PhD subjects
| 10 sujets IPhT |
Dernière mise à jour : 21-07-2019
S-matrix methods for effective field theories
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Contact : |
Starting date :
| Contact : |
|
| Thesis supervisor : |
|
Laboratory link : https://www.ipht.fr
Historically, progress in understanding fundamental physics has been driven mostly by experimental
discoveries. Yet purely theoretical (at the time) developments have played pivotal roles as well, to mention
only the Yang-Mills theories or the Higgs mechanism. Now it may be a good time to reappraise the basics
of our quantum mechanical description of elementary particles.
Such a description is intrinsically rooted in the Effective Field Theory approach, that is one of the
deepest and most useful guiding principles in physics. Its tools and methods allow one to study the
universal aspects of entire classes of unknown microscopic models, with their main features being captured
by symmetries and few relevant parameters of the effective degrees of freedom. Because of its universality,
Effective Field Theories find applications across all scale in physics: from super-Hubble scales all the way
to the Planck length, passing from the TeV scale relevant at particle colliders.
At the same time, alternative conceptual and computational methods are making their way into particle
physics. These are built upon very basic axioms: Poincaré invariance, locality, causality, and unitarity of
the scattering S-matrix, without necessarily introducing auxiliary objects like fields, Lagrangians, gauge
invariance, etc. These new methods allow one to reformulate known facts about effective field theory in a
simpler and more intuitive language, and often to derive new surprising results that would be difficult to
uncover using the traditional techniques.
New applications of the S-matrix approach to Effective Field Theory will be the focus of this PhD
project.
One direction of exploration of this project will involve the so-called on-shell amplitude methods, where
probabilities of particle processes are calculated using recursion relations rather than Feynman diagrams.
Most of the existing applications is in theories with massless particles, such as gluons or gravitons. Recently,
a convenient formalism was proposed to extend these methods to particles with arbitrary masses. This
opens a possibility to study a larger class of theories, such as the spontaneously broken Yang-Mills theories
with massive vector bosons. Taking advantage of this new formalism, this PhD project will undertake
a systematic exploration of the Standard Model and its effective theory extensions using the on-shell
amplitude methods.
Another important question is related to calculating operator mixing in Effective Field Theories. Renor-
malization group equations for Wilson coefficients of effective operators can be laboriously calculated for
certain theories using the standard Feynman diagram techniques. However, using the amplitude methods
allows one to obtain the same results more efficiently, and also to uncover new surprising patterns and
non-renormalization theorems. One of the tasks in this PhD project will be to generalize these methods,
e.g. to finite renormalization terms, to massive theories, and apply them to explicit classes of theories of
interest in particle physics and cosmology. Constraints on the renormalization group flow from amplitudes’
positivity techniques will be explored as well.
The project will also develop new theoretical methods to study the effective theory of massive higher-
spin theories, as well as the generalization of galileon symmetries that control their high-energy scattering
processes. Our goal is to write down the most general effective theory for higher spin particles interacting
with matter employing S-matrix techniques, including positivity bounds for scattering amplitudes. With
that framework at hand, we will be able to explore the phenomenology of higher-spin particles in colliders
and in cosmology. In the very same spirit of the various no-go theorems that forbid exactly massless higher
spins, one can establish general scaling properties of the interactions between light (but not massless)
higher spins and ordinary matter. As those interactions must be be strongly suppressed at low energies,
one could address the question whether higher spin particles can constitute the dark matter in the universe.
discoveries. Yet purely theoretical (at the time) developments have played pivotal roles as well, to mention
only the Yang-Mills theories or the Higgs mechanism. Now it may be a good time to reappraise the basics
of our quantum mechanical description of elementary particles.
Such a description is intrinsically rooted in the Effective Field Theory approach, that is one of the
deepest and most useful guiding principles in physics. Its tools and methods allow one to study the
universal aspects of entire classes of unknown microscopic models, with their main features being captured
by symmetries and few relevant parameters of the effective degrees of freedom. Because of its universality,
Effective Field Theories find applications across all scale in physics: from super-Hubble scales all the way
to the Planck length, passing from the TeV scale relevant at particle colliders.
At the same time, alternative conceptual and computational methods are making their way into particle
physics. These are built upon very basic axioms: Poincaré invariance, locality, causality, and unitarity of
the scattering S-matrix, without necessarily introducing auxiliary objects like fields, Lagrangians, gauge
invariance, etc. These new methods allow one to reformulate known facts about effective field theory in a
simpler and more intuitive language, and often to derive new surprising results that would be difficult to
uncover using the traditional techniques.
New applications of the S-matrix approach to Effective Field Theory will be the focus of this PhD
project.
One direction of exploration of this project will involve the so-called on-shell amplitude methods, where
probabilities of particle processes are calculated using recursion relations rather than Feynman diagrams.
Most of the existing applications is in theories with massless particles, such as gluons or gravitons. Recently,
a convenient formalism was proposed to extend these methods to particles with arbitrary masses. This
opens a possibility to study a larger class of theories, such as the spontaneously broken Yang-Mills theories
with massive vector bosons. Taking advantage of this new formalism, this PhD project will undertake
a systematic exploration of the Standard Model and its effective theory extensions using the on-shell
amplitude methods.
Another important question is related to calculating operator mixing in Effective Field Theories. Renor-
malization group equations for Wilson coefficients of effective operators can be laboriously calculated for
certain theories using the standard Feynman diagram techniques. However, using the amplitude methods
allows one to obtain the same results more efficiently, and also to uncover new surprising patterns and
non-renormalization theorems. One of the tasks in this PhD project will be to generalize these methods,
e.g. to finite renormalization terms, to massive theories, and apply them to explicit classes of theories of
interest in particle physics and cosmology. Constraints on the renormalization group flow from amplitudes’
positivity techniques will be explored as well.
The project will also develop new theoretical methods to study the effective theory of massive higher-
spin theories, as well as the generalization of galileon symmetries that control their high-energy scattering
processes. Our goal is to write down the most general effective theory for higher spin particles interacting
with matter employing S-matrix techniques, including positivity bounds for scattering amplitudes. With
that framework at hand, we will be able to explore the phenomenology of higher-spin particles in colliders
and in cosmology. In the very same spirit of the various no-go theorems that forbid exactly massless higher
spins, one can establish general scaling properties of the interactions between light (but not massless)
higher spins and ordinary matter. As those interactions must be be strongly suppressed at low energies,
one could address the question whether higher spin particles can constitute the dark matter in the universe.
