory and theoretical physics.
Over the last decade, we significantly expanded our understanding of 2D lattice models of statistical physics, their conformally invariant scaling limits and related random geometries. However, there seem to be serious obstacles, preventing further development and requiring novel ideas. We plan to attack those, in particular we intend to:
(A) Describe new scaling limits by Schramm’s SLE curves and their generalizations,
(B) Study discrete complex structures and use them to describe more 2D models,
(C) Describe the scaling limits of random planar graphs by the Liouville Quantum Gravity,
(D) Understand universality and lay framework for the Renormalization Group Formalism,
(E) Go beyond the current setup of spin models and SLEs.
These problems are known to be very difficult, but fundamental questions, which have the potential to lead to significant breakthroughs in our understanding of phase transitions, allowing for further progresses. In resolving them, we plan to exploit interactions of different subjects, and recent advances are encouraging."
Max ERC Funding
1 995 900 €
Duration
Start date: 2014-01-01, End date: 2018-12-31
Project acronym COMPAT
Project Complex Patterns for Strongly Interacting Dynamical Systems
Researcher (PI) Susanna Terracini
Host Institution (HI) UNIVERSITA DEGLI STUDI DI TORINO
Country Italy
Call Details Advanced Grant (AdG), PE1, ERC-2013-ADG
Summary This project focuses on nontrivial solutions of systems of differential equations characterized by strongly nonlinear interactions. We are interested in the effect of the nonlinearities on the emergence of non trivial self-organized structures. Such patterns correspond to selected solutions of the differential system possessing special symmetries or shadowing particular shapes. We want to understand, from the
mathematical point of view, what are the main mechanisms involved in the aggregation process in terms of the global variational structure of the problem. Following this common thread, we deal with both with the classical N-body problem of Celestial Mechanics, where interactions feature attractive singularities, and competition-diffusion systems, where pattern formation is driven by strongly repulsive forces. More
precisely, we are interested in periodic and bounded solutions, parabolic trajectories with the final intent to build complex motions and possibly obtain the symbolic dynamics for the general N–body problem. On the other hand, we deal with elliptic, parabolic and hyperbolic systems of differential equations with strongly competing interaction terms, modeling both the dynamics of competing populations (Lotka-
Volterra systems) and other interesting physical phenomena, among which the phase segregation of solitary waves of Gross-Pitaevskii systems arising in the study of multicomponent Bose-Einstein condensates. In particular, we will study existence, multiplicity and asymptotic expansions of solutions when the competition parameter tends to infinity. We shall be concerned with optimal partition problems
related to linear and nonlinear eigenvalues
Summary
This project focuses on nontrivial solutions of systems of differential equations characterized by strongly nonlinear interactions. We are interested in the effect of the nonlinearities on the emergence of non trivial self-organized structures. Such patterns correspond to selected solutions of the differential system possessing special symmetries or shadowing particular shapes. We want to understand, from the
mathematical point of view, what are the main mechanisms involved in the aggregation process in terms of the global variational structure of the problem. Following this common thread, we deal with both with the classical N-body problem of Celestial Mechanics, where interactions feature attractive singularities, and competition-diffusion systems, where pattern formation is driven by strongly repulsive forces. More
precisely, we are interested in periodic and bounded solutions, parabolic trajectories with the final intent to build complex motions and possibly obtain the symbolic dynamics for the general N–body problem. On the other hand, we deal with elliptic, parabolic and hyperbolic systems of differential equations with strongly competing interaction terms, modeling both the dynamics of competing populations (Lotka-
Volterra systems) and other interesting physical phenomena, among which the phase segregation of solitary waves of Gross-Pitaevskii systems arising in the study of multicomponent Bose-Einstein condensates. In particular, we will study existence, multiplicity and asymptotic expansions of solutions when the competition parameter tends to infinity. We shall be concerned with optimal partition problems
related to linear and nonlinear eigenvalues
Max ERC Funding
1 346 145 €
Duration
Start date: 2014-02-01, End date: 2019-01-31
Project acronym COORDINATINGforLIFE
Project Coordinating for life. Success and failure of Western European societies in coping with rural hazards and disasters, 1300-1800
Researcher (PI) Balthassar Jozef Paul (Bas) Van Bavel
Host Institution (HI) UNIVERSITEIT UTRECHT
Country Netherlands
Call Details Advanced Grant (AdG), SH6, ERC-2013-ADG
Summary Societies in past and present are regularly confronted with major hazards, which sometimes have disastrous effects. Some societies are successful in preventing these effects and buffering threats, or they recover quickly, while others prove highly vulnerable. Why is this?
Increasingly it is clear that disasters are not merely natural events, and also that wealth and technology alone are not adequate to prevent them. Rather, hazards and disasters are social occurrences as well, and they form a tough test for the organizational capacities of a society, both in mitigation and recovery. This project targets a main element of this capacity, namely: the way societies have organized the exchange, allocation and use of resources. It aims to explain why some societies do well in preventing or remedying disasters through these institutional arrangements and others not.
In order to do so, this project analyses four key variables: the mix of coordination systems available within that society, its degree of autarky, economic equity and political equality. The recent literature on historical and present-day disasters suggests these factors as possible causes of success or failure of institutional arrangements in their confrontation with hazards, but their discussion remains largely descriptive and they have never been systematically analyzed.
