PhD subjects
| 4 sujets IPhT |
Dernière mise à jour : 07-07-2020
PN junction and quantum Hall effect
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Contact : |
Starting date : 01-10-2020
| Contact : |
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| Thesis supervisor : |
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Laboratory link : https://www.ipht.fr
The Higgs Boson Mass and Cosmology
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Contact : |
Starting date : 01-10-2020
| Contact : |
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| Thesis supervisor : |
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Context: In our current description of Nature there are two parameters that have the strongest impact on the
phenomenology of the Universe. At the same time they are the most sensitive to the details of the underlying
theory at high energies. These parameters are the cosmological constant and the Higgs boson mass. The
cosmological constant ultimately determines the size of the observable Universe. It was measured about two
decades ago by studying the luminosity of high-redshift supernovae [1, 2]. The Higgs boson mass determines
the vacuum expectation value of the Higgs field which enters the mass of most known particles and determines
the scale of weak interactions. The stability of nuclei, and thus complex chemistry and ultimately life as we
know it, are strongly tied to this parameter. The Higgs boson was discovered, and its mass measured, by the
ATLAS and CMS experiments at the Large Hadron Collider (LHC) [3,4]. Theoretically it is hard to understand
the measured values of the Higgs mass and of the cosmological constant. The difficulty has the same origin for
both parameters and can be traced to quantum corrections and the symmetries of fundamental interactions. As a
consequence the values of these parameters are still unexplained. In this proposal we study a class of ideas that
tie the Higgs boson mass to the evolution of the Universe. This makes the values of the cosmological constant
and of the Higgs mass deeply interconnected and points to the sky as the ultimate laboratory to understand their
origin.
Thesis Project: We develop a class of ideas that ties the origin of the weak scale to the evolution of the
Universe at early times and explore their connections to the cosmological constant. This has experimental
consequences for CMB-Stage4 experiments [5, 6], fifth-force searches [7–14], equivalence principle violation
tests [15–17] and high-luminosity lepton colliders [18, 19]. I will consider models where the Higgs mass
changes via a scalar field that is slowly rolling during inflation and stops at the observed value [20, 21] (Higgs
mass “relaxation”) and models where the Higgs mass is dynamically selected at reheating [22].
Project (1a): Experimental Impact of the Cosmological Origin of the Higgs Mass. The first step of the
project is to work out in detail the experimental implications of existing cosmological explanations of the Higgs
mass. In the case of the reheating solution in [22], explaining the Higgs mass requires introducing dark sectors
with the same particle content as the SM and a new particle that reheats them. We will consider the implications
of fixing neutrinos, electrons or protons in the new sectors to be dark matter and work out the signatures in the
CMB and in small scale structure [23]. We will also study the induced exotic Higgs and Z decays at lepton
colliders and new particles at high-intensity beam-dump experiments. In the case of dynamical effects during
inflation (including the class of ideas in [20, 21, 24]), the most interesting research direction is the study of the
imprint on the CMB of the very unique models of inflation needed to make the mechanisms work.
Project (1b): Model Building Challenges in Cosmological Explanations. The first half of this project
can be enough for a PhD thesis. If the student completes the work ahead of time, there is a second direction of
investigation worth pursuing.
In this second part of the project we try to turn the proof-of-concept ideas in the first papers into more
appealing, complete theoretical models. In the case of [22] one objective is to find dynamical constructions that
require fewer copies of the SM for a fixed fundamental scale in the theory. A second objective is to improve the
reheating mechanism, decoupling the mass of the particle responsible for reheating the Universe from the weak
scale. This requires employing pre-heating and parametric resonance. In the case of [20, 21] and related ideas,
the key open question is what is the model building price to pay to write a complete model that includes an
explanation for their tiny dimensionful couplings and at the same time an inflationary sector that successfully
reheats the SM. In some sense one can reformulate the question by saying that while these models make the
weak scale technically natural they still do not explain its origin. At the end of this effort we will have more
solid models or have conclusively disfavored this class of theories.
References
[1] Supernova Search Team Collaboration, A. G. Riess et al., “Observational evidence from supernovae
for an accelerating universe and a cosmological constant,” Astron. J. 116 (1998) 1009–1038,
arXiv:astro-ph/9805201 [astro-ph].
[2] Supernova Cosmology Project Collaboration, S. Perlmutter et al., “Measurements of O and ? from 42
high redshift supernovae,” Astrophys. J. 517 (1999) 565–586, arXiv:astro-ph/9812133
[astro-ph].