Statistical physics modelling of artificial neural networks
|
Contact : |
Starting date : 01-10-2019
| Contact : |
|
| Thesis supervisor : |
|
Personal web page : https://www.ipht.fr/Phocea/Membres/Annuaire/index.php
Laboratory link : https://www.ipht.fr
There is a long history of statistical physics bringing ideas to machine learning. Some of the commonly
used terms such as Boltzmann machine or Gibbs sampling are witnesses of that. Notably the 80s-90s were
very fruitful period where research in statistical physics brought a range of theoretical results about mod-
els of neural networks, see e.g. [AGS85,GD88,EVB01]. Those results concentrate on probabilistic models
of data (both the data distribution and the map to labels is modelled) in a way complementary to the
mainstream learning theory. Nowadays, the wide use of deep learning brings up a range of open theoreti-
cal questions and challenges that will likely require a synergy of theoretical ideas from several areas in-
cluding theoretical physics. In terms of modelling artificial neural networks, existing physics literature
mostly considers fully connected feedforward neural networks for supervised learning, and restricted
Boltzmann machines for unsupervised learning, it models data as random iid vectors. LZ currently holds
an ERC Starting grant focusing on statistical physics study of fully connected feedforward neural net-
works and auto-encoders, and related theoretical and algorithmic questions.
This PhD project will apply the statistical physics analysis to two classes of neural networks that, as far as
we know, have not yet been studied within this framework (and are not part the above ERC project):
Convolutional neural networks (for supervised learning) and Generative Adversarial Learning (for unsu-
pervised learning). We will evaluate analytically the optimal performance of such networks in the mod-
elled situations and compare it to the performance of efficient algorithm (message passing, and gradient
based algorithms), studied analytically and numerically. The main goal is to understand the behaviour,
advantages and limitations of such networks and improve the algorithmic procedures used for training.
Convolutional neural networks (ConvNets) stand at the basis of majority of modern state-of-the-art im-
age processing systems. Compared to fully connected networks the hidden neurons in ConvNets are con-
nected to only a subset of variables in the previous layer (a so-called receptive field) and usually many of
the hidden neurons connected to different receptive fields share the corresponding vector of weights thus
leading to computational speed up. The ConvNets architectures are also chosen for their ability to impose
the symmetries (e.g. the translational one). The model for ConvNet we have in mind is related to the
committee machine. The two supervisors recently worked on the committee machine neural networks,
while LZ studied its fully connected version [AMB18], PU studied a tree version where weights of each
hidden neuron are independent [FHU18]. The tree committee machine with weights of each hidden neu-
ron being the same is a simple (possibly simplest) model for convolutional neural network previously
studied in theoretical statistics and computer science literature, see e.g. [DLT17]. This model has not been
analyzed yet using the statistical physics methods that can access a broad range of open questions. Its so-
lution should not be more complicated than what is already done in [AMB18, FHU18], thus as ideal sub-
ject for a PhD student. With the solution at hand, many questions about ConvNets, their performance and
learning with efficient algorithms, will become analytically accessible and will be investigated. Exten-
sions to models where the receptive fields overlap will be the next case to study.
Generative adversarial networks (GANs) [GPM14] are often cited as the most influential idea in deep
learning in the past five years. Their purpose is to generate data samples that look statistically indistin-
guishable from sample in the training set. The principle of GANs is very simple: A generator-neural-net-
work is being trained to minimise the accuracy of a discriminator-neural-networks, that is in turn trying
maximise the number of samples classified correctly as coming from the true data versus from the genera-
tor-neural-network. The min-max nature of the training problem, however, causes serious problems to the
training algorithms and it is not understood mathematically when such learning is reliable and leads to
convergence and when it does not. A very recent work [WHL18] proposed a very elegant simple model of
GANs and analyzed the behavior of online learning in the model. The goal of this thesis project is to ana-
lyze the batch learning in this model of GANs, the underlying algorithms, their convergence and proper-
ties. From the point of view of existing research the above model of GANs can be seen as a combination
of a low-rank matrix factorisation model, and a perceptron problems with structured disorder. Both these
models were studied extensively by both of the supervisors, e.g. [LKZ17, FPSUZ17], and we are positive
that their combination corresponding the the above model of GANs can also be analyzed in a closed
form.
The longer term goal of this project is to understand the underlying principles of why the current deep
learning methods work well, what are their limitations and how they can be further improved. The two
supervisors combine expertise of the powerful methodology coming from statistical physics of disordered
systems, that is applicable to study of high-dimensional non-convex problems, and experience in multi-
disciplinary applications of this methodology. The student shall be trained in this vibrant field having ap-
plications in modern data analysis and machine learning which should be a great asset for his/her future
career prospects.
References
[AGS85] Amit, D. J., Gutfreund, H., & Sompolinsky, H. (1985). Spin-glass models of neural networks. Phys. Rev. A, 32(2), 1007.
[AMB18] Aubin, B., Maillard, A., Barbier, J., Krzakala, F., Macris, N., & Zdeborová, L. (2018). The committee machine: Com-
putational to statistical gaps in learning a two-layers neural network. arXiv preprint arXiv:1806.05451.
[DLT17] Du, S.S., Lee, J.D., Tian, Y., Poczos, B., & Singh, A. (2017). Gradient Descent Learns One-hidden-layer CNN: Don’t be
Afraid of Spurious Local Minima. arXiv:1712.00779
[EVB01] Engel A., Van Den Broeck C. (2001), Statistical Mechanics of Learning, Cambridge.
[FPSUZ17] Franz, S., Parisi, G., Sevelev, M., Urbani, P. & Zamponi, F. (2017) Universality of the SAT-UNSAT (jamming)
threshold in non-convex continuous constraint satisfaction problems, SciPost Phys. 2, 019.
[FHU18] Franz, S., Hwang, S., & Urbani, P. (2018). Jamming in multilayer supervised learning models. ArXiv:1809.09945.
[GD88] Gardner, E., & Derrida, B. (1988). Optimal storage properties of neural network models. J. Phys. A: Math. and Gen.
[GPM14] Goodfellow, I., Pouget-Abadie, J., Mirza, M., Xu, B., Warde-Farley, D., Ozair, S., ... & Bengio, Y. (2014). Generative
adversarial nets. In Advances in neural information processing systems (pp. 2672-2680).
[LKZ17] Lesieur, T., Krzakala, F., & Zdeborová, L. (2017). Constrained low-rank matrix estimation: Phase transitions, approxi-
mate message passing and applications. J. Stat. Mech.: Th. and Exp. 073403
[WHL18] Wang, C., Hu, H., & Lu, Y. M. (2018). A Solvable High-Dimensional Model of GAN. Preprint arXiv:1805.08349.
used terms such as Boltzmann machine or Gibbs sampling are witnesses of that. Notably the 80s-90s were
very fruitful period where research in statistical physics brought a range of theoretical results about mod-
els of neural networks, see e.g. [AGS85,GD88,EVB01]. Those results concentrate on probabilistic models
of data (both the data distribution and the map to labels is modelled) in a way complementary to the
mainstream learning theory. Nowadays, the wide use of deep learning brings up a range of open theoreti-
cal questions and challenges that will likely require a synergy of theoretical ideas from several areas in-
cluding theoretical physics. In terms of modelling artificial neural networks, existing physics literature
mostly considers fully connected feedforward neural networks for supervised learning, and restricted
Boltzmann machines for unsupervised learning, it models data as random iid vectors. LZ currently holds
an ERC Starting grant focusing on statistical physics study of fully connected feedforward neural net-
works and auto-encoders, and related theoretical and algorithmic questions.
