Your search keyword '"Partouche, Hervé"' showing total 203 results

1. Closed FRW holography: A time-dependent ER=EPR realization

Author

Franken, Victor, Partouche, Hervé, Rondeau, François, and Toumbas, Nicolaos

Subjects

High Energy Physics - Theory, General Relativity and Quantum Cosmology

Abstract

We extend a recent de Sitter holographic proposal and entanglement entropy prescription to generic closed FRW cosmologies in arbitrary dimensions, and propose that for large classes of bouncing and Big Bang/Big Crunch cosmologies, the full spacetime can be encoded holographically on two holographic screens, associated to two antipodal observers. In the expanding phase, the two screens lie at the apparent horizons. In the contracting phase, there is an infinite number of possible trajectories of the holographic screens, which can be grouped in equivalence classes. In each class the effective holographic theory can be derived from a pair of ``parent'' screens on the apparent horizons. A number of cases including moduli dominated cosmologies escape our discussion, and it is expected that two antipodal observers and their associated screens do not suffice to reconstruct these cosmologies. The leading contributions to the entanglement entropy between the screens arise from a minimal extremal trapped or anti-trapped surface lying in the region between them. This picture entails a time-dependent realization of the ER=EPR conjecture, where an effective geometrical bridge connecting the screens via the minimal extremal surface emerges from entanglement. For the Big Crunch contracting cases, the screens disentangle and the geometrical bridge closes off when the minimal extremal trapped sphere hits the Big Crunch singularity at a finite time before the collapse of the Universe. Semiclassical, thermal corrections are incorporated in the cases of radiation dominated cosmologies., Comment: 60 pages + 3 appendices, 20 figures. Published version

Published

2023

2. Bridging the static patches: de Sitter holography and entanglement

Author

Franken, Victor, Partouche, Hervé, Rondeau, François, and Toumbas, Nicolaos

Subjects

High Energy Physics - Theory, General Relativity and Quantum Cosmology

Abstract

In the context of de Sitter static-patch holography, two prescriptions have been put forward for holographic entanglement entropy computations, the monolayer and bilayer proposals. In this paper, we reformulate both prescriptions in a covariant way and extend them to include quantum corrections. We argue that the bilayer proposal is self-consistent, while the monolayer proposal exhibits contradictory behavior. In fact, the bilayer proposal leads to a stronger holographic description, in which the full spacetime is encoded on two screens at the cosmological horizons. At the classical level, we find large degeneracies of minimal extremal homologous surfaces, localized at the horizons, which can be lifted by quantum corrections. The entanglement wedges of subregions of the screens exhibit non-trivial behaviors, hinting at the existence of interesting phase transitions and non-locality in the holographic theory. In particular, while each screen encodes its corresponding static patch, we show that the entanglement wedge of the screen with the larger quantum area extends and covers the causal diamond between the screens, with a phase transition occurring when the quantum areas of the screens become equal. We argue that the capacity of the screens to encode the region between them is lost, when these are pushed further in the static patches of the observers and placed on stretched horizons., Comment: 83 pages, 11 figures. Published version

Published

2023

3. A unimodular-like string effective description

Author

Kehagias, Alex, Partouche, Hervé, and Toumbas, Nicolaos

Subjects

High Energy Physics - Theory, General Relativity and Quantum Cosmology

Abstract

We show that vanishing of the sigma-model beta-functions for the metric $g_{\mu\nu}$, antisymmetric tensor $B_{\mu\nu}$ and dilaton $\Phi$ of any string-theory model in $D$ dimensions at tree level can be obtained from a universal effective action, provided that the field combination $\sqrt{-g}e^{-2\Phi}$ is non-dynamical. The central-charge deficit term is omitted from the action and appears as an integration constant at the level of the field equations. The analysis is done at leading order in $\alpha'$, i.e. at the two-derivative level in the effective description. It can be extended to incorporate higher order string-loop corrections, Ramond-Ramond forms and moduli fields. In all cases, the non-dynamical field combination turns out to be $\sqrt{-g}\, U$, where $U$ is the effective potential. When certain fluxes are fixed and the moduli fields are stabilized, no cosmological term will arise in the action. Instead, the cosmological constant will appear as an integration constant as in unimodular modifications of general relativity., Comment: 1+23 pages

