Project acronym ANSR
Project Ab initio approach to nuclear structure and reactions (++)
Researcher (PI) Christian Erik Forssén
Host Institution (HI) CHALMERS TEKNISKA HOEGSKOLA AB
Call Details Starting Grant (StG), PE2, ERC-2009-StG
Summary Today, much interest in several fields of physics is devoted to the study of small, open quantum systems, whose properties are profoundly affected by the environment; i.e., the continuum of decay channels. In nuclear physics, these problems were originally studied in the context of nuclear reactions but their importance has been reestablished with the advent of radioactive-beam physics and the resulting interest in exotic nuclei. In particular, strong theory initiatives in this area of research will be instrumental for the success of the experimental program at the Facility for Antiproton and Ion Research (FAIR) in Germany. In addition, many of the aspects of open quantum systems are also being explored in the rapidly evolving research on ultracold atomic gases, quantum dots, and other nanodevices. A first-principles description of open quantum systems presents a substantial theoretical and computational challenge. However, the current availability of enormous computing power has allowed theorists to make spectacular progress on problems that were previously thought intractable. The importance of computational methods to study quantum many-body systems is stressed in this proposal. Our approach is based on the ab initio no-core shell model (NCSM), which is a well-established theoretical framework aimed originally at an exact description of nuclear structure starting from realistic inter-nucleon forces. A successful completion of this project requires extensions of the NCSM mathematical framework and the development of highly advanced computer codes. The '++' in the project title indicates the interdisciplinary aspects of the present research proposal and the ambition to make a significant impact on connected fields of many-body physics.
Summary
Today, much interest in several fields of physics is devoted to the study of small, open quantum systems, whose properties are profoundly affected by the environment; i.e., the continuum of decay channels. In nuclear physics, these problems were originally studied in the context of nuclear reactions but their importance has been reestablished with the advent of radioactive-beam physics and the resulting interest in exotic nuclei. In particular, strong theory initiatives in this area of research will be instrumental for the success of the experimental program at the Facility for Antiproton and Ion Research (FAIR) in Germany. In addition, many of the aspects of open quantum systems are also being explored in the rapidly evolving research on ultracold atomic gases, quantum dots, and other nanodevices. A first-principles description of open quantum systems presents a substantial theoretical and computational challenge. However, the current availability of enormous computing power has allowed theorists to make spectacular progress on problems that were previously thought intractable. The importance of computational methods to study quantum many-body systems is stressed in this proposal. Our approach is based on the ab initio no-core shell model (NCSM), which is a well-established theoretical framework aimed originally at an exact description of nuclear structure starting from realistic inter-nucleon forces. A successful completion of this project requires extensions of the NCSM mathematical framework and the development of highly advanced computer codes. The '++' in the project title indicates the interdisciplinary aspects of the present research proposal and the ambition to make a significant impact on connected fields of many-body physics.
Max ERC Funding
1 304 800 €
Duration
Start date: 2009-12-01, End date: 2014-11-30
Project acronym BIOFINDER
Project New biomarkers for Alzheimer’s & Parkinson’s diseases - key tools for early diagnosis and drug development
Researcher (PI) Oskar Hansson
Host Institution (HI) LUNDS UNIVERSITET
Call Details Starting Grant (StG), LS7, ERC-2012-StG_20111109
Summary Alzheimer’s disease (AD) and Parkinson’s disease (PD) are common in elderly and the prevalence of these is increasing. AD and PD have distinct pathogenesis, which precede the overt clinical symptoms by 10-15 years, opening a window for early diagnosis and treatment. New disease-modifying therapies are likely to be most efficient if initiated before the patients exhibit overt symptoms, making biomarkers for early diagnosis crucial for future clinical trials. Validated biomarkers would speed up initiation of treatment, avoid unnecessary investigations, and reduce patient insecurity.
AIMS: (1) identify and validate accurate and cost-effective blood-based biomarkers for early identification of those at high risk to develop AD and PD, (2) develop algorithms using advanced imaging and cerebrospinal fluid biomarkers for earlier more accurate diagnoses, and (3) better understand the underlying pathology and early progression of AD and PD, aiming at finding new relevant drug targets.