[3] ATLAS Collaboration, G. Aad et al., “Observation of a new particle in the search for the Standard
Model Higgs boson with the ATLAS detector at the LHC,” Phys. Lett. B716 (2012) 1–29,
arXiv:1207.7214 [hep-ex].
[4] CMS Collaboration, S. Chatrchyan et al., “Observation of a New Boson at a Mass of 125 GeV with the
CMS Experiment at the LHC,” Phys. Lett. B716 (2012) 30–61, arXiv:1207.7235 [hep-ex].
[5] CMB-S4 Collaboration, K. N. Abazajian et al., “CMB-S4 Science Book, First Edition,”
arXiv:1610.02743 [astro-ph.CO].
[6] K. Abazajian et al., “CMB-S4 Science Case, Reference Design, and Project Plan,” arXiv:1907.04473
[astro-ph.IM].
[7] R. Spero, J. K. Hoskins, R. Newman, J. Pellam, and J. Schultz, “Test of the Gravitational Inverse-Square
Law at Laboratory Distances,” Phys. Rev. Lett. 44 (1980) 1645–1648.
[8] J. K. Hoskins, R. D. Newman, R. Spero, and J. Schultz, “Experimental tests of the gravitational inverse
square law for mass separations from 2-cm to 105-cm,” Phys. Rev. D32 (1985) 3084–3095.
[9] J. Chiaverini, S. J. Smullin, A. A. Geraci, D. M. Weld, and A. Kapitulnik, “New experimental constraints
on nonNewtonian forces below 100 microns,” Phys. Rev. Lett. 90 (2003) 151101,
arXiv:hep-ph/0209325 [hep-ph].
[10] C. D. Hoyle, D. J. Kapner, B. R. Heckel, E. G. Adelberger, J. H. Gundlach, U. Schmidt, and H. E.
Swanson, “Sub-millimeter tests of the gravitational inverse-square law,” Phys. Rev. D70 (2004) 042004,
arXiv:hep-ph/0405262 [hep-ph].
[11] S. J. Smullin, A. A. Geraci, D. M. Weld, J. Chiaverini, S. P. Holmes, and A. Kapitulnik, “New
constraints on Yukawa-type deviations from Newtonian gravity at 20 microns,” Phys. Rev. D72 (2005)
122001, arXiv:hep-ph/0508204 [hep-ph]. [Erratum: Phys. Rev.D72,129901(2005)].
[12] D. J. Kapner, T. S. Cook, E. G. Adelberger, J. H. Gundlach, B. R. Heckel, C. D. Hoyle, and H. E.
Swanson, “Tests of the gravitational inverse-square law below the dark-energy length scale,” Phys. Rev.
Lett. 98 (2007) 021101, arXiv:hep-ph/0611184 [hep-ph].
[13] M. Bordag, U. Mohideen, and V. M. Mostepanenko, “New developments in the Casimir effect,” Phys.
Rept. 353 (2001) 1–205, arXiv:quant-ph/0106045 [quant-ph].
[14] M. Bordag, G. L. Klimchitskaya, U. Mohideen, and V. M. Mostepanenko, “Advances in the Casimir
effect,” Int. Ser. Monogr. Phys. 145 (2009) 1–768.
[15] G. L. Smith, C. D. Hoyle, J. H. Gundlach, E. G. Adelberger, B. R. Heckel, and H. E. Swanson, “Short
range tests of the equivalence principle,” Phys. Rev. D61 (2000) 022001.
[16] S. Schlamminger, K. Y. Choi, T. A. Wagner, J. H. Gundlach, and E. G. Adelberger, “Test of the
equivalence principle using a rotating torsion balance,” Phys. Rev. Lett. 100 (2008) 041101,
arXiv:0712.0607 [gr-qc].
[17] J. Bergé, P. Brax, G. Métris, M. Pernot-Borràs, P. Touboul, and J.-P. Uzan, “MICROSCOPE Mission:
First Constraints on the Violation of the Weak Equivalence Principle by a Light Scalar Dilaton,” Phys.
Rev. Lett. 120 (2018) no. 14, 141101, arXiv:1712.00483 [gr-qc].
[18] FCC Collaboration, A. Abada et al., “FCC-ee: The Lepton Collider,” Eur. Phys. J. ST 228 (2019) no. 2,
261–623.
[19] CEPC Study Group Collaboration, M. Dong et al., “CEPC Conceptual Design Report: Volume 2 -
Physics & Detector,” arXiv:1811.10545 [hep-ex].