Published

2022

4. Closed FRW holography: a time-dependent ER=EPR realization

Author

Franken, Victor, Partouche, Hervé, Rondeau, François, and Toumbas, Nicolaos

Published

2024

5. Probability distribution for the quantum universe

Author

Kehagias, Alex, Partouche, Hervé, and Toumbas, Nicolaos

Subjects

High Energy Physics - Theory, General Relativity and Quantum Cosmology

Abstract

We determine the inner product on the Hilbert space of wavefunctions of the universe by imposing the Hermiticity of the quantum Hamiltonian in the context of the minisuperspace model. The corresponding quantum probability density reproduces successfully the classical probability distribution in the $\hbar \to 0$ limit, for closed universes filled with a perfect fluid of index $w$. When $-1/3

Published

2021

6. Geometry of orientifold vacua and supersymmetry breaking

Author

Coudarchet, Thibaut, Dudas, Emilian, and Partouche, Hervé

Subjects

High Energy Physics - Theory

Abstract

Starting from a peculiar orientifold projection proposed long ago by Angelantonj and Cardella, we elaborate on a novel perturbative scenario that involves only D-branes, together with the two types of orientifold planes ${\rm O}_{\pm}$ and anti-orientifold planes $\overline{{\rm O}}_{\pm}$. We elucidate the microscopic ingredients of such models, connecting them to a novel realization of brane supersymmetry breaking. Depending on the position of the D-branes in the internal space, supersymmetry can be broken at the string scale on branes, or alternatively only at the massive level. The main novelty of this construction is that it features no NS-NS disk tadpoles, while avoiding open-string instabilities. The one-loop potential, which depends on the positions of the D-branes, is minimized for maximally broken, nonlinearly realized supersymmetry. The orientifold projection and the effective field theory description reveal a soft breaking of supersymmetry in the closed-string sector. In such models it is possible to decouple the gravitino mass from the value of the scalar potential, while avoiding brane instabilities., Comment: 1+37 pages, 2 figures. References added

Published

2021

7. Gauge fixing and field redefinitions of the Hartle--Hawking wavefunction path integral

Author

Partouche, Hervé, Toumbas, Nicolaos, and de Vaulchier, Balthazar

Subjects

High Energy Physics - Theory, General Relativity and Quantum Cosmology

Abstract

We review some recent results concerning the Hartle--Hawking wavefunction of the universe. We focus on pure Einstein theory of gravity in the presence of a positive cosmological constant. We carefully implement the gauge-fixing procedure for the minisuperspace path integral, by identifying the single modulus and by using diffeomorphism-invariant measures for the ghosts and the scale factor. Field redefinitions of the scale factor yield different prescriptions for computing the no-boundary ground-state wavefunction. They give rise to an infinite set of ground-state wavefunctions, each satisfying a different Wheeler--DeWitt equation, at the semi-classical level. The differences in the form of the Wheeler--DeWitt equations can be traced to ordering ambiguities in constructing the Hamiltonian upon canonical quantization. However, the inner products of the corresponding Hilbert spaces turn out to be equivalent, at least semi-classically. Thus, the model yields universal quantum predictions.

Published

2021

8. Wavefunction of the universe: Reparametrization invariance and field redefinitions of the minisuperspace path integral

Author

Partouche, Hervé, Toumbas, Nicolaos, and de Vaulchier, Balthazar

Subjects

High Energy Physics - Theory, General Relativity and Quantum Cosmology

Abstract

We consider the Hartle-Hawking wavefunction of the universe defined as a Euclidean path integral that satisfies the "no-boundary proposal." We focus on the simplest minisuperspace model that comprises a single scale factor degree of freedom and a positive cosmological constant. The model can be seen as a non-linear $\sigma$-model with a line-segment base. We reduce the path integral over the lapse function to an integral over the proper length of the base and use diffeomorphism-invariant measures for the ghosts and the scale factor. As a result, the gauge-fixed path integral is independent of the gauge. However, we point out that all field redefinitions of the scale factor degree of freedom yield different choices of gauge-invariant path-integral measures. For each prescription, we compute the wavefunction at the semi-classical level and find a different result. We resolve in each case the ambiguity in the form of the Wheeler-DeWitt equation at this level of approximation. By imposing that the Hamiltonians associated with these possibly distinct quantum theories are Hermitian, we determine the inner products of the corresponding Hilbert spaces and find that they lead to a universal norm, at least semi-classically. Quantum predictions are thus independent of the prescription at this level of approximation. Finally, all wavefunctions of the Hilbert spaces of the minisuperspace model we consider turn out to be non-normalizable, including the no-boundary states., Comment: 1+56 pages, 1 figure