We will assess well-characterized and clinically relevant populations of patients and healthy elderly. We will use population- and clinic-based cohorts and follow them prospectively for 4 year. Participants will undergo neurocognitive evaluation, provide blood and cerebrospinal fluid, and have brain imaging using advanced MRI protocols and a newly developed PET-tracer visualizing brain amyloid. Sample will be analyzed with quantitative mass spectrometry and high sensitivity immunoassays.
New biomarkers and brain imaging techniques will aid early diagnosis and facilitate the development of disease-modifying therapies, since treatment can start earlier in the disease process. New methods to quantify relevant drug targets, such as oligomers of β-amyloid and α-synuclein, will be vital when selecting drug candidates for large-scale clinical trials. By improving both diagnosis and therapies the social and economic burden of dementia might be reduced by expanding the period of healthy and active aging
Summary
Alzheimer’s disease (AD) and Parkinson’s disease (PD) are common in elderly and the prevalence of these is increasing. AD and PD have distinct pathogenesis, which precede the overt clinical symptoms by 10-15 years, opening a window for early diagnosis and treatment. New disease-modifying therapies are likely to be most efficient if initiated before the patients exhibit overt symptoms, making biomarkers for early diagnosis crucial for future clinical trials. Validated biomarkers would speed up initiation of treatment, avoid unnecessary investigations, and reduce patient insecurity.
AIMS: (1) identify and validate accurate and cost-effective blood-based biomarkers for early identification of those at high risk to develop AD and PD, (2) develop algorithms using advanced imaging and cerebrospinal fluid biomarkers for earlier more accurate diagnoses, and (3) better understand the underlying pathology and early progression of AD and PD, aiming at finding new relevant drug targets.
We will assess well-characterized and clinically relevant populations of patients and healthy elderly. We will use population- and clinic-based cohorts and follow them prospectively for 4 year. Participants will undergo neurocognitive evaluation, provide blood and cerebrospinal fluid, and have brain imaging using advanced MRI protocols and a newly developed PET-tracer visualizing brain amyloid. Sample will be analyzed with quantitative mass spectrometry and high sensitivity immunoassays.
New biomarkers and brain imaging techniques will aid early diagnosis and facilitate the development of disease-modifying therapies, since treatment can start earlier in the disease process. New methods to quantify relevant drug targets, such as oligomers of β-amyloid and α-synuclein, will be vital when selecting drug candidates for large-scale clinical trials. By improving both diagnosis and therapies the social and economic burden of dementia might be reduced by expanding the period of healthy and active aging
Max ERC Funding
1 500 000 €
Duration
Start date: 2013-06-01, End date: 2018-05-31
Project acronym BLAST
Project Eclipsing binary stars as cutting edge laboratories for astrophysics of stellar
structure, stellar evolution and planet formation
Researcher (PI) Maciej Konacki
Host Institution (HI) CENTRUM ASTRONOMICZNE IM. MIKOLAJAKOPERNIKA POLSKIEJ AKADEMII NAUK
Call Details Starting Grant (StG), PE9, ERC-2010-StG_20091028
Summary Spectroscopic binary stars (SB2s) and in particular spectroscopic eclipsing binaries are one of the most useful objects in astrophysics. Their photometric and spectroscopic observations allow one to determine basic parameters of stars and carry out a wide range of tests of stellar structure, evolution and dynamics. Perhaps somewhat surprisingly, they can also contribute to our understanding of the formation and evolution of (extrasolar) planets. We will study eclipsing binary stars by combining the classic - stellar astronomy - and the modern - extrasolar planets - subjects into a cutting edge project.
We propose to search for and subsequently characterize circumbinary planets around ~350 eclipsing SB2s using our own novel cutting edge radial velocity technique for binary stars and a modern version of the photometry based eclipse timing of eclipsing binary stars employing 0.5-m robotic telescopes. We will also derive basic parameters of up to ~700 stars (~350 binaries) with an unprecedented precision. In particular for about 50% of our sample we expect to deliver masses of the components with an accuracy ~10-100 times better than the current state of the art.
Our project will provide unique constraints for the theories of planet formation and evolution and an unprecedented in quality set of the basic parameters of stars to test the theories of the stellar structure and evolution.
Summary
Spectroscopic binary stars (SB2s) and in particular spectroscopic eclipsing binaries are one of the most useful objects in astrophysics. Their photometric and spectroscopic observations allow one to determine basic parameters of stars and carry out a wide range of tests of stellar structure, evolution and dynamics. Perhaps somewhat surprisingly, they can also contribute to our understanding of the formation and evolution of (extrasolar) planets. We will study eclipsing binary stars by combining the classic - stellar astronomy - and the modern - extrasolar planets - subjects into a cutting edge project.