[20] P. W. Graham, D. E. Kaplan, and S. Rajendran, “Cosmological Relaxation of the Electroweak Scale,”
Phys. Rev. Lett. 115 (2015) no. 22, 221801, arXiv:1504.07551 [hep-ph].
[21] M. Geller, Y. Hochberg, and E. Kuflik, “Inflating to the Weak Scale,” Phys. Rev. Lett. 122 (2019) no. 19,
191802, arXiv:1809.07338 [hep-ph].
[22] N. Arkani-Hamed, R. T. D’Agnolo, M. Low, and D. Pinner, “Unification and New Particles at the LHC,”
JHEP 11 (2016) 082, arXiv:1608.01675 [hep-ph].
[23] GAIA Collaboration, “The Gaia mission,” 595 (Nov, 2016) A1, arXiv:1609.04153 [astro-ph.IM].
[24] G. F. Giudice, A. Kehagias, and A. Riotto, “The Selfish Higgs,” arXiv:1907.05370 [hep-ph].
phenomenology of the Universe. At the same time they are the most sensitive to the details of the underlying
theory at high energies. These parameters are the cosmological constant and the Higgs boson mass. The
cosmological constant ultimately determines the size of the observable Universe. It was measured about two
decades ago by studying the luminosity of high-redshift supernovae [1, 2]. The Higgs boson mass determines
the vacuum expectation value of the Higgs field which enters the mass of most known particles and determines
the scale of weak interactions. The stability of nuclei, and thus complex chemistry and ultimately life as we
know it, are strongly tied to this parameter. The Higgs boson was discovered, and its mass measured, by the
ATLAS and CMS experiments at the Large Hadron Collider (LHC) [3,4]. Theoretically it is hard to understand
the measured values of the Higgs mass and of the cosmological constant. The difficulty has the same origin for
both parameters and can be traced to quantum corrections and the symmetries of fundamental interactions. As a
consequence the values of these parameters are still unexplained. In this proposal we study a class of ideas that
tie the Higgs boson mass to the evolution of the Universe. This makes the values of the cosmological constant
and of the Higgs mass deeply interconnected and points to the sky as the ultimate laboratory to understand their
origin.
Thesis Project: We develop a class of ideas that ties the origin of the weak scale to the evolution of the
Universe at early times and explore their connections to the cosmological constant. This has experimental
consequences for CMB-Stage4 experiments [5, 6], fifth-force searches [7–14], equivalence principle violation
tests [15–17] and high-luminosity lepton colliders [18, 19]. I will consider models where the Higgs mass
changes via a scalar field that is slowly rolling during inflation and stops at the observed value [20, 21] (Higgs
mass “relaxation”) and models where the Higgs mass is dynamically selected at reheating [22].
Project (1a): Experimental Impact of the Cosmological Origin of the Higgs Mass. The first step of the
project is to work out in detail the experimental implications of existing cosmological explanations of the Higgs
mass. In the case of the reheating solution in [22], explaining the Higgs mass requires introducing dark sectors
with the same particle content as the SM and a new particle that reheats them. We will consider the implications
of fixing neutrinos, electrons or protons in the new sectors to be dark matter and work out the signatures in the
CMB and in small scale structure [23]. We will also study the induced exotic Higgs and Z decays at lepton
colliders and new particles at high-intensity beam-dump experiments. In the case of dynamical effects during
inflation (including the class of ideas in [20, 21, 24]), the most interesting research direction is the study of the
imprint on the CMB of the very unique models of inflation needed to make the mechanisms work.
Project (1b): Model Building Challenges in Cosmological Explanations. The first half of this project
can be enough for a PhD thesis. If the student completes the work ahead of time, there is a second direction of
investigation worth pursuing.
In this second part of the project we try to turn the proof-of-concept ideas in the first papers into more
appealing, complete theoretical models. In the case of [22] one objective is to find dynamical constructions that
require fewer copies of the SM for a fixed fundamental scale in the theory. A second objective is to improve the
reheating mechanism, decoupling the mass of the particle responsible for reheating the Universe from the weak
scale. This requires employing pre-heating and parametric resonance. In the case of [20, 21] and related ideas,
the key open question is what is the model building price to pay to write a complete model that includes an
explanation for their tiny dimensionful couplings and at the same time an inflationary sector that successfully
reheats the SM. In some sense one can reformulate the question by saying that while these models make the
weak scale technically natural they still do not explain its origin. At the end of this effort we will have more
solid models or have conclusively disfavored this class of theories.