Published

2021

9. Two-point functions of Neumann-Dirichlet open-string sector moduli

Author

Coudarchet, Thibaut and Partouche, Hervé

Subjects

High Energy Physics - Theory

Abstract

We compute at one loop the two-point functions of massless scalars in the Neumann-Dirichlet open-string sector of the type IIB orientifold compactified on $T^2\times T^4/\mathbb{Z}_2$, when $\mathcal{N}=2$ supersymmetry is spontaneously broken. This is done by evaluating correlation functions of ``boundary-changing vertex operators'' which are analogous to correlators of twist fields for closed strings. We use our results to compute the mass developed at one loop by the moduli fields arising in the Neumann-Dirichlet sector., Comment: 1+15 pages, 1 figure. Based on a talk given at the "9th International Conference on New Frontiers in Physics'' (ICNFP 2020), 4-12 September 2020, Kolympari, Greece

Published

2020

10. One-loop masses of Neumann-Dirichlet open strings and boundary-changing vertex operators

Author

Coudarchet, Thibaut and Partouche, Hervé

Subjects

High Energy Physics - Theory

Abstract

We derive the masses acquired at one loop by massless scalars in the Neumann-Dirichlet sector of open strings, when supersymmetry is spontaneously broken. It is done by computing two-point functions of "boundary-changing vertex operators" inserted on the boundaries of the annulus and M\"obius strip. This requires the evaluation of correlators of "excited boundary-changing fields," which are analogous to excited twist fields for closed strings. We work in the type IIB orientifold theory compactified on $T^2\times T^4/\mathbb{Z}_2$, where $\mathcal{N}=2$ supersymmetry is broken to $\mathcal{N}=0$ by the Scherk-Schwarz mechanism implemented along $T^2$. Even though the full expression of the squared masses is complicated, it reduces to a very simple form when the lowest scale of the background is the supersymmetry breaking scale $M_{3/2}$. We apply our results to analyze in this regime the stability at the quantum level of the moduli fields arising in the Neumann-Dirichlet sector. This completes the study of Ref. [32], where the quantum masses of all other types of moduli arising in the open- or closed-string sectors are derived. Ultimately, we identify all brane configurations that produce backgrounds without tachyons at one loop and yield an effective potential exponentially suppressed, or strictly positive with runaway behavior of $M_{3/2}$., Comment: 1+74 pages, 5 figures

Published

2020

11. Heterotic orbifolds, reduced rank and SO(2n+1) characters

Author

Partouche, Hervé and de Vaulchier, Balthazar

Subjects

High Energy Physics - Theory

Abstract

The moduli space of the maximally supersymmetric heterotic string in d-dimensional Minkowski space contains various components characterized by the rank of the gauge symmetries of the vacua they parametrize. We develop an approach for describing in a unified way continuous Wilson lines which parametrize a component of the moduli space, together with discrete deformations responsible for the switch from one component to the other. Applied to a component that contains vacua with SO(2n+1) gauge-symmetry factors, our approach yields a description of all backgrounds of the component in terms of free-orbifold models. The orbifold generators turn out to act symmetrically or asymmetrically on the internal space, with or without discrete torsion. Our derivations use extensively affine characters of SO(2n+1). As a by-product, we find a peculiar orbifold description of the heterotic string in ten dimensions, where all gauge degrees of freedom arise as twisted states, while the untwisted sector reduces to the gravitational degrees of freedom., Comment: 1+46 pages

Published

2020

12. Moduli stability in type I string orbifold models

Author

Coudarchet, Thibaut and Partouche, Hervé

Subjects

High Energy Physics - Theory

Abstract

We analyze the stability of the moduli at the quantum level in an open-string model realizing the $\mathcal{N}=2\to \mathcal{N}=0$ spontaneous breaking of supersymmetry in four-dimensional Minkowski spacetime. In the region of moduli space where the supersymmetry breaking scale is lower than the other scales, we identify vanishing minima of the one-loop effective potential, up to exponentially small corrections. In these backgrounds, the spectrum satisfies Bose-Fermi degeneracy at the massless level., Comment: 1+27 pages, 6 figures. Based on a talk given at the "Humboldt Kolleg Frontiers in Physics: From the Electroweak to the Planck Scales,'' 15--19 September 2019, Corfu, Greece

Published

2020

13. Dark-matter spontaneous freeze out

Author

Partouche, Hervé

Subjects

High Energy Physics - Phenomenology, Astrophysics - High Energy Astrophysical Phenomena, High Energy Physics - Theory

Abstract

We consider the possibility that thermalized dark-matter particles acquire their mass thanks to the spontaneous breaking of a symmetry below some critical temperature. We describe the regime where a freeze out mechanism takes place shortly after the onset of the phase transition, while the dark-matter mass has not yet reached its final constant value. For such a "spontaneous freeze out" to yield the correct relic density, the present-time cross section of annihilation of the dark matter into Standard-Model states has to be one or two orders of magnitude larger than in the case of a constant dark-matter mass., Comment: Based on a talk given at the International Conference on Neutrinos and Dark Matter (NDM-2020), 11-14 January 2020, Hurghada, Egypt