We propose to search for and subsequently characterize circumbinary planets around ~350 eclipsing SB2s using our own novel cutting edge radial velocity technique for binary stars and a modern version of the photometry based eclipse timing of eclipsing binary stars employing 0.5-m robotic telescopes. We will also derive basic parameters of up to ~700 stars (~350 binaries) with an unprecedented precision. In particular for about 50% of our sample we expect to deliver masses of the components with an accuracy ~10-100 times better than the current state of the art.
Our project will provide unique constraints for the theories of planet formation and evolution and an unprecedented in quality set of the basic parameters of stars to test the theories of the stellar structure and evolution.
Max ERC Funding
1 500 000 €
Duration
Start date: 2010-12-01, End date: 2016-11-30
Project acronym CARDIOMICS
Project Cardiomics: Use of -omics methods in large populations for identification of novel drug targets and clinical biomarkers for coronary heart disease
Researcher (PI) Erik Ingelsson
Host Institution (HI) UPPSALA UNIVERSITET
Call Details Starting Grant (StG), LS7, ERC-2013-StG
Summary There is a large need for revitalization of the research on coronary heart disease (CHD) including: a) improved risk prediction and more adequate individually-tailored treatment; and b) new targets for drug development based on pathways previously unknown to be involved in CHD pathophysiology.
The overall goal of this proposal is to improve prevention and treatment of CHD through better understanding of the biology underlying disease development, identification of new biomarkers for improved risk prediction, and discovery of novel targets for drug development.
The specific aims are to:
1) Establish and characterize causal genes in known CHD loci (gene regions) through: a) resequencing of known CHD loci; b) expression profiling in liver, arteries, myocardium and skeletal muscle; c) high-throughput protein profiling; and d) experimental follow-up in zebrafish (Danio rerio) models.
2) Discover new proteins, metabolites and pathways involved in CHD pathophysiology using global proteomic and metabolomic profiling to provide new biomarkers and drug targets.
We will integrate genomic, transcriptomic, metabolomic and proteomic data from five longitudinal, population-based cohort studies with detailed phenotyping and one study with tissue collections for expression studies. The cohort studies include 36,907 individuals; there are 3,093 prevalent CHD cases at baseline and the estimated number of incident (new) events in previously healthy by 2016 is 2,202. In addition, we work with zebrafish model systems to establish causal CHD genes and characterize their mechanisms of action.
We have access to unique study materials, state-of-the art methods, and a strong track record of successful projects in this field. To our knowledge, there are no other groups combining -omics methods to elucidate the whole chain from DNA variation to overt CHD in such large and well-characterized study samples. Further, we are unaware of other groups using zebrafish models to screen for and characterize causal CHD genes. Our work is anticipated to lead to new important insights into the pathophysiology of CHD, identification of new biomarkers for improved risk prediction, and discovery of novel targets for drug development.
Summary
There is a large need for revitalization of the research on coronary heart disease (CHD) including: a) improved risk prediction and more adequate individually-tailored treatment; and b) new targets for drug development based on pathways previously unknown to be involved in CHD pathophysiology.
The overall goal of this proposal is to improve prevention and treatment of CHD through better understanding of the biology underlying disease development, identification of new biomarkers for improved risk prediction, and discovery of novel targets for drug development.
The specific aims are to:
1) Establish and characterize causal genes in known CHD loci (gene regions) through: a) resequencing of known CHD loci; b) expression profiling in liver, arteries, myocardium and skeletal muscle; c) high-throughput protein profiling; and d) experimental follow-up in zebrafish (Danio rerio) models.
2) Discover new proteins, metabolites and pathways involved in CHD pathophysiology using global proteomic and metabolomic profiling to provide new biomarkers and drug targets.
We will integrate genomic, transcriptomic, metabolomic and proteomic data from five longitudinal, population-based cohort studies with detailed phenotyping and one study with tissue collections for expression studies. The cohort studies include 36,907 individuals; there are 3,093 prevalent CHD cases at baseline and the estimated number of incident (new) events in previously healthy by 2016 is 2,202. In addition, we work with zebrafish model systems to establish causal CHD genes and characterize their mechanisms of action.