This research project offers such a systematic investigation, using rural societies in Western Europe in the period 1300-1800 - with their variety of socio-economic characteristics - as a testing ground. The historical perspective enables us to compare widely differing cases, also over the long run, and to test for the variables chosen, in order to isolate the determining factors in the resilience of different societies. By using the opportunities offered by history in this way, we will increase our insight into the relative performance of societies and gain a better understanding of a critical determinant of human wellbeing.
Summary
Societies in past and present are regularly confronted with major hazards, which sometimes have disastrous effects. Some societies are successful in preventing these effects and buffering threats, or they recover quickly, while others prove highly vulnerable. Why is this?
Increasingly it is clear that disasters are not merely natural events, and also that wealth and technology alone are not adequate to prevent them. Rather, hazards and disasters are social occurrences as well, and they form a tough test for the organizational capacities of a society, both in mitigation and recovery. This project targets a main element of this capacity, namely: the way societies have organized the exchange, allocation and use of resources. It aims to explain why some societies do well in preventing or remedying disasters through these institutional arrangements and others not.
In order to do so, this project analyses four key variables: the mix of coordination systems available within that society, its degree of autarky, economic equity and political equality. The recent literature on historical and present-day disasters suggests these factors as possible causes of success or failure of institutional arrangements in their confrontation with hazards, but their discussion remains largely descriptive and they have never been systematically analyzed.
This research project offers such a systematic investigation, using rural societies in Western Europe in the period 1300-1800 - with their variety of socio-economic characteristics - as a testing ground. The historical perspective enables us to compare widely differing cases, also over the long run, and to test for the variables chosen, in order to isolate the determining factors in the resilience of different societies. By using the opportunities offered by history in this way, we will increase our insight into the relative performance of societies and gain a better understanding of a critical determinant of human wellbeing.
Max ERC Funding
2 227 326 €
Duration
Start date: 2014-03-01, End date: 2019-02-28
Project acronym COS
Project "The Cult of Saints: a christendom-wide study of its origins, spread and development"
Researcher (PI) Bryan Ward-Perkins
Host Institution (HI) THE CHANCELLOR, MASTERS AND SCHOLARS OF THE UNIVERSITY OF OXFORD
Country United Kingdom
Call Details Advanced Grant (AdG), SH6, ERC-2013-ADG
Summary "An investigation of the origins and development of a central feature of late-antique, medieval and modern culture: the belief that dead saints can act as mediators between a distant God and humankind, and that they are active on earth in many different ways (such as healing the sick, punishing the irreverent, or even controlling the weather).
The project will investigate the emergence of this belief by systematically collecting all the available evidence - across several academic disciplines and six linguistic cultures (Latin, Greek, Syriac, Coptic, Armenian and Georgian), from the first stirrings of the phenomenon in the third century until around the year 700, by which time the cult of saints was fully developed and firmly rooted throughout the Christian world, from Ireland to Iran.
The work will be done by a team of researchers (under expert supervision for four of the eastern languages), closely co-ordinated by the PI. The project will operate concurrently at two levels. The individual researchers will produce free-standing regional studies on aspects of the cult of saints that are essential to the wider project, but at present under-researched. While doing this, they will collect the full range of evidence from their regions within a single searchable database. This will provide the basis for a christendom-wide monograph on the emergence of the cult of saints authored by the PI, and also the context essential to give breadth and depth to the regional studies.
For the first time it will be possible to tell the history of the emergence of the cult of saints across the full geographical and cultural range of early Christendom. Of great importance in itself, this will also link, and thereby enhance, the many pre-existing works of scholarship on aspects of the cult of saints.
The ‘Cult of Saints’ will result in a major summative monograph, a comprehensive international conference, a series of ground-breaking regional studies, and a freely-available database."
Summary
"An investigation of the origins and development of a central feature of late-antique, medieval and modern culture: the belief that dead saints can act as mediators between a distant God and humankind, and that they are active on earth in many different ways (such as healing the sick, punishing the irreverent, or even controlling the weather).
The project will investigate the emergence of this belief by systematically collecting all the available evidence - across several academic disciplines and six linguistic cultures (Latin, Greek, Syriac, Coptic, Armenian and Georgian), from the first stirrings of the phenomenon in the third century until around the year 700, by which time the cult of saints was fully developed and firmly rooted throughout the Christian world, from Ireland to Iran.
The work will be done by a team of researchers (under expert supervision for four of the eastern languages), closely co-ordinated by the PI. The project will operate concurrently at two levels. The individual researchers will produce free-standing regional studies on aspects of the cult of saints that are essential to the wider project, but at present under-researched. While doing this, they will collect the full range of evidence from their regions within a single searchable database. This will provide the basis for a christendom-wide monograph on the emergence of the cult of saints authored by the PI, and also the context essential to give breadth and depth to the regional studies.
For the first time it will be possible to tell the history of the emergence of the cult of saints across the full geographical and cultural range of early Christendom. Of great importance in itself, this will also link, and thereby enhance, the many pre-existing works of scholarship on aspects of the cult of saints.
The ‘Cult of Saints’ will result in a major summative monograph, a comprehensive international conference, a series of ground-breaking regional studies, and a freely-available database."
Max ERC Funding
2 499 240 €
Duration
Start date: 2014-01-01, End date: 2018-12-31