Published

2020

14. On the stability of open-string orbifold models with broken supersymmetry

Author

Abel, Steven, Coudarchet, Thibaut, and Partouche, Hervé

Subjects

High Energy Physics - Theory

Abstract

We consider an open-string realisation of $\mathcal{N}=2\to \mathcal{N}=0$ spontaneous breaking of supersymmetry in four-dimensional Minkowski spacetime. It is based on type IIB orientifold theory compactified on $T^2\times T^4/\mathbb{Z}_2$, with Scherk--Schwarz supersymmetry breaking implemented along $T^2$. We show that in the regions of moduli space where the supersymmetry breaking scale is lower than the other scales, there exist configurations with minima that have massless Bose-Fermi degeneracy and hence vanishing one-loop effective potential, up to exponentially suppressed corrections. These backgrounds describe non-Abelian gauge theories, with all open-string moduli and blowing up modes of $T^4/\mathbb{Z}_2$ stabilized, while all untwisted closed-string moduli remain flat directions. Other backgrounds with strictly positive effective potentials exist, where the only instabilities arising at one loop are associated with the supersymmetry breaking scale, which runs away. All of these backgrounds are consistent non-perturbatively., Comment: 1+66 pages, 6 figures. v2: New results. Stable models with massless Bose-Fermi degeneracy exist. v3: Minor corrections of gauge groups of stable models

Published

2020

15. Heterotic-Type I Dual Pairs, Rigid Branes and Broken Susy

Author

Angelantonj, Carlo, Partouche, Herve, and Pradisi, Gianfranco

Subjects

High Energy Physics - Theory

Abstract

The moduli space of toroidal type I vacua, which are consistent at the non-perturbative level, consists of independent branches characterized by the number (0, 16 or 32) of rigid branes sitting on top of orientifold planes. This structure persists also when supersymmetry is spontaneously broken a la Scherk-Schwarz. We show that all the components of the moduli space in dimension $D\ge 5$ indeed admit heterotic dual components, by explicitly constructing heterotic-type I dual pairs with the rank of the gauge group reduced by 0, 8 or 16 units. In the presence of spontaneous breaking of supersymmetry, the dual pairs we consider are also free of tachyonic instabilities at the one-loop level, provided the scale of supersymmetry breaking is lower than the string scale., Comment: 1+30 pages, minor corrections, one reference added. Accepted Version in Nucl.Phys.B

Published

2019

16. Induced cosmological and Newton constants from towers of states

Author

Partouche, Hervé and de Vaulchier, Balthazar

Subjects

High Energy Physics - Theory, General Relativity and Quantum Cosmology

Abstract

We consider quadratic gravity with only Ricci squared and Weyl squared kinetic terms at tree-level, coupled to specific numbers of infinite towers of free scalars, Weyl fermions and gauge bosons in four dimensions. We show that predictable cosmological and Newton constants are induced at 1-loop. This result is cross-checked using both the heat kernel method and Adler's approach., Comment: Based on a talk given at the Corfu Summer Institute 2019 "School and Workshops on Elementary Particle Physics and Gravity'' (CORFU2019), 31 August -- 25 September 2019, Corfu, Greece

Published

2019

17. Spontaneous Freeze Out of Dark Matter

Author

Coudarchet, Thibaut, Heurtier, Lucien, and Partouche, Hervé

Subjects

High Energy Physics - Theory, Astrophysics - High Energy Astrophysical Phenomena, General Relativity and Quantum Cosmology, High Energy Physics - Phenomenology

Abstract

We present a new paradigm for the production of dark-matter particles called the spontaneous freeze out, in which the decoupling from the thermal bath is enforced by the sudden increase of the dark-matter mass, due to the spontaneous breaking of some global symmetry rather than by the slow decrease of the temperature. We study the details of the spontaneous freeze out mechanism using a simple toy model and analyze the phenomenology of our scenario. We show that in order to obtain the correct relic abundance, the annihilation cross section of dark-matter particles into Standard-Model states has to be typically much larger than in the case of a constant-mass thermal dark-matter candidate. We present a string theory model in which such a scenario takes place naturally., Comment: Based on a talk given at the Conference on Recent Developments in Strings and Gravity, 10 to 16 September 2019, Corfu, Greece