We have access to unique study materials, state-of-the art methods, and a strong track record of successful projects in this field. To our knowledge, there are no other groups combining -omics methods to elucidate the whole chain from DNA variation to overt CHD in such large and well-characterized study samples. Further, we are unaware of other groups using zebrafish models to screen for and characterize causal CHD genes. Our work is anticipated to lead to new important insights into the pathophysiology of CHD, identification of new biomarkers for improved risk prediction, and discovery of novel targets for drug development.
Max ERC Funding
1 498 224 €
Duration
Start date: 2014-01-01, End date: 2018-12-31
Project acronym CARDIOPREVENT
Project INTEGRATION OF GENOMICS AND CARDIOMETABOLIC PLASMA BIOMARKERS FOR IMPROVED PREDICTION AND PRIMARY PREVENTION OF CARDIOVASCULAR DISEASE
Researcher (PI) Olle Sten Melander
Host Institution (HI) LUNDS UNIVERSITET
Call Details Starting Grant (StG), LS7, ERC-2011-StG_20101109
Summary "By taking advantage of great experience in genetic and cardiovascular epidemiology and some of the largest cohorts in the world including 60 000 unique individuals, the applicant aims at (1) improving CVD risk prediction and (2) identifying mechanisms causally related to CVD development in order to provide novel targets for drug discovery and targeted life style interventions for use in primary prevention.
In SUBPROJECT 1 we aim at identifying disease causing alleles of loci implicated in CVD by Genome Wide Association Studies (GWAS) and to identify rare alleles with large impact on human CVD. We thus perform whole exome and targeted sequencing in early CVD cases and healthy controls and evaluate all identified variants by relating them to incident CVD in 60.000 individuals. Further, we will create a score of all validated CVD gene variants and test whether such a score improves clinical risk assessment over and above traditional risk factors.
In SUBPROJECT 2 we test whether the plasma metabolome- a phenotype representing the product of dietary intake and inherent (e.g. genetic) metabolism- differs between incident CVD cases and controls and between individuals with high and low CVD genetic risk. We further test whether a life style intervention differentially alters the plasma metabolome between individuals with high and low CVD genetic risk. Finally, we will elucidate the mechanisms underlying CVD genetic associations by testing whether myocardial expression of such genes are affected by experimental myocardial infarction (MI) and whether heart function, MI size and the plasma metabolome are affected by adenoviral myocardial CVD gene transfer in rats.
In SUBPROJECT 3 we test whether glucose metabolism and CVD risk factors can be ameliorated by suppressing vasopressin (VP) by increased water intake in humans. Finally, we test which of the 3 VP receptors is responsible for adverse glucometabolic VP effects in rats by specific VP receptor pharmacological studies."
Summary
"By taking advantage of great experience in genetic and cardiovascular epidemiology and some of the largest cohorts in the world including 60 000 unique individuals, the applicant aims at (1) improving CVD risk prediction and (2) identifying mechanisms causally related to CVD development in order to provide novel targets for drug discovery and targeted life style interventions for use in primary prevention.
In SUBPROJECT 1 we aim at identifying disease causing alleles of loci implicated in CVD by Genome Wide Association Studies (GWAS) and to identify rare alleles with large impact on human CVD. We thus perform whole exome and targeted sequencing in early CVD cases and healthy controls and evaluate all identified variants by relating them to incident CVD in 60.000 individuals. Further, we will create a score of all validated CVD gene variants and test whether such a score improves clinical risk assessment over and above traditional risk factors.
In SUBPROJECT 2 we test whether the plasma metabolome- a phenotype representing the product of dietary intake and inherent (e.g. genetic) metabolism- differs between incident CVD cases and controls and between individuals with high and low CVD genetic risk. We further test whether a life style intervention differentially alters the plasma metabolome between individuals with high and low CVD genetic risk. Finally, we will elucidate the mechanisms underlying CVD genetic associations by testing whether myocardial expression of such genes are affected by experimental myocardial infarction (MI) and whether heart function, MI size and the plasma metabolome are affected by adenoviral myocardial CVD gene transfer in rats.
In SUBPROJECT 3 we test whether glucose metabolism and CVD risk factors can be ameliorated by suppressing vasopressin (VP) by increased water intake in humans. Finally, we test which of the 3 VP receptors is responsible for adverse glucometabolic VP effects in rats by specific VP receptor pharmacological studies."