References
[1] Supernova Search Team Collaboration, A. G. Riess et al., “Observational evidence from supernovae
for an accelerating universe and a cosmological constant,” Astron. J. 116 (1998) 1009–1038,
arXiv:astro-ph/9805201 [astro-ph].
[2] Supernova Cosmology Project Collaboration, S. Perlmutter et al., “Measurements of O and ? from 42
high redshift supernovae,” Astrophys. J. 517 (1999) 565–586, arXiv:astro-ph/9812133
[astro-ph].
[3] ATLAS Collaboration, G. Aad et al., “Observation of a new particle in the search for the Standard
Model Higgs boson with the ATLAS detector at the LHC,” Phys. Lett. B716 (2012) 1–29,
arXiv:1207.7214 [hep-ex].
[4] CMS Collaboration, S. Chatrchyan et al., “Observation of a New Boson at a Mass of 125 GeV with the
CMS Experiment at the LHC,” Phys. Lett. B716 (2012) 30–61, arXiv:1207.7235 [hep-ex].
[5] CMB-S4 Collaboration, K. N. Abazajian et al., “CMB-S4 Science Book, First Edition,”
arXiv:1610.02743 [astro-ph.CO].
[6] K. Abazajian et al., “CMB-S4 Science Case, Reference Design, and Project Plan,” arXiv:1907.04473
[astro-ph.IM].
[7] R. Spero, J. K. Hoskins, R. Newman, J. Pellam, and J. Schultz, “Test of the Gravitational Inverse-Square
Law at Laboratory Distances,” Phys. Rev. Lett. 44 (1980) 1645–1648.
[8] J. K. Hoskins, R. D. Newman, R. Spero, and J. Schultz, “Experimental tests of the gravitational inverse
square law for mass separations from 2-cm to 105-cm,” Phys. Rev. D32 (1985) 3084–3095.
[9] J. Chiaverini, S. J. Smullin, A. A. Geraci, D. M. Weld, and A. Kapitulnik, “New experimental constraints
on nonNewtonian forces below 100 microns,” Phys. Rev. Lett. 90 (2003) 151101,
arXiv:hep-ph/0209325 [hep-ph].
[10] C. D. Hoyle, D. J. Kapner, B. R. Heckel, E. G. Adelberger, J. H. Gundlach, U. Schmidt, and H. E.
Swanson, “Sub-millimeter tests of the gravitational inverse-square law,” Phys. Rev. D70 (2004) 042004,
arXiv:hep-ph/0405262 [hep-ph].
[11] S. J. Smullin, A. A. Geraci, D. M. Weld, J. Chiaverini, S. P. Holmes, and A. Kapitulnik, “New
constraints on Yukawa-type deviations from Newtonian gravity at 20 microns,” Phys. Rev. D72 (2005)
122001, arXiv:hep-ph/0508204 [hep-ph]. [Erratum: Phys. Rev.D72,129901(2005)].
[12] D. J. Kapner, T. S. Cook, E. G. Adelberger, J. H. Gundlach, B. R. Heckel, C. D. Hoyle, and H. E.
Swanson, “Tests of the gravitational inverse-square law below the dark-energy length scale,” Phys. Rev.
Lett. 98 (2007) 021101, arXiv:hep-ph/0611184 [hep-ph].
[13] M. Bordag, U. Mohideen, and V. M. Mostepanenko, “New developments in the Casimir effect,” Phys.
Rept. 353 (2001) 1–205, arXiv:quant-ph/0106045 [quant-ph].
[14] M. Bordag, G. L. Klimchitskaya, U. Mohideen, and V. M. Mostepanenko, “Advances in the Casimir
effect,” Int. Ser. Monogr. Phys. 145 (2009) 1–768.
[15] G. L. Smith, C. D. Hoyle, J. H. Gundlach, E. G. Adelberger, B. R. Heckel, and H. E. Swanson, “Short
range tests of the equivalence principle,” Phys. Rev. D61 (2000) 022001.
[16] S. Schlamminger, K. Y. Choi, T. A. Wagner, J. H. Gundlach, and E. G. Adelberger, “Test of the
equivalence principle using a rotating torsion balance,” Phys. Rev. Lett. 100 (2008) 041101,
arXiv:0712.0607 [gr-qc].