Published

2019

18. Induced Einstein gravity from infinite towers of states

Author

Kehagias, Alex, Partouche, Hervé, and de Vaulchier, Balthazar

Subjects

High Energy Physics - Theory, General Relativity and Quantum Cosmology

Abstract

We consider four-dimensional quadratic gravity coupled to infinite towers of free massive scalar fields, Weyl fermions and vector bosons. We find that for specific numbers of towers, finite cosmological and Newton constants are induced in the 1-loop effective action. This is derived both in Adler's approach and by using the heat kernel method, which yield identical results. If the infinite number of massive states may be regarded as Kaluza--Klein modes arising from fields in higher dimensions, there are no Kaluza--Klein states associated with the four-dimensional graviton. Hence gravity is intrinsically four-dimensional.

Published

2019

19. Spontaneous Freeze Out of Dark Matter From an Early Thermal Phase Transition

Author

Heurtier, Lucien and Partouche, Herve

Subjects

High Energy Physics - Phenomenology, Astrophysics - High Energy Astrophysical Phenomena, High Energy Physics - Theory

Abstract

We propose a new paradigm for the thermal production of dark matter in the early universe, in which dark-matter particles acquire their mass and freeze out spontaneously from the thermal bath after a dark phase transition takes place. The decoupling arises because the dark-matter particles become suddenly non-relativistic and not because of any decay channel becoming kinematically close. We propose a minimal scenario in which a scalar and a fermionic dark-matter are in thermal equilibrium with the Standard-Model bath. We compute the finite temperature corrections to the scalar potential and identify a region of the parameter space where the fermionic dark-matter mass spontaneously jumps over the temperature when the dark phase transition happens. We explore the phenomenological implications of such a model in simple cases and show that the annihilation cross section of dark-matter particles has to be larger by more than one order of magnitude as compared to the usual constant-mass WIMP scenario in order to accomodate the correct relic abundance. We show that in the spontaneous freeze out regime a TeV-scale fermionic dark-matter that annihilates into leptons through s-wave processes can be accessible to detection in the near future., Comment: 14 pages, 8 figures

Published

2019

20. Phase transition at high supersymmetry breaking scale in string theory

Author

Partouche, Herve and de Vaulchier, Balthazar

Subjects

High Energy Physics - Theory

Abstract

When supersymmetry is spontaneously broken at tree level, the spectrum of the heterotic string compactified on orbifolds of tori contains an infinite number of potentially tachyonic modes. We show that this implies instabilities of Minkowski spacetime, when the scale of supersymmetry breaking is of the order of the string scale. We derive the phase space structure of vacua in the case where the tachyonic spectrum contains a mode with trivial momenta and winding numbers along the internal directions not involved in the supersymmetry breaking.

Published

2019

21. Hagedorn-like transition at high supersymmetry breaking scale

Author

Partouche, Herve and de Vaulchier, Balthazar

Subjects

High Energy Physics - Theory, General Relativity and Quantum Cosmology

Abstract

We consider phase transitions occurring in four-dimensional heterotic orbifold models, when the scale of spontaneous breaking of N=1 supersymmetry is of the order of the string scale. The super-Higgs mechanism is implemented by imposing distinct boundary conditions for bosons and fermions along an internal circle of radius R. Depending on the orbifold action, the usual scalars becoming tachyonic when R falls below the Hagedorn radius may or may not be projected out of the spectrum. In all cases, infinitely many other scalars, which are pure Kaluza-Klein or pure winding states along other internal directions, become tachyonic in subregions in moduli space. We derive the off-shell tree level effective potential that takes into account these potentially tachyonic modes. We show that when a combination of the usual tachyons survives the orbifold action, it is the only degree of freedom that actually condenses., Comment: 35+1 pages, 1 figure. v2: Improved discussion of the orbifold action

Published

2019

22. Quantum stability in open string theory with broken supersymmetry

Author

Partouche, Herve

Subjects

High Energy Physics - Theory, General Relativity and Quantum Cosmology, High Energy Physics - Phenomenology

Abstract

We consider the 1-loop effective potential in type I string theory compactified on a torus, with supersymmetry broken by the Scherk-Schwarz mechanism. At fixed supersymmetry breaking scale M, and up to exponentially suppressed terms, we show that the potential admits local minima of arbitrary sign, in dimension d<=5. While the open string Wilson lines are massive, the closed string moduli are flat directions. In a T-dual picture, the relevant backgrounds involve isolated 1/2-branes, whose positions are frozen on orientifold planes, thus decreasing the rank of the gauge group, and introducing massless fermions in fundamental representations., Comment: 1+9 pages