Max ERC Funding
1 500 000 €
Duration
Start date: 2011-12-01, End date: 2016-11-30
Project acronym Cat-In-hAT
Project Catastrophic Interactions of Binary Stars and the Associated Transients
Researcher (PI) Ondrej PEJCHA
Host Institution (HI) UNIVERZITA KARLOVA
Call Details Starting Grant (StG), PE9, ERC-2018-STG
Summary "One of the crucial formation channels of compact object binaries, including sources of gravitational waves, critically depends on catastrophic binary interactions accompanied by the loss of mass, angular momentum, and energy (""common envelope"" evolution - CEE). Despite its importance, CEE is perhaps the least understood major phase of binary star evolution and progress in this area is urgently needed to interpret observations from the new facilities (gravitational wave detectors, time-domain surveys).
Recently, the dynamical phase of the CEE has been associated with a class of transient brightenings exhibiting slow expansion velocities and copious formation of dust and molecules (red transients - RT). A number of RT features, especially the long timescale of mass loss, challenge the existing CEE paradigm.
Motivated by RT, I will use a new variant of magnetohydrodynamics to comprehensively examine the 3D evolution of CEE from the moment when the mass loss commences to the remnant phase. I expect to resolve the long timescales observed in RT, characterize binary stability in 3D with detailed microphysics, illuminate the fundamental problem of how is orbital energy used to unbind the common envelope in a regime that was inaccessible before, and break new ground on the amplification of magnetic fields during CEE.
I will establish RT as an entirely new probe of the CEE physics by comparing my detailed theoretical predictions of light curves from different viewing angles, spectra, line profiles, and polarimetric signatures with observations of RT. I will accomplish this by coupling multi-dimensional moving mesh hydrodynamics with radiation, dust formation, and chemical reactions. Finally, I will examine the physical processes in RT remnants on timescales of years to centuries after the outburst to connect RT with the proposed merger products and to identify them in time-domain surveys.
"
Summary
"One of the crucial formation channels of compact object binaries, including sources of gravitational waves, critically depends on catastrophic binary interactions accompanied by the loss of mass, angular momentum, and energy (""common envelope"" evolution - CEE). Despite its importance, CEE is perhaps the least understood major phase of binary star evolution and progress in this area is urgently needed to interpret observations from the new facilities (gravitational wave detectors, time-domain surveys).
Recently, the dynamical phase of the CEE has been associated with a class of transient brightenings exhibiting slow expansion velocities and copious formation of dust and molecules (red transients - RT). A number of RT features, especially the long timescale of mass loss, challenge the existing CEE paradigm.
Motivated by RT, I will use a new variant of magnetohydrodynamics to comprehensively examine the 3D evolution of CEE from the moment when the mass loss commences to the remnant phase. I expect to resolve the long timescales observed in RT, characterize binary stability in 3D with detailed microphysics, illuminate the fundamental problem of how is orbital energy used to unbind the common envelope in a regime that was inaccessible before, and break new ground on the amplification of magnetic fields during CEE.
I will establish RT as an entirely new probe of the CEE physics by comparing my detailed theoretical predictions of light curves from different viewing angles, spectra, line profiles, and polarimetric signatures with observations of RT. I will accomplish this by coupling multi-dimensional moving mesh hydrodynamics with radiation, dust formation, and chemical reactions. Finally, I will examine the physical processes in RT remnants on timescales of years to centuries after the outburst to connect RT with the proposed merger products and to identify them in time-domain surveys.
"
Max ERC Funding
1 243 219 €
Duration
Start date: 2019-01-01, End date: 2023-12-31
Project acronym collectiveQCD
Project Collectivity in small, srongly interacting systems
Researcher (PI) Korinna ZAPP
Host Institution (HI) LUNDS UNIVERSITET
Call Details Starting Grant (StG), PE2, ERC-2018-STG
Summary In collisions of heavy nuclei at collider energies, for instance at the Large Hadron Collider (LHC) at CERN, the energy density is so high that an equilibrated Quark-Gluon Plasma (QGP), an exotic state of matter consisting of deconfined quarks and gluons, is formed. In proton-proton (p+p) collisions, on the other hand, the density of produced particles is low. The traditional view on such reactions is that final state particles are free and do not rescatter. This picture is challenged by recent LHC data, which found features in p+p collisions that are indicative of collective behaviour and/or the formation of a hot and dense system. These findings have been taken as signs of QGP formation in p+p reactions. Such an interpretation is complicated by the fact that jets, which are the manifestation of very energetic quarks and gluons, are quenched in heavy ion collisions, but appear to be unmodified in p+p reactions. This is puzzling because collectivity and jet quenching are caused by the same processes. So far there is no consensus about the interpretation of these results, which is also due to a lack of suitable tools.