[17] J. Bergé, P. Brax, G. Métris, M. Pernot-Borràs, P. Touboul, and J.-P. Uzan, “MICROSCOPE Mission:
First Constraints on the Violation of the Weak Equivalence Principle by a Light Scalar Dilaton,” Phys.
Rev. Lett. 120 (2018) no. 14, 141101, arXiv:1712.00483 [gr-qc].
[18] FCC Collaboration, A. Abada et al., “FCC-ee: The Lepton Collider,” Eur. Phys. J. ST 228 (2019) no. 2,
261–623.
[19] CEPC Study Group Collaboration, M. Dong et al., “CEPC Conceptual Design Report: Volume 2 -
Physics & Detector,” arXiv:1811.10545 [hep-ex].
[20] P. W. Graham, D. E. Kaplan, and S. Rajendran, “Cosmological Relaxation of the Electroweak Scale,”
Phys. Rev. Lett. 115 (2015) no. 22, 221801, arXiv:1504.07551 [hep-ph].
[21] M. Geller, Y. Hochberg, and E. Kuflik, “Inflating to the Weak Scale,” Phys. Rev. Lett. 122 (2019) no. 19,
191802, arXiv:1809.07338 [hep-ph].
[22] N. Arkani-Hamed, R. T. D’Agnolo, M. Low, and D. Pinner, “Unification and New Particles at the LHC,”
JHEP 11 (2016) 082, arXiv:1608.01675 [hep-ph].
[23] GAIA Collaboration, “The Gaia mission,” 595 (Nov, 2016) A1, arXiv:1609.04153 [astro-ph.IM].
[24] G. F. Giudice, A. Kehagias, and A. Riotto, “The Selfish Higgs,” arXiv:1907.05370 [hep-ph].
Scalar field scenarios for dark matter
|
Contact : |
Starting date : 01-10-2020
| Contact : |
|
| Thesis supervisor : |
|
Laboratory link : https://www.ipht.fr
Machine Learning for Fundamental Physics
|
Contact : |
Starting date : 01-10-2020
| Contact : |
|
| Thesis supervisor : |
|
Laboratory link : https://www.ipht.fr
Context: Today, as a result of an outstanding experimental program, particle physics and cosmology are
flooded with data. This offers us the unique opportunity to answer questions that have been the object of
speculation for more than fifty years. In particular, particle colliders and Cosmic Microwave Background
(CMB) surveys have collected a wealth of high-quality data in the past decades and may continue to do so for
decades to come. Analyzing these datasets effectively is key to make progress in fundamental physics.
In particle physics, as more and more data are collected, the problems that confront us become sharper
and harder to solve. We know that the theories that well describe current data are incomplete and should be
extended, but our prior beliefs on how the extension should look like and on where to discover it experimentally
become less concordant every day. This calls for a model-independent approach to data analysis.
In cosmology, well established measurements, such as the rate of expansion of the Universe from the CMB
radiation, are being challenged by new observations. Reconciling these different observations or understanding
if they signal the presence of new physical phenomena, can only be done by interrogating the data in novel
ways. Mining these large, multivariate datasets for signs of new phenomena, presents many of the challenges
that machine learning and deep learning are overcoming in a variety of other domains. In this project we
leverage the unprecedented growth of these fields to shed light on the open questions of fundamental physics.
Thesis Project: We consider the problem of having large multivariate datasets that are seemingly well de-
scribed by a reference model. Departures from the reference model can be statistically significant, but are
caused only by a very small fraction of events. The significance might stem from the extreme rarity of the
discrepant events in the reference model and in this case anomaly detection techniques might be employed.
Or the discrepancy is due to a small excess (or even a deficit) of events in a region of the space of physical
observables that is also populated in the reference model. Our goal is to determine if the experimental dataset
does follow the reference model exactly or if it instead contains “smal” departures as described above. In the
latter case, we also want to know in which region of the space of observables the discrepancy is localized. This
problem is relevant to Large Hadron Collider (LHC) datasets that are well described by the Standard Model of
particle physics (SM) and CMB datasets that are well described by the standard cosmological model ?CDM.
I have already developed a new machine learning technique [1] that allows to analyze large datasets in
a model-independent way, detecting data departures from a given reference model with no prior bias on the
nature of the new physics responsible for the discrepancy. There are a number of potential applications in
particle physics, astrophysics and cosmology. We are already taking the relevant steps in collaboration with
CMS experimentalists to use this technique on LHC data. The next step is to apply this technique to CMB
datasets in order to detect deviations from ?CDM (which can contribute to shed light on the current tension
between different measurements of the Hubble parameter). The application of this technique to CMB data will
be the main focus of the project.