Published

2019

23. A unimodular-like string effective description

Author

Kehagias, Alex, Partouche, Hervé, and Toumbas, Nicolaos

Published

2023

24. The Casimir effect in string theory

Author

Kehagias, Alexandros and Partouche, Herve

Subjects

High Energy Physics - Theory, General Relativity and Quantum Cosmology, Quantum Physics

Abstract

We discuss the Casimir effect in heterotic string theory. This is done by considering a Z_2 twist acting on one external compact direction and three internal coordinates. The hyperplanes fixed by the orbifold generator G realize the two infinite parallel plates. For the latter to behave as "conducting material", we implement in a modular invariant way the projection (1-G)/2 on the spectrum running in the vacuum-to-vacuum amplitude at one-loop. Hence, the relevant projector to account for the Casimir effect is orthogonal to that commonly used in string orbifold models, which is (1+G)/2. We find that this setup yields the same net force acting on the plates in the context of quantum field theory and string theory. However, when supersymmetry is not present from the onset, finiteness of the resultant force in field theory is reached by adding formally infinite forces acting on either side of each plate, while in string theory both contributions are finite. On the contrary, when supersymmetry is spontaneously broken a la Scherk-Schwarz, finiteness of each contribution is fulfilled in field and string theory., Comment: 1+30 pages

Published

2018

25. Spontaneous dark-matter mass generation along cosmological attractors in string theory

Author

Coudarchet, Thibaut, Heurtier, Lucien, and Partouche, Herve

Subjects

High Energy Physics - Theory, General Relativity and Quantum Cosmology, High Energy Physics - Phenomenology

Abstract

We propose a new scenario for generating a relic density of non-relativistic dark matter in the context of heterotic string theory. Contrary to standard thermal freeze-out scenarios, dark-matter particles are abundantly produced while still relativistic, and then decouple from the thermal bath due to the sudden increase of their mass above the universe temperature. This mass variation is sourced by the condensation of an order-parameter modulus, which is triggered when the temperature T(t) drops below the supersymmetry breaking scale M(t), which are both time-dependent. A cosmological attractor mechanism forces this phase transition to take place, in an explicit class of heterotic string models with spontaneously broken supersymmetry, and at finite temperature., Comment: 41 pages, 6 figures

Published

2018

26. Stability and vacuum energy in open string models with broken supersymmetry

Author

Abel, Steven, Dudas, Emilian, Lewis, Daniel, and Partouche, Herve

Subjects

High Energy Physics - Theory, General Relativity and Quantum Cosmology, High Energy Physics - Phenomenology

Abstract

We construct type I string models with supersymmetry broken by compactification that are non-tachyonic and have exponentially small effective potential at one-loop. All open string moduli can be stabilized, while the closed string moduli remain massless at one-loop. The backgrounds of interest have rigid Wilson lines by the use of stacked branes, and some models should have heterotic duals. We also present non-tachyonic backgrounds with positive potentials of runaway type at one-loop. This class of models could be used to test various swampland conjectures., Comment: 1+53 pages, 2 figures, 2 tables

Published

2018

27. Corrigendum to On the stability of open-string orbifold models with broken supersymmetry [Nuclear Physics, Section B,(2020) NUPHB 115100]

Author

Abel, Steven, primary, Coudarchet, Thibaut, additional, and Partouche, Hervé, additional

Published

2024

28. Quantum no-scale regimes and string moduli

Author

Partouche, Herve

Subjects

High Energy Physics - Theory, General Relativity and Quantum Cosmology, High Energy Physics - Phenomenology

Abstract

We review that in perturbative string theory, flat, homogeneous and isotropic cosmological evolutions found in no-scale models at the quantum level can enter into "quantum no-scale regimes" (QNSRs). When this is the case, the quantum effective potential is dominated by the classical kinetic energies of the no-scale modulus, dilaton and moduli not involved in the supersymmetry breaking. As a result, the evolutions approach the classical ones, where the no-scale structure is exact. When the 1-loop potential is positive, a global attractor mechanism forces the initially expanding solutions to enter the QNSR describing a flat, ever-expanding universe. On the contrary, when the potential can reach negative values, the internal moduli induce in most cases some kind of instability of the growing universe. The latter stops expanding and eventually collapses, unless the initial conditions are tuned in a tiny region of the phase space. Finally, in QNSR, no gauge instability takes place, regardless of the details of the potential., Comment: 1+17 pages, 3 figures

Published

2018

29. Quantum no-scale regimes and moduli dynamics

Author

Coudarchet, Thibaut and Partouche, Herve

Subjects

High Energy Physics - Theory, General Relativity and Quantum Cosmology, High Energy Physics - Phenomenology