It is the objective of this proposal to address the question whether there are collective effects in p+p collisions. To this end two models capable of describing all relevant aspects of p+p and heavy ion collisions will be developed. They will be obtained by extending a successful description of p+p to heavy ion reactions and vice versa.
The answer to these questions will either clarify the long-standing problem how collectivity emerges from fundamental interactions, or it will necessitate qualitative changes to our interpretation of collective phenomena in p+p and/or heavy ion collisions.
The PI is in a unique position to accomplish this goal, as she has spent her entire career working on different aspects of p+p and heavy ion collisions. The group in Lund is the ideal host, as it is very active in developing alternative interpretations of the data.
Summary
In collisions of heavy nuclei at collider energies, for instance at the Large Hadron Collider (LHC) at CERN, the energy density is so high that an equilibrated Quark-Gluon Plasma (QGP), an exotic state of matter consisting of deconfined quarks and gluons, is formed. In proton-proton (p+p) collisions, on the other hand, the density of produced particles is low. The traditional view on such reactions is that final state particles are free and do not rescatter. This picture is challenged by recent LHC data, which found features in p+p collisions that are indicative of collective behaviour and/or the formation of a hot and dense system. These findings have been taken as signs of QGP formation in p+p reactions. Such an interpretation is complicated by the fact that jets, which are the manifestation of very energetic quarks and gluons, are quenched in heavy ion collisions, but appear to be unmodified in p+p reactions. This is puzzling because collectivity and jet quenching are caused by the same processes. So far there is no consensus about the interpretation of these results, which is also due to a lack of suitable tools.
It is the objective of this proposal to address the question whether there are collective effects in p+p collisions. To this end two models capable of describing all relevant aspects of p+p and heavy ion collisions will be developed. They will be obtained by extending a successful description of p+p to heavy ion reactions and vice versa.
The answer to these questions will either clarify the long-standing problem how collectivity emerges from fundamental interactions, or it will necessitate qualitative changes to our interpretation of collective phenomena in p+p and/or heavy ion collisions.
The PI is in a unique position to accomplish this goal, as she has spent her entire career working on different aspects of p+p and heavy ion collisions. The group in Lund is the ideal host, as it is very active in developing alternative interpretations of the data.
Max ERC Funding
1 500 000 €
Duration
Start date: 2019-02-01, End date: 2024-01-31
Project acronym CurvedSusy
Project Dynamics of Supersymmetry in Curved Space
Researcher (PI) Guido Festuccia
Host Institution (HI) UPPSALA UNIVERSITET
Call Details Starting Grant (StG), PE2, ERC-2014-STG
Summary Quantum field theory provides a theoretical framework to explain quantitatively natural phenomena as diverse as the fluctuations in the cosmic microwave background, superconductivity, and elementary particle interactions in colliders. Even if we use quantum field theories in different settings, their structure and dynamics are still largely mysterious. Weakly coupled systems can be studied perturbatively, however many natural phenomena are characterized by strong self-interactions (e.g. high T superconductors, nuclear forces) and their analysis requires going beyond perturbation theory. Supersymmetric field theories are very interesting in this respect because they can be studied exactly even at strong coupling and their dynamics displays phenomena like confinement or the breaking of chiral symmetries that occur in nature and are very difficult to study analytically.
Recently it was realized that many interesting insights on the dynamics of supersymmetric field theories can be obtained by placing these theories in curved space preserving supersymmetry. These advances have opened new research avenues but also left many important questions unanswered. The aim of our research programme will be to clarify the dynamics of supersymmetric field theories in curved space and use this knowledge to establish new exact results for strongly coupled supersymmetric gauge theories. The novelty of our approach resides in the systematic use of the interplay between the physical properties of a supersymmetric theory and the geometrical properties of the space-time it lives in. The analytical results we will obtain, while derived for very symmetric theories, can be used as a guide in understanding the dynamics of many physical systems. Besides providing new tools to address the dynamics of quantum field theory at strong coupling this line of investigation could lead to new connections between Physics and Mathematics.