This PhD project will apply the statistical physics analysis to two classes of neural networks that, as far as
we know, have not yet been studied within this framework (and are not part the above ERC project):
Convolutional neural networks (for supervised learning) and Generative Adversarial Learning (for unsu-
pervised learning). We will evaluate analytically the optimal performance of such networks in the mod-
elled situations and compare it to the performance of efficient algorithm (message passing, and gradient
based algorithms), studied analytically and numerically. The main goal is to understand the behaviour,
advantages and limitations of such networks and improve the algorithmic procedures used for training.
Convolutional neural networks (ConvNets) stand at the basis of majority of modern state-of-the-art im-
age processing systems. Compared to fully connected networks the hidden neurons in ConvNets are con-
nected to only a subset of variables in the previous layer (a so-called receptive field) and usually many of
the hidden neurons connected to different receptive fields share the corresponding vector of weights thus
leading to computational speed up. The ConvNets architectures are also chosen for their ability to impose
the symmetries (e.g. the translational one). The model for ConvNet we have in mind is related to the
committee machine. The two supervisors recently worked on the committee machine neural networks,
while LZ studied its fully connected version [AMB18], PU studied a tree version where weights of each
hidden neuron are independent [FHU18]. The tree committee machine with weights of each hidden neu-
ron being the same is a simple (possibly simplest) model for convolutional neural network previously
studied in theoretical statistics and computer science literature, see e.g. [DLT17]. This model has not been
analyzed yet using the statistical physics methods that can access a broad range of open questions. Its so-
lution should not be more complicated than what is already done in [AMB18, FHU18], thus as ideal sub-
ject for a PhD student. With the solution at hand, many questions about ConvNets, their performance and
learning with efficient algorithms, will become analytically accessible and will be investigated. Exten-
sions to models where the receptive fields overlap will be the next case to study.
Generative adversarial networks (GANs) [GPM14] are often cited as the most influential idea in deep
learning in the past five years. Their purpose is to generate data samples that look statistically indistin-
guishable from sample in the training set. The principle of GANs is very simple: A generator-neural-net-
work is being trained to minimise the accuracy of a discriminator-neural-networks, that is in turn trying
maximise the number of samples classified correctly as coming from the true data versus from the genera-
tor-neural-network. The min-max nature of the training problem, however, causes serious problems to the
training algorithms and it is not understood mathematically when such learning is reliable and leads to
convergence and when it does not. A very recent work [WHL18] proposed a very elegant simple model of
GANs and analyzed the behavior of online learning in the model. The goal of this thesis project is to ana-
lyze the batch learning in this model of GANs, the underlying algorithms, their convergence and proper-
ties. From the point of view of existing research the above model of GANs can be seen as a combination
of a low-rank matrix factorisation model, and a perceptron problems with structured disorder. Both these
models were studied extensively by both of the supervisors, e.g. [LKZ17, FPSUZ17], and we are positive
that their combination corresponding the the above model of GANs can also be analyzed in a closed
form.
The longer term goal of this project is to understand the underlying principles of why the current deep
learning methods work well, what are their limitations and how they can be further improved. The two
supervisors combine expertise of the powerful methodology coming from statistical physics of disordered
systems, that is applicable to study of high-dimensional non-convex problems, and experience in multi-
disciplinary applications of this methodology. The student shall be trained in this vibrant field having ap-
plications in modern data analysis and machine learning which should be a great asset for his/her future
career prospects.
References
[AGS85] Amit, D. J., Gutfreund, H., & Sompolinsky, H. (1985). Spin-glass models of neural networks. Phys. Rev. A, 32(2), 1007.
[AMB18] Aubin, B., Maillard, A., Barbier, J., Krzakala, F., Macris, N., & Zdeborová, L. (2018). The committee machine: Com-
putational to statistical gaps in learning a two-layers neural network. arXiv preprint arXiv:1806.05451.
[DLT17] Du, S.S., Lee, J.D., Tian, Y., Poczos, B., & Singh, A. (2017). Gradient Descent Learns One-hidden-layer CNN: Don’t be
Afraid of Spurious Local Minima. arXiv:1712.00779
[EVB01] Engel A., Van Den Broeck C. (2001), Statistical Mechanics of Learning, Cambridge.
[FPSUZ17] Franz, S., Parisi, G., Sevelev, M., Urbani, P. & Zamponi, F. (2017) Universality of the SAT-UNSAT (jamming)
threshold in non-convex continuous constraint satisfaction problems, SciPost Phys. 2, 019.
[FHU18] Franz, S., Hwang, S., & Urbani, P. (2018). Jamming in multilayer supervised learning models. ArXiv:1809.09945.
[GD88] Gardner, E., & Derrida, B. (1988). Optimal storage properties of neural network models. J. Phys. A: Math. and Gen.
[GPM14] Goodfellow, I., Pouget-Abadie, J., Mirza, M., Xu, B., Warde-Farley, D., Ozair, S., ... & Bengio, Y. (2014). Generative
adversarial nets. In Advances in neural information processing systems (pp. 2672-2680).
[LKZ17] Lesieur, T., Krzakala, F., & Zdeborová, L. (2017). Constrained low-rank matrix estimation: Phase transitions, approxi-
mate message passing and applications. J. Stat. Mech.: Th. and Exp. 073403
[WHL18] Wang, C., Hu, H., & Lu, Y. M. (2018). A Solvable High-Dimensional Model of GAN. Preprint arXiv:1805.08349.
New universality classes in combinatorial models of statistical mechanics
|
Contact : |
Starting date : 01-09-2019
| Contact : |
|
| Thesis supervisor : |
|
Personal web page : https://www.ipht.fr/Pisp/jeremie.bouttier/index_fr.php
Laboratory link : https://ipht.fr
There are deep connections between statistical mechanics and combinatorics, particu-
larly within the realm of “exactly solvable models”. Such models played historically an
important role in the study of phase transitions and critical phenomena, they are still
useful today to analyze for instance systems out of equilibrium, and to prove rigorous
mathematical results. There are many examples of the fascinating interplay between
physics and combinatorics: the 2D Ising model and its connections with dimer models,
spanning trees and free fermions [1]; polymers and self-avoiding walks [2]; the ice/six-
vertex model and alternating sign matrices [3], etc.
In this PhD thesis we propose two directions to investigate:
1. decorated random maps and 2D quantum gravity,
2. 2D dimer models, domino/lozenge tilings, random partitions and Schur processes.
Common to these two directions is the appearance of new universality classes which are
still not fully understood.
Random maps are discretizations of random surfaces, used to model 2D quantum
gravity. Much attention has been devoted to the study of the “uniform” distribution on
random maps: it is for instance known that large planar maps have a fractal structure
of dimension 4, whose essence is described by the so-called Brownian map [4]. But it is
believed that the geometry changes drastically when the maps are decorated by a critical
model of statistical physics, such as Ising/Potts spins or nonintersecting loops [5]. We
propose to investigate some of the properties of such decorated random maps, through
the use of suitable exploration processes [6].