Abstract

We analyze quantum no-scale regimes (QNSR) in perturbative heterotic string compactified on tori, with total spontaneous breaking of supersymmetry. We show that for marginal deformations initially at any point in moduli space, the dynamics of a flat, homogeneous and isotropic universe can always be attracted to a QNSR. This happens independently of the characteristics of the 1-loop effective potential $V_{1-loop}$, which can be initially positive, negative or vanishing, and maximal, minimal or at a saddle point. In all cases, the classical no-scale structure is restored at the quantum level, during the cosmological evolution. This is shown analytically by considering moduli evolutions entirely in the vicinity of their initial values. Global attractor mechanisms are analyzed numerically and depend drastically on the sign of $V_{1-loop}$. We find that all initially expanding cosmological evolutions along which $V_{1-loop}$ is positive are attracted to the QNSR describing a flat, ever-expanding universe. On the contrary, when $V_{1-loop}$ can reach negative values, the expansion comes to a halt and the universe eventually collapses into a Big Crunch, unless the initial conditions are tuned in a tiny region of the phase space. This suggests that flat, ever-expanding universes with positive potentials are way more natural than their counterparts with negative potentials., Comment: 1+65 pages, 9 figures, 1 appendix

Published

2018

30. Quantum no-scale regimes in string theory

Author

Coudarchet, Thibaut, Fleming, Claude, and Partouche, Herve

Subjects

High Energy Physics - Theory, General Relativity and Quantum Cosmology, High Energy Physics - Phenomenology

Abstract

We show that in generic no-scale models in string theory, the flat, expanding cosmological evolutions found at the quantum level can be attracted to a "quantum no-scale regime", where the no-scale structure is restored asymptotically. In this regime, the quantum effective potential is dominated by the classical kinetic energies of the no-scale modulus and dilaton. We find that this natural preservation of the classical no-scale structure at the quantum level occurs when the initial conditions of the evolutions sit in a subcritical region of their space. On the contrary, supercritical initial conditions yield solutions that have no analogue at the classical level. The associated intrinsically quantum universes are sentenced to collapse and their histories last finite cosmic times. Our analysis is done at 1-loop, in perturbative heterotic string compactified on tori, with spontaneous supersymmetry breaking implemented by a stringy version of the Scherk-Schwarz mechanism., Comment: 26+1 pages, 3 figures

Published

2017

31. N=2 -> 0 super no-scale models and moduli quantum stability

Author

Kounnas, Costas and Partouche, Herve

Subjects

High Energy Physics - Theory, General Relativity and Quantum Cosmology, High Energy Physics - Phenomenology

Abstract

We consider a class of heterotic N=2 -> 0 super no-scale Z_2-orbifold models. An appropriate stringy Scherk-Schwarz supersymmetry breaking induces tree level masses to all massless bosons of the twisted hypermultiplets and therefore stabilizes all twisted moduli. At high supersymmetry breaking scale, the tachyons that occur in the N=4 -> 0 parent theories are projected out, and no Hagedorn-like instability takes place in the N=2 -> 0 models (for small enough marginal deformations). At low supersymmetry breaking scale, the stability of the untwisted moduli is studied at the quantum level by taking into account both untwisted and twisted contributions to the 1-loop effective potential. The latter depends on the specific branch of the gauge theory along which the background can be deformed. We derive its expression in terms of all classical marginal deformations in the pure Coulomb phase, and in some mixed Coulomb/Higgs phases. In this class of models, the super no-scale condition requires having at the massless level equal numbers of untwisted bosonic and twisted fermionic degrees of freedom. Finally, we show that N=1 -> 0 super no-scale models are obtained by implementing a second Z_2 orbifold twist on N=2 -> 0 super no-scale Z_2-orbifold models., Comment: 43+1 pages

Published

2017

32. Phase Transitions at High Supersymmetry Breaking Scale in String Theory

Author

Partouche, Hervé, de Vaulchier, Balthazar, and Dobrev, Vladimir, editor

Published

2020

33. Super no-scale models in string theory

Author

Kounnas, Costas and Partouche, Herve

Subjects

High Energy Physics - Theory, General Relativity and Quantum Cosmology, High Energy Physics - Phenomenology