Summary
Quantum field theory provides a theoretical framework to explain quantitatively natural phenomena as diverse as the fluctuations in the cosmic microwave background, superconductivity, and elementary particle interactions in colliders. Even if we use quantum field theories in different settings, their structure and dynamics are still largely mysterious. Weakly coupled systems can be studied perturbatively, however many natural phenomena are characterized by strong self-interactions (e.g. high T superconductors, nuclear forces) and their analysis requires going beyond perturbation theory. Supersymmetric field theories are very interesting in this respect because they can be studied exactly even at strong coupling and their dynamics displays phenomena like confinement or the breaking of chiral symmetries that occur in nature and are very difficult to study analytically.
Recently it was realized that many interesting insights on the dynamics of supersymmetric field theories can be obtained by placing these theories in curved space preserving supersymmetry. These advances have opened new research avenues but also left many important questions unanswered. The aim of our research programme will be to clarify the dynamics of supersymmetric field theories in curved space and use this knowledge to establish new exact results for strongly coupled supersymmetric gauge theories. The novelty of our approach resides in the systematic use of the interplay between the physical properties of a supersymmetric theory and the geometrical properties of the space-time it lives in. The analytical results we will obtain, while derived for very symmetric theories, can be used as a guide in understanding the dynamics of many physical systems. Besides providing new tools to address the dynamics of quantum field theory at strong coupling this line of investigation could lead to new connections between Physics and Mathematics.
Max ERC Funding
1 145 879 €
Duration
Start date: 2015-09-01, End date: 2020-08-31
Project acronym DARKJETS
Project Discovery strategies for Dark Matter and new phenomena in hadronic signatures with the ATLAS detector at the Large Hadron Collider
Researcher (PI) Caterina Doglioni
Host Institution (HI) LUNDS UNIVERSITET
Call Details Starting Grant (StG), PE2, ERC-2015-STG
Summary The Standard Model of Particle Physics describes the fundamental components of ordinary matter and their interactions. Despite its success in predicting many experimental results, the Standard Model fails to account for a number of interesting phenomena. One phenomenon of particular interest is the large excess of unobservable (Dark) matter in the Universe. This excess cannot be explained by Standard Model particles. A compelling hypothesis is that Dark Matter is comprised of particles that can be produced in the proton-proton collisions from the Large Hadron Collider (LHC) at CERN.
Within this project, I will build a team of researchers at Lund University dedicated to searches for signals of the presence of Dark Matter particles. The discovery strategies employed seek the decays of particles that either mediate the interactions between Dark and Standard Model particles or are produced in association with Dark Matter. These new particles manifest in detectors as two, three, or four collimated jets of particles (hadronic jets).
The LHC will resume delivery of proton-proton collisions to the ATLAS detector in 2015. Searches for new, rare, low mass particles such as Dark Matter mediators have so far been hindered by constraints on the rates of data that can be stored. These constraints will be overcome through the implementation of a novel real-time data analysis technique and a new search signature, both introduced to ATLAS by this project. The coincidence of this project with the upcoming LHC runs and the software and hardware improvements within the ATLAS detector is a unique opportunity to increase the sensitivity to hadronically decaying new particles by a large margin with respect to any previous searches. The results of these searches will be interpreted within a comprehensive and coherent set of theoretical benchmarks, highlighting the strengths of collider experiments in the global quest for Dark Matter.
Summary
The Standard Model of Particle Physics describes the fundamental components of ordinary matter and their interactions. Despite its success in predicting many experimental results, the Standard Model fails to account for a number of interesting phenomena. One phenomenon of particular interest is the large excess of unobservable (Dark) matter in the Universe. This excess cannot be explained by Standard Model particles. A compelling hypothesis is that Dark Matter is comprised of particles that can be produced in the proton-proton collisions from the Large Hadron Collider (LHC) at CERN.
Within this project, I will build a team of researchers at Lund University dedicated to searches for signals of the presence of Dark Matter particles. The discovery strategies employed seek the decays of particles that either mediate the interactions between Dark and Standard Model particles or are produced in association with Dark Matter. These new particles manifest in detectors as two, three, or four collimated jets of particles (hadronic jets).