Dimer models are among the simplest combinatorial models of statistical mechanics.
Noninteracting fully-packed dimers in 2D are known to belong to the class of determi-
nantal (or free fermionic) processes. Due to the nonoverlapping constraint, the boundary
conditions may have long-range effects, and cause spatial phase separations. This is the
“limit shape” or “arctic curve” phenomenon, which is now understood rigorously. Of
particular interest is the interface between phases, where we observe universal scaling
limits closely related with random matrices. We propose to investigate a certain family
of models [7] and special boundary conditions [8] giving rise to new scaling limits.
References
[1] D. Chelkak, D. Cimasoni, and A. Kassel. Revisiting the combinatorics of the 2D Ising
model. Ann. Inst. Henri Poincaré D, 4(3):309–385, 2017.
[2] H. Duminil-Copin
and S. Smirnov. The connective constant of the honeycomb lattice
p
v
equals 2 + 2. Ann. of Math. (2), 175(3):1653–1665, 2012.
[3] L. Cantini and A. Sportiello. Proof of the Razumov-Stroganov conjecture. J. Combin.
Theory Ser. A, 118(5):1549–1574, 2011.
[4] G. Miermont. Aspects of random maps. Lecture notes of the 2014 Saint-Flour Proba-
bility Summer School, preliminary version available at http://perso.ens-lyon.fr/
gregory.miermont/coursSaint-Flour.pdf, 2014.
[5] G. Borot, J. Bouttier, and E. Guitter. A recursive approach to the O(n) model on
random maps via nested loops. J. Phys. A, 45(4):045002, 38, 2012.
[6] T. Budd. The peeling process on random planar maps coupled to an O(n) loop model.
arXiv:1809.02012 [math.PR], 2018. With an appendix by L. Chen.
[7] C. Boutillier, J. Bouttier, G. Chapuy, S. Corteel, and S. Ramassamy. Dimers on rail
yard graphs. Ann. Inst. Henri Poincaré D, 4(4):479–539, 2017.
[8] Dan B., J. Bouttier, P. Nejjar, and M. Vuletic. The free boundary Schur process and
applications. Ann. Henri Poincaré, to appear, 2018.
larly within the realm of “exactly solvable models”. Such models played historically an
important role in the study of phase transitions and critical phenomena, they are still
useful today to analyze for instance systems out of equilibrium, and to prove rigorous
mathematical results. There are many examples of the fascinating interplay between
physics and combinatorics: the 2D Ising model and its connections with dimer models,
spanning trees and free fermions [1]; polymers and self-avoiding walks [2]; the ice/six-
vertex model and alternating sign matrices [3], etc.
In this PhD thesis we propose two directions to investigate:
1. decorated random maps and 2D quantum gravity,
2. 2D dimer models, domino/lozenge tilings, random partitions and Schur processes.
Common to these two directions is the appearance of new universality classes which are
still not fully understood.
Random maps are discretizations of random surfaces, used to model 2D quantum
gravity. Much attention has been devoted to the study of the “uniform” distribution on
random maps: it is for instance known that large planar maps have a fractal structure
of dimension 4, whose essence is described by the so-called Brownian map [4]. But it is
believed that the geometry changes drastically when the maps are decorated by a critical
model of statistical physics, such as Ising/Potts spins or nonintersecting loops [5]. We
propose to investigate some of the properties of such decorated random maps, through
the use of suitable exploration processes [6].
Dimer models are among the simplest combinatorial models of statistical mechanics.
Noninteracting fully-packed dimers in 2D are known to belong to the class of determi-
nantal (or free fermionic) processes. Due to the nonoverlapping constraint, the boundary
conditions may have long-range effects, and cause spatial phase separations. This is the
“limit shape” or “arctic curve” phenomenon, which is now understood rigorously. Of
particular interest is the interface between phases, where we observe universal scaling
limits closely related with random matrices. We propose to investigate a certain family
of models [7] and special boundary conditions [8] giving rise to new scaling limits.
References
[1] D. Chelkak, D. Cimasoni, and A. Kassel. Revisiting the combinatorics of the 2D Ising
model. Ann. Inst. Henri Poincaré D, 4(3):309–385, 2017.
[2] H. Duminil-Copin
and S. Smirnov. The connective constant of the honeycomb lattice
p
v
equals 2 + 2. Ann. of Math. (2), 175(3):1653–1665, 2012.
[3] L. Cantini and A. Sportiello. Proof of the Razumov-Stroganov conjecture. J. Combin.
Theory Ser. A, 118(5):1549–1574, 2011.
[4] G. Miermont. Aspects of random maps. Lecture notes of the 2014 Saint-Flour Proba-
bility Summer School, preliminary version available at http://perso.ens-lyon.fr/
gregory.miermont/coursSaint-Flour.pdf, 2014.
[5] G. Borot, J. Bouttier, and E. Guitter. A recursive approach to the O(n) model on
random maps via nested loops. J. Phys. A, 45(4):045002, 38, 2012.
[6] T. Budd. The peeling process on random planar maps coupled to an O(n) loop model.
arXiv:1809.02012 [math.PR], 2018. With an appendix by L. Chen.
[7] C. Boutillier, J. Bouttier, G. Chapuy, S. Corteel, and S. Ramassamy. Dimers on rail
yard graphs. Ann. Inst. Henri Poincaré D, 4(4):479–539, 2017.
[8] Dan B., J. Bouttier, P. Nejjar, and M. Vuletic. The free boundary Schur process and
applications. Ann. Henri Poincaré, to appear, 2018.
Black Hole Microstate Geometries
|
Contact : |
Starting date : 01-10-2019
| Contact : |
|
| Thesis supervisor : |
|
Black Hole Microstate Geometries
Geometries de Micro-état des Trous Noirs.
Black holes are defined to be objects whose gravity is strong enough to trap light. In General Relativity, a black hole not only traps light but also traps all other matter and information inside a surface of no return, called the event horizon. As a result, the exterior of a black hole (outside the horizon) is independent of how, and from what, the black hole formed. Moreover, the exterior structure of a black hole is completely determined by its long-range parameters, like mass, charge and angular momentum. This is black hole uniqueness.
When first formulated in GR, black holes were thought to be unphysical artifacts of imposing symmetry on solutions to Einstein’s equations. However, in the early 1970’s, the singularity theorems of Penrose and Hawking began the shift towards today’s paradigm: black holes are essential parts of Nature. Indeed, by the 1980’s, black holes provided the best description of certain ‘exotic’ binary star systems as well as the engines powering jets from the cores of active galaxies. The LIGO detection of black-hole mergers, in 2015, was the crowning achievement of over a century of theoretical development, finally confirmed by observations of characteristic, extremely strong-field signatures of the black holes of GR.