In parallel we will refine [1] and look for the optimal model-independent new physics detection strategy.
This problem can be reduced to finding the minimum of a suitable loss function. Furthermore, the loss function
first developed in [1] can be used to obtain better performances in traditional classification problems, with a
variety of possible applications to fundamental physics (such as for example the separation between quark and
gluon jets). There are many other directions that are worth exploring such as embedding [1] in a Generative
Adversarial Network and using Autoencoders to compute a p-value rather than just signaling the presence of
anomalous events. Depending on the progress of the student during his thesis project we will explore all these
directions or only a subset, with the priorities outlined above: 1) CMB data mining 2) Optimal search strategy
3) Applications in classification 4) Variations on Autoencoders.
[1] R. T. D’Agnolo and A. Wulzer, Learning New Physics from a Machine, Phys. Rev. D 99, no. 1, 015014
(2019) doi:10.1103/PhysRevD.99.015014 [arXiv:1806.02350 [hep-ph]].
flooded with data. This offers us the unique opportunity to answer questions that have been the object of
speculation for more than fifty years. In particular, particle colliders and Cosmic Microwave Background
(CMB) surveys have collected a wealth of high-quality data in the past decades and may continue to do so for
decades to come. Analyzing these datasets effectively is key to make progress in fundamental physics.
In particle physics, as more and more data are collected, the problems that confront us become sharper
and harder to solve. We know that the theories that well describe current data are incomplete and should be
extended, but our prior beliefs on how the extension should look like and on where to discover it experimentally
become less concordant every day. This calls for a model-independent approach to data analysis.
In cosmology, well established measurements, such as the rate of expansion of the Universe from the CMB
radiation, are being challenged by new observations. Reconciling these different observations or understanding
if they signal the presence of new physical phenomena, can only be done by interrogating the data in novel
ways. Mining these large, multivariate datasets for signs of new phenomena, presents many of the challenges
that machine learning and deep learning are overcoming in a variety of other domains. In this project we
leverage the unprecedented growth of these fields to shed light on the open questions of fundamental physics.
Thesis Project: We consider the problem of having large multivariate datasets that are seemingly well de-
scribed by a reference model. Departures from the reference model can be statistically significant, but are
caused only by a very small fraction of events. The significance might stem from the extreme rarity of the
discrepant events in the reference model and in this case anomaly detection techniques might be employed.
Or the discrepancy is due to a small excess (or even a deficit) of events in a region of the space of physical
observables that is also populated in the reference model. Our goal is to determine if the experimental dataset
does follow the reference model exactly or if it instead contains “smal” departures as described above. In the
latter case, we also want to know in which region of the space of observables the discrepancy is localized. This
problem is relevant to Large Hadron Collider (LHC) datasets that are well described by the Standard Model of
particle physics (SM) and CMB datasets that are well described by the standard cosmological model ?CDM.
I have already developed a new machine learning technique [1] that allows to analyze large datasets in
a model-independent way, detecting data departures from a given reference model with no prior bias on the
nature of the new physics responsible for the discrepancy. There are a number of potential applications in
particle physics, astrophysics and cosmology. We are already taking the relevant steps in collaboration with
CMS experimentalists to use this technique on LHC data. The next step is to apply this technique to CMB
datasets in order to detect deviations from ?CDM (which can contribute to shed light on the current tension
between different measurements of the Hubble parameter). The application of this technique to CMB data will
be the main focus of the project.
In parallel we will refine [1] and look for the optimal model-independent new physics detection strategy.
This problem can be reduced to finding the minimum of a suitable loss function. Furthermore, the loss function
first developed in [1] can be used to obtain better performances in traditional classification problems, with a
variety of possible applications to fundamental physics (such as for example the separation between quark and
gluon jets). There are many other directions that are worth exploring such as embedding [1] in a Generative
Adversarial Network and using Autoencoders to compute a p-value rather than just signaling the presence of
anomalous events. Depending on the progress of the student during his thesis project we will explore all these
directions or only a subset, with the priorities outlined above: 1) CMB data mining 2) Optimal search strategy
3) Applications in classification 4) Variations on Autoencoders.
[1] R. T. D’Agnolo and A. Wulzer, Learning New Physics from a Machine, Phys. Rev. D 99, no. 1, 015014
(2019) doi:10.1103/PhysRevD.99.015014 [arXiv:1806.02350 [hep-ph]].