The LHC will resume delivery of proton-proton collisions to the ATLAS detector in 2015. Searches for new, rare, low mass particles such as Dark Matter mediators have so far been hindered by constraints on the rates of data that can be stored. These constraints will be overcome through the implementation of a novel real-time data analysis technique and a new search signature, both introduced to ATLAS by this project. The coincidence of this project with the upcoming LHC runs and the software and hardware improvements within the ATLAS detector is a unique opportunity to increase the sensitivity to hadronically decaying new particles by a large margin with respect to any previous searches. The results of these searches will be interpreted within a comprehensive and coherent set of theoretical benchmarks, highlighting the strengths of collider experiments in the global quest for Dark Matter.
Max ERC Funding
1 268 076 €
Duration
Start date: 2016-02-01, End date: 2021-01-31
Project acronym DIALOY
Project Mosaic loss of chromosome Y (LOY) in blood cells - a new biomarker for risk of cancer and Alzheimer’s disease in men
Researcher (PI) Lars Anders Forsberg
Host Institution (HI) UPPSALA UNIVERSITET
Call Details Starting Grant (StG), LS7, ERC-2015-STG
Summary My recent discoveries show that mosaic loss of chromosome Y (LOY) in peripheral blood is associated with increased risks of cancer and Alzheimer’s disease (AD). These conditions are responsible for >50% of morbidity/mortality in aging men. More than 15% of men older than 70 show some degree of LOY and these men survive on average only half as long as men without LOY. Smoking is strongly associated with LOY and remarkably, the fraction of cells with LOY decreases after cessation of smoking. Cells with LOY can be detected, and disease risks predicted, many years before clinical manifestation of disease. These results of associations between LOY, cancer and smoking have been published in Nature Genetics and Science during 2014.
The overall objective of the proposal is to develop LOY as a new, strong and predictive biomarker. To this end, the research program focuses on three objectives: 1) expanding the study of LOY and associations with disease risks in still larger cohorts; 2) investigating functional aspects of LOY; and 3) develop improved technology for LOY-detection. The successful execution of the project is essential before LOY-testing in clinics can be realized.
Diagnosis of cancer and AD in modern medicine is based on clinical symptoms of disease. Through earlier identification of individuals at increased risk for disease, preventive strategies could be applied, before the severe stages appear. Preliminary results affirm the feasibility of the project and provide proof-of-concept that LOY-tests can be used for early identification of men with increased risks for these diseases. In addition to improving diagnostics and therapeutics; implementation of LOY-testing could prevent smoking-related disease and reduce the health care costs. In the end, LOY-testing could decrease male mortality rates and possibly eliminate the sex-difference in life expectancy. The project will therefore benefit individual patients as well as healthcare systems and society at large.
Summary
My recent discoveries show that mosaic loss of chromosome Y (LOY) in peripheral blood is associated with increased risks of cancer and Alzheimer’s disease (AD). These conditions are responsible for >50% of morbidity/mortality in aging men. More than 15% of men older than 70 show some degree of LOY and these men survive on average only half as long as men without LOY. Smoking is strongly associated with LOY and remarkably, the fraction of cells with LOY decreases after cessation of smoking. Cells with LOY can be detected, and disease risks predicted, many years before clinical manifestation of disease. These results of associations between LOY, cancer and smoking have been published in Nature Genetics and Science during 2014.
The overall objective of the proposal is to develop LOY as a new, strong and predictive biomarker. To this end, the research program focuses on three objectives: 1) expanding the study of LOY and associations with disease risks in still larger cohorts; 2) investigating functional aspects of LOY; and 3) develop improved technology for LOY-detection. The successful execution of the project is essential before LOY-testing in clinics can be realized.
Diagnosis of cancer and AD in modern medicine is based on clinical symptoms of disease. Through earlier identification of individuals at increased risk for disease, preventive strategies could be applied, before the severe stages appear. Preliminary results affirm the feasibility of the project and provide proof-of-concept that LOY-tests can be used for early identification of men with increased risks for these diseases. In addition to improving diagnostics and therapeutics; implementation of LOY-testing could prevent smoking-related disease and reduce the health care costs. In the end, LOY-testing could decrease male mortality rates and possibly eliminate the sex-difference in life expectancy. The project will therefore benefit individual patients as well as healthcare systems and society at large.
Max ERC Funding
1 525 000 €
Duration
Start date: 2016-03-01, End date: 2021-02-28