The “frustrating details” emerge when black-hole physics is combined with quantum mechanics (QM). In 1975, Hawking showed that the correct description of the vacuum around an event horizon leads to the emission of Hawking Radiation as a form of vacuum polarization. Because this radiation originates from just above the horizon, the uniqueness of black holes in GR implies that Hawking radiation is universal, thermal and (almost) featureless. In particular, it is independent of how the black hole formed. Semi-classical back-reaction of this Hawking radiation also implies that the black hole will evaporate, albeit extremely slowly.
This leads to the Information Paradox: It is impossible to reconstruct the interior state of a black hole (apart from mass, charge and angular momentum) from the exterior data, and thus from the final state of the Hawking radiation. The evaporation process cannot, therefore, be represented through a unitary transformation of states in a Hilbert space. Hence black-hole evaporation, as predicted by GR and QM, is inconsistent with a foundational postulate of QM. Based on its horizon area, the black hole at the core of the Milky Way should have about e^(10^90) microstates. From the outside, black-hole uniqueness implies that its state is unique, as would be the state of its Hawking radiation were it to evaporate. The problem is therefore vast: e^(10^90) ? 1!
In 2009, Mathur used quantum information theory to show that Hawking’s information paradox could not be solved incrementally: It will require radical modification of the physics at the scale of the black hole horizon.
The only existing framework in which this can be done while including complete, general-relativistic, gravitational effects is the Microstate Geometry (MG) programme. This programme, which forms the core of this thesis research was started more than 15 years ago by the two supervisors, and has resulted in the construction of huge families of string theory and supergravity (that we call black hole Microstate Geometries) that have no singularity, no horizon, and exactly the same mass, charge, and angular momentum as a black hole.
This thesis has three directions. The first is to analyze the existing Microstate Geometries within the framework of the AdS-CFT correspondence. The second is to construct new Microstate Geometries for supersymmetric black holes. The third is to construct such geometries for non-supersymmetric black holes. The techniques that will be used in the first area are those of the holographic AdS-CFT correspondence, and mastering them will be useful if the student will want to explore other areas of holography. Research in the second direction will be done using supersymmetric solution-building methods of supergravity. These methods will also be useful if the student will want in the future to diversify his or her research interests towards string phenomenology or cosmology. The techniques to be used in the third area will be at first analytical (probe brane actions and factorized supergravity equations for constructing non-supersymmetric solutions), but depending on the preliminary results numerical methods to construct cohomegeneity-two supergravity solutions may also be used.
Applicants are expected to have a solid background in General Relativity and Quantum Field Theory. Knowledge of basic String Theory notions is a bonus.
Geometries de Micro-état des Trous Noirs.
Black holes are defined to be objects whose gravity is strong enough to trap light. In General Relativity, a black hole not only traps light but also traps all other matter and information inside a surface of no return, called the event horizon. As a result, the exterior of a black hole (outside the horizon) is independent of how, and from what, the black hole formed. Moreover, the exterior structure of a black hole is completely determined by its long-range parameters, like mass, charge and angular momentum. This is black hole uniqueness.
When first formulated in GR, black holes were thought to be unphysical artifacts of imposing symmetry on solutions to Einstein’s equations. However, in the early 1970’s, the singularity theorems of Penrose and Hawking began the shift towards today’s paradigm: black holes are essential parts of Nature. Indeed, by the 1980’s, black holes provided the best description of certain ‘exotic’ binary star systems as well as the engines powering jets from the cores of active galaxies. The LIGO detection of black-hole mergers, in 2015, was the crowning achievement of over a century of theoretical development, finally confirmed by observations of characteristic, extremely strong-field signatures of the black holes of GR.
The “frustrating details” emerge when black-hole physics is combined with quantum mechanics (QM). In 1975, Hawking showed that the correct description of the vacuum around an event horizon leads to the emission of Hawking Radiation as a form of vacuum polarization. Because this radiation originates from just above the horizon, the uniqueness of black holes in GR implies that Hawking radiation is universal, thermal and (almost) featureless. In particular, it is independent of how the black hole formed. Semi-classical back-reaction of this Hawking radiation also implies that the black hole will evaporate, albeit extremely slowly.
This leads to the Information Paradox: It is impossible to reconstruct the interior state of a black hole (apart from mass, charge and angular momentum) from the exterior data, and thus from the final state of the Hawking radiation. The evaporation process cannot, therefore, be represented through a unitary transformation of states in a Hilbert space. Hence black-hole evaporation, as predicted by GR and QM, is inconsistent with a foundational postulate of QM. Based on its horizon area, the black hole at the core of the Milky Way should have about e^(10^90) microstates. From the outside, black-hole uniqueness implies that its state is unique, as would be the state of its Hawking radiation were it to evaporate. The problem is therefore vast: e^(10^90) ? 1!
In 2009, Mathur used quantum information theory to show that Hawking’s information paradox could not be solved incrementally: It will require radical modification of the physics at the scale of the black hole horizon.
The only existing framework in which this can be done while including complete, general-relativistic, gravitational effects is the Microstate Geometry (MG) programme. This programme, which forms the core of this thesis research was started more than 15 years ago by the two supervisors, and has resulted in the construction of huge families of string theory and supergravity (that we call black hole Microstate Geometries) that have no singularity, no horizon, and exactly the same mass, charge, and angular momentum as a black hole.
This thesis has three directions. The first is to analyze the existing Microstate Geometries within the framework of the AdS-CFT correspondence. The second is to construct new Microstate Geometries for supersymmetric black holes. The third is to construct such geometries for non-supersymmetric black holes. The techniques that will be used in the first area are those of the holographic AdS-CFT correspondence, and mastering them will be useful if the student will want to explore other areas of holography. Research in the second direction will be done using supersymmetric solution-building methods of supergravity. These methods will also be useful if the student will want in the future to diversify his or her research interests towards string phenomenology or cosmology. The techniques to be used in the third area will be at first analytical (probe brane actions and factorized supergravity equations for constructing non-supersymmetric solutions), but depending on the preliminary results numerical methods to construct cohomegeneity-two supergravity solutions may also be used.
Applicants are expected to have a solid background in General Relativity and Quantum Field Theory. Knowledge of basic String Theory notions is a bonus.
de Sitter vacua in String Theory
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Contact : |
Starting date : 01-10-2019
| Contact : |
|
| Thesis supervisor : |
|
Personal web page : https://www.ipht.fr/Phocea/Membres/Annuaire/index.php?uid=ibena
Laboratory link : https://www.ipht.fr
String Theory is the most promising candidate for a theory that
unifies all the forces that exist in nature, and could therefore
provide a framework from which one may hope to derive all the observed
physical laws. However, String Theory lives in ten dimensions, and to
obtain real-world physics one needs to compactify it on certain
six-dimensional compact spaces that have a size much smaller than any
scale accessible to observations. Since there exist a large number of
such spaces it has been argued that there exist of order 10^{500}
four-dimensional String Theory vacua. These vacua have all possible
physical laws with all possible constants. This has led to a radically
new view of the physics in which one argues that the constants in the
physical laws that we measure in our Universe do not come from an
underlying unified theory, but are environmental,
anthropically-constrained variables that are determined by where we
are in this Multiverse.
Despite the fact that it goes agains the reductionist paradigm that
has driven scientific progress over the past century, the anthropic
explanation is rapidly becoming the favored explanation to the
extremely difficult task of explaining the enormous amount of fine
tuning present in the physical laws. First, the observed accelerated
expansion of the Universe is driven by a mysterious form of energy
density with negative pressure, whose value is 120 orders of magnitude
smaller than expected in particle physics (this was called “the worst
theoretical prediction in the history of physics”). Next comes the
hierarchy problem: the 24 orders of magnitude between the electroweak
energy scale and the gravity scale. Supersymmetry was thought for many
years to provide a beautiful solution to this problem, but the absence
of any LHC signal supporting supersymmetry, after scanning most of the
available phase space, is driving many towards anthropic/multiverse
explanations. Finally, models of cosmological inflation require
considerable fine-tuning when trying to achieve the almost flatness of
the inflationary potential and to meet the upper bound from
2015-Planck results on tensor-to-scalar ratio in the spectrum of
perturbations.
The multiverse paradigm provides a framework where none of these
fine-tunings requires an explanation, and string theory, with its
believed “landscape” of de Sitter vacua, appears to support
it. However, solutions in the landscape are not constructed directly
in ten dimensional string theory, but are found using effective
low-energy descriptions in four space-time dimensions. In order to
satisfy all experimental constraints, the effective theories require a
number of intricate ingredients such as anti-branes, T-branes or
nongeometric fluxes, whose string theory origin and consistency is
unclear. The purpose of this thesis is to examine whether a very large
number of these vacua are in fact unstable or inconsistent with the
experimental data coming out of the Large Hadron Collider. This will
be done by analyzing one of the key ingredients of the Multiverse
construction - the uplifting of the cosmological constant, and taking
into account the embeddings of Standard Model physics in String
Theory.
In parallel to this to-down endeavor to understand de Sitter vacua in
string theory, over the past year there has been an explosion of
interest in this question from the bottom-up perspective: the recent
de Sitter Swampland conjecture, (by Vafa and collaborators
arXiv:1806.08362) proposes that, in the regime of parameters where
calculations can be trusted, all solutions with a positive
cosmological constant are either unstable or have a runaway
behavior. We will attempt to link the top-down results we will obtain
with this line of work, hoping to establish that String Theory does
not support the multiverse paradigm. Applicants are expected to have a
solid background in general relativity and quantum field theory.
Understanding the origin of the laws governing our universe is an
endeavor in which the DRF is positioned very well worldwide, both
theoretically and experimentally: from the LHC group at the IRFU/DPP
that puts stronger and stronger bounds on beyond-the-standard-model
physics, to the Planck group at the IRFU/Département d'Astrophysique
that tries to measure the cosmological parameters of our Universe
using the cosmic microwave background, to the particle theory group at
the IPhT that explores extensions of the Standard Model and the fine
tuning thereof. Moreover, there exists an ongoing line of research to
count and investigate the vacua of string theory using Machine
Learning. One of the talks at the “Séminaire Intelligence Artificielle
et Physique Théorique” organized by DRT/LIST last June was on this
topic.
unifies all the forces that exist in nature, and could therefore
provide a framework from which one may hope to derive all the observed
physical laws. However, String Theory lives in ten dimensions, and to
obtain real-world physics one needs to compactify it on certain
six-dimensional compact spaces that have a size much smaller than any
scale accessible to observations. Since there exist a large number of
such spaces it has been argued that there exist of order 10^{500}
four-dimensional String Theory vacua. These vacua have all possible
physical laws with all possible constants. This has led to a radically
new view of the physics in which one argues that the constants in the
physical laws that we measure in our Universe do not come from an
underlying unified theory, but are environmental,
anthropically-constrained variables that are determined by where we
are in this Multiverse.
Despite the fact that it goes agains the reductionist paradigm that
has driven scientific progress over the past century, the anthropic
explanation is rapidly becoming the favored explanation to the
extremely difficult task of explaining the enormous amount of fine
tuning present in the physical laws. First, the observed accelerated
expansion of the Universe is driven by a mysterious form of energy
density with negative pressure, whose value is 120 orders of magnitude
smaller than expected in particle physics (this was called “the worst
theoretical prediction in the history of physics”). Next comes the
hierarchy problem: the 24 orders of magnitude between the electroweak
energy scale and the gravity scale. Supersymmetry was thought for many
years to provide a beautiful solution to this problem, but the absence
of any LHC signal supporting supersymmetry, after scanning most of the
available phase space, is driving many towards anthropic/multiverse
explanations. Finally, models of cosmological inflation require
considerable fine-tuning when trying to achieve the almost flatness of
the inflationary potential and to meet the upper bound from
2015-Planck results on tensor-to-scalar ratio in the spectrum of
perturbations.
The multiverse paradigm provides a framework where none of these
fine-tunings requires an explanation, and string theory, with its
believed “landscape” of de Sitter vacua, appears to support
it. However, solutions in the landscape are not constructed directly
in ten dimensional string theory, but are found using effective
low-energy descriptions in four space-time dimensions. In order to
satisfy all experimental constraints, the effective theories require a
number of intricate ingredients such as anti-branes, T-branes or
nongeometric fluxes, whose string theory origin and consistency is
unclear. The purpose of this thesis is to examine whether a very large
number of these vacua are in fact unstable or inconsistent with the
experimental data coming out of the Large Hadron Collider. This will
be done by analyzing one of the key ingredients of the Multiverse
construction - the uplifting of the cosmological constant, and taking
into account the embeddings of Standard Model physics in String
Theory.
In parallel to this to-down endeavor to understand de Sitter vacua in
string theory, over the past year there has been an explosion of
interest in this question from the bottom-up perspective: the recent
de Sitter Swampland conjecture, (by Vafa and collaborators
arXiv:1806.08362) proposes that, in the regime of parameters where
calculations can be trusted, all solutions with a positive
cosmological constant are either unstable or have a runaway
behavior. We will attempt to link the top-down results we will obtain
with this line of work, hoping to establish that String Theory does
not support the multiverse paradigm. Applicants are expected to have a
solid background in general relativity and quantum field theory.
Understanding the origin of the laws governing our universe is an
endeavor in which the DRF is positioned very well worldwide, both
theoretically and experimentally: from the LHC group at the IRFU/DPP
that puts stronger and stronger bounds on beyond-the-standard-model
physics, to the Planck group at the IRFU/Département d'Astrophysique
that tries to measure the cosmological parameters of our Universe
using the cosmic microwave background, to the particle theory group at
the IPhT that explores extensions of the Standard Model and the fine
tuning thereof. Moreover, there exists an ongoing line of research to
count and investigate the vacua of string theory using Machine
Learning. One of the talks at the “Séminaire Intelligence Artificielle
et Physique Théorique” organized by DRT/LIST last June was on this
topic.
Black Hole Microstate Geometries
|
Contact : |
Starting date : 01-10-2019
| Contact : |
|
| Thesis supervisor : |
|
More : https://www.ipht.fr
Black holes are defined to be objects whose gravity is strong enough to trap light. In General Relativity, a black hole not only traps light but also traps all other matter and information inside a surface of no return, called the event horizon. As a result, the exterior of a black hole (outside the horizon) is independent of how, and from what, the black hole formed. Moreover, the exterior structure of a black hole is completely determined by its long-range parameters, like mass, charge and angular momentum. This is black hole uniqueness.
When first formulated in GR, black holes were thought to be unphysical artifacts of imposing symmetry on solutions to Einstein’s equations. However, in the early 1970’s, the singularity theorems of Penrose and Hawking began the shift towards today’s paradigm: black holes are essential parts of Nature. Indeed, by the 1980’s, black holes provided the best description of certain ‘exotic’ binary star systems as well as the engines powering jets from the cores of active galaxies. The LIGO detection of black-hole mergers, in 2015, was the crowning achievement of over a century of theoretical development, finally confirmed by observations of characteristic, extremely strong-field signatures of the black holes of GR.
The “frustrating details” emerge when black-hole physics is combined with quantum mechanics (QM). In 1975, Hawking showed that the correct description of the vacuum around an event horizon leads to the emission of Hawking Radiation as a form of vacuum polarization. Because this radiation originates from just above the horizon, the uniqueness of black holes in GR implies that Hawking radiation is universal, thermal and (almost) featureless. In particular, it is independent of how the black hole formed. Semi-classical back-reaction of this Hawking radiation also implies that the black hole will evaporate, albeit extremely slowly.
This leads to the Information Paradox: It is impossible to reconstruct the interior state of a black hole (apart from mass, charge and angular momentum) from the exterior data, and thus from the final state of the Hawking radiation. The evaporation process cannot, therefore, be represented through a unitary transformation of states in a Hilbert space. Hence black-hole evaporation, as predicted by GR and QM, is inconsistent with a foundational postulate of QM. Based on its horizon area, the black hole at the core of the Milky Way should have about e^(10^90) microstates. From the outside, black-hole uniqueness implies that its state is unique, as would be the state of its Hawking radiation were it to evaporate. The problem is therefore vast: e^(10^90) ? 1!
In 2009, Mathur used quantum information theory to show that Hawking’s information paradox could not be solved incrementally: It will require radical modification of the physics at the scale of the black hole horizon.
The only existing framework in which this can be done while including complete, general-relativistic, gravitational effects is the Microstate Geometry (MG) programme. This programme, which forms the core of this thesis research was started more than 15 years ago by the two supervisors, and has resulted in the construction of huge families of string theory and supergravity (that we call black hole Microstate Geometries) that have no singularity, no horizon, and exactly the same mass, charge, and angular momentum as a black hole.
This thesis has three directions. The first is to analyze the existing Microstate Geometries within the framework of the AdS-CFT correspondence. The second is to construct new Microstate Geometries for supersymmetric black holes. The third is to construct such geometries for non-supersymmetric black holes. The techniques that will be used in the first area are those of the holographic AdS-CFT correspondence, and mastering them will be useful if the student will want to explore other areas of holography. Research in the second direction will be done using supersymmetric solution-building methods of supergravity. These methods will also be useful if the student will want in the future to diversify his or her research interests towards string phenomenology or cosmology. The techniques to be used in the third area will be at first analytical (probe brane actions and factorized supergravity equations for constructing non-supersymmetric solutions), but depending on the preliminary results numerical methods to construct cohomegeneity-two supergravity solutions may also be used.
Applicants are expected to have a solid background in General Relativity and Quantum Field Theory. Knowledge of basic String Theory notions is a bonus.
When first formulated in GR, black holes were thought to be unphysical artifacts of imposing symmetry on solutions to Einstein’s equations. However, in the early 1970’s, the singularity theorems of Penrose and Hawking began the shift towards today’s paradigm: black holes are essential parts of Nature. Indeed, by the 1980’s, black holes provided the best description of certain ‘exotic’ binary star systems as well as the engines powering jets from the cores of active galaxies. The LIGO detection of black-hole mergers, in 2015, was the crowning achievement of over a century of theoretical development, finally confirmed by observations of characteristic, extremely strong-field signatures of the black holes of GR.
The “frustrating details” emerge when black-hole physics is combined with quantum mechanics (QM). In 1975, Hawking showed that the correct description of the vacuum around an event horizon leads to the emission of Hawking Radiation as a form of vacuum polarization. Because this radiation originates from just above the horizon, the uniqueness of black holes in GR implies that Hawking radiation is universal, thermal and (almost) featureless. In particular, it is independent of how the black hole formed. Semi-classical back-reaction of this Hawking radiation also implies that the black hole will evaporate, albeit extremely slowly.
This leads to the Information Paradox: It is impossible to reconstruct the interior state of a black hole (apart from mass, charge and angular momentum) from the exterior data, and thus from the final state of the Hawking radiation. The evaporation process cannot, therefore, be represented through a unitary transformation of states in a Hilbert space. Hence black-hole evaporation, as predicted by GR and QM, is inconsistent with a foundational postulate of QM. Based on its horizon area, the black hole at the core of the Milky Way should have about e^(10^90) microstates. From the outside, black-hole uniqueness implies that its state is unique, as would be the state of its Hawking radiation were it to evaporate. The problem is therefore vast: e^(10^90) ? 1!
In 2009, Mathur used quantum information theory to show that Hawking’s information paradox could not be solved incrementally: It will require radical modification of the physics at the scale of the black hole horizon.
The only existing framework in which this can be done while including complete, general-relativistic, gravitational effects is the Microstate Geometry (MG) programme. This programme, which forms the core of this thesis research was started more than 15 years ago by the two supervisors, and has resulted in the construction of huge families of string theory and supergravity (that we call black hole Microstate Geometries) that have no singularity, no horizon, and exactly the same mass, charge, and angular momentum as a black hole.
This thesis has three directions. The first is to analyze the existing Microstate Geometries within the framework of the AdS-CFT correspondence. The second is to construct new Microstate Geometries for supersymmetric black holes. The third is to construct such geometries for non-supersymmetric black holes. The techniques that will be used in the first area are those of the holographic AdS-CFT correspondence, and mastering them will be useful if the student will want to explore other areas of holography. Research in the second direction will be done using supersymmetric solution-building methods of supergravity. These methods will also be useful if the student will want in the future to diversify his or her research interests towards string phenomenology or cosmology. The techniques to be used in the third area will be at first analytical (probe brane actions and factorized supergravity equations for constructing non-supersymmetric solutions), but depending on the preliminary results numerical methods to construct cohomegeneity-two supergravity solutions may also be used.
Applicants are expected to have a solid background in General Relativity and Quantum Field Theory. Knowledge of basic String Theory notions is a bonus.
Solving two-dimensional conformal field theories using the bootstrap approach
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Contact : |
Starting date : 01-10-2019
| Contact : |
|
| Thesis supervisor : |
|
Personal web page : Sylvain Ribault
More : https://www.ipht.fr
Two-dimensional conformal field theories have applications to
statistical mechanics, string theory and quantum gravity. Moreover, they
provide nontrivial examples of exactly solvable quantum field theories.
The bootstrap approach consists in computing correlation functions by
solving symmetry and consistency constraints. This can be done
numerically in CFTs in arbitrary dimensions, and this can also be done
analytically in some 2d CFTs such as minimal models or Liouville theory.
The aim of this PhD project is to solve two-dimensional CFTs, if
possible exactly. By solving we mean computing three- and four-point
correlation functions, and checking that four-point functions obey the
consistency constraint called crossing symmetry. Solving a CFT in this
sense not only establishes its existence, but also leads to a
quantitative understanding that is crucial for applications. In order to
exactly solve CFTs, we will rely on algebraic structures such as fusion
rules, and analytic properties of correlation functions, including their
decomposition into special functions called conformal blocks.
The CFTs we will focus on are known theories that have not yet been
fully solved, and new CFTs that we will strive to explore. The known
CFTs may include the SL(2,R) Wess-Zumino-Witten model, the critical
Ashkin-Teller model, or logarithmic minimal models. The new CFTs may be
constructed by taking limits of known CFTs, or starting with a symmetry
algebra and working out its fusion rules.
For a taste of the ideas and methods, see my "minimal lectures"
https://arxiv.org/abs/1609.09523
In order to apply, please send me a CV, cover letter and Master grade
transcripts no later than 16 April 2019. The plan is to apply for a
scholarship from ED PIF https://www.edpif.org/fr/edpif/ (deadline 30
April), unless you have access to other funding.
statistical mechanics, string theory and quantum gravity. Moreover, they
provide nontrivial examples of exactly solvable quantum field theories.
The bootstrap approach consists in computing correlation functions by
solving symmetry and consistency constraints. This can be done
numerically in CFTs in arbitrary dimensions, and this can also be done
analytically in some 2d CFTs such as minimal models or Liouville theory.
The aim of this PhD project is to solve two-dimensional CFTs, if
possible exactly. By solving we mean computing three- and four-point
correlation functions, and checking that four-point functions obey the
consistency constraint called crossing symmetry. Solving a CFT in this
sense not only establishes its existence, but also leads to a
quantitative understanding that is crucial for applications. In order to
exactly solve CFTs, we will rely on algebraic structures such as fusion
rules, and analytic properties of correlation functions, including their
decomposition into special functions called conformal blocks.
The CFTs we will focus on are known theories that have not yet been
fully solved, and new CFTs that we will strive to explore. The known
CFTs may include the SL(2,R) Wess-Zumino-Witten model, the critical
Ashkin-Teller model, or logarithmic minimal models. The new CFTs may be
constructed by taking limits of known CFTs, or starting with a symmetry
algebra and working out its fusion rules.
For a taste of the ideas and methods, see my "minimal lectures"
https://arxiv.org/abs/1609.09523
In order to apply, please send me a CV, cover letter and Master grade
transcripts no later than 16 April 2019. The plan is to apply for a
scholarship from ED PIF https://www.edpif.org/fr/edpif/ (deadline 30
April), unless you have access to other funding.
Modelling of urban systems
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Contact : |
Starting date : 01-10-2019
| Contact : |
|
| Thesis supervisor : |
|
See french abstract
M-theory quantum corrections, fluxes and compactifications to four dimensions
|
Contact : |
Starting date : 01-10-2019
| Contact : |
|
| Thesis supervisor : |
|
More : https://www.ipht.fr
The focus of this project is on four-dimensional compactifications of eleven-dimensional M-theory on seven manifolds with fluxes.
In the relatively better studied case of purely gravitational backgrounds, the internal seven-manifold should be of G2 holonomy. This is a very interesting class of geometries that saw much recent interest. Notably there has been a huge progress in construction of explicit examples. However there are many unexplored questions concerning four-dimensional theories (and their quantum properties) that arise as a result of compactification of M-theory on these manifolds.
The situation becomes much more complicated when the four-form flux of M-theory is turned on. While it is known how to turn on the internal flux while preserving supersymmetry, the global constraints seem to rule out compact internal manifolds. To this day there is no known mechanism of tadpole cancellation. The quantum corrections of M-theory and the so-far unexplored possibility of higher-derivative corrections to the M-theoretic Bianchi identities present the best hope of avoiding the no-go theorems to four-dimensional compactifications. Better understanding of the M-theoretic quantum corrections and their possible geometric interpretation is an important open problem on its own. Recently generalised-geometric tools have been developed that may facilitate the analysis systematically.
In addition to addressing some purely sting/M-theoretic and geometric questions, the project should hopefully lead to progress in analysing an important and largely unexplored class of four-dimensional theories with low or no supersymmetry. In particular, the effects of the quantum corrections on the possible four-dimensional M-theoretic vacua will be studied and the possibility of construction of de Sitter vacua in M-theory will be explored.
The project will require the candidate to master string dualities and a large set of geometric and string theoretic computational techniques.
In the relatively better studied case of purely gravitational backgrounds, the internal seven-manifold should be of G2 holonomy. This is a very interesting class of geometries that saw much recent interest. Notably there has been a huge progress in construction of explicit examples. However there are many unexplored questions concerning four-dimensional theories (and their quantum properties) that arise as a result of compactification of M-theory on these manifolds.
The situation becomes much more complicated when the four-form flux of M-theory is turned on. While it is known how to turn on the internal flux while preserving supersymmetry, the global constraints seem to rule out compact internal manifolds. To this day there is no known mechanism of tadpole cancellation. The quantum corrections of M-theory and the so-far unexplored possibility of higher-derivative corrections to the M-theoretic Bianchi identities present the best hope of avoiding the no-go theorems to four-dimensional compactifications. Better understanding of the M-theoretic quantum corrections and their possible geometric interpretation is an important open problem on its own. Recently generalised-geometric tools have been developed that may facilitate the analysis systematically.
In addition to addressing some purely sting/M-theoretic and geometric questions, the project should hopefully lead to progress in analysing an important and largely unexplored class of four-dimensional theories with low or no supersymmetry. In particular, the effects of the quantum corrections on the possible four-dimensional M-theoretic vacua will be studied and the possibility of construction of de Sitter vacua in M-theory will be explored.
The project will require the candidate to master string dualities and a large set of geometric and string theoretic computational techniques.
de Sitter vacua and non-susy black-hole microstates in string theory
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Contact : |
Starting date : 01-10-2019
| Contact : |
|
| Thesis supervisor : |
|