Abstract

We consider "super no-scale models" in the framework of the heterotic string, where the N=4,2,1 --> 0 spontaneous breaking of supersymmetry is induced by geometrical fluxes realizing a stringy Scherk-Schwarz perturbative mechanism. Classically, these backgrounds are characterized by a boson/fermion degeneracy at the massless level, even if supersymmetry is broken. At the 1-loop level, the vacuum energy is exponentially suppressed, provided the supersymmetry breaking scale is small, m_{3/2} << M_{string}. We show that the "super no-scale string models" under consideration are free of Hagedorn-like tachyonic singularities, even when the supersymmetry breaking scale is large, m_{3/2} ~ M_{string}. The vacuum energy decreases monotonically and converges exponentially to zero, when m_{3/2} varies from M_{string} to 0. We also show that all Wilson lines associated to asymptotically free gauge symmetries are dynamically stabilized by the 1-loop effective potential, while those corresponding to non-asymtotically free gauge groups lead to instabilities and condense. The Wilson lines of the conformal gauge symmetries remain massless. When stable, the stringy super no-scale models admit low energy effective actions, where decoupling gravity yields theories in flat spacetime, with softly broken supersymmetry., Comment: 1+46 pages, 1 figure

Published

2016

34. Large volume supersymmetry breaking without decompactification problem

Author

Partouche, Herve

Subjects

High Energy Physics - Theory, High Energy Physics - Phenomenology

Abstract

We consider heterotic string backgrounds in four-dimensional Minkowski space, where N=1 supersymmetry is spontaneously broken at a low scale m_{3/2} by a stringy Scherk-Schwarz mechanism. We review how the effective gauge couplings at 1-loop may evade the "decompactification problem", namely the proportionality of the gauge threshold corrections, with the large volume of the compact space involved in the supersymmetry breaking., Comment: 10 pages. Based on a talk given at "Lie theory and its applications in physics (LT-11), Varna, Bulgaria, 15 - 21 June 2015

Published

2016

35. Stringy N = 1 super no-scale models

Author

Kounnas, Costas and Partouche, Herve

Subjects

High Energy Physics - Theory, General Relativity and Quantum Cosmology, High Energy Physics - Phenomenology

Abstract

N=1 no-scale models describe at tree level the spontaneous breaking of supersymmetry at an arbitrary scale m_{3/2}, with vanishing vacuum energy. We define N=1 super no-scale models in string theory as being those, which maintain these properties at 1-loop. In other words, in super no-scale models, m_{3/2} is a flat direction of a positive semi-definite 1-loop effective potential. We find explicit examples in heterotic Z_2 x Z_2 orbifold models, where N=1 is spontaneously broken by a stringy Scherk-Schwarz mechanism, and where the "decompactification problem" does not arise., Comment: 23 pages

Published

2015

36. Heterotic − type I dual pairs, rigid branes and broken SUSY

Author

Angelantonj, Carlo, Partouche, Hervé, and Pradisi, Gianfranco

Published

2020

37. Large volume susy breaking with a solution to the decompactification problem

Author

Faraggi, Alon E., Kounnas, Costas, and Partouche, Herve

Subjects

High Energy Physics - Theory, High Energy Physics - Phenomenology

Abstract

We study heterotic ground states in which supersymmetry is broken by coupling the momentum and winding charges of two large extra dimensions to the R-charges of the supersymmetry generators. The large dimensions give rise to towers of heavy string thresholds that contribute to the running of the gauge couplings. In the general case, these contributions are proportional to the volume of the two large dimensions and invalidate the perturbative string expansion. The problem is evaded if the susy breaking sectors arise as a spontaneously broken phase of N=4 -> N=2 -> N=0 supersymmetry, provided that N=4 supersymmetry is restored on the boundary of the moduli space. We discuss the mechanism in the case of Z_2 x Z_2 orbifolds, which requires that the twisted sector that contains the large extra dimensions has no fixed points. We analyse the full string partition function and show that the twisted sectors distribute themselves in non-aligned N=2 orbits, hence preserving the solution to the string decompactification problem. Remarkably, we find that the contribution to the vacuum energy from the N=2 -> N=0 sectors is suppressed, and the only substantial contribution arises from the breaking of the N=4 sector to N=0., Comment: 1+63 pages

Published

2014

38. Cosmological Perturbations Across an S-brane

Author

Brandenberger, Robert H., Kounnas, Costas, Partouche, Herve, Patil, Subodh P., and Toumbas, Nicolaos

Subjects

High Energy Physics - Theory, Astrophysics - Cosmology and Nongalactic Astrophysics, General Relativity and Quantum Cosmology, High Energy Physics - Phenomenology

Abstract

Space-filling S-branes can mediate a transition between a contracting and an expanding universe in the Einstein frame. Following up on previous work that uncovered such bouncing solutions in the context of weakly coupled thermal configurations of a certain class of type II superstrings, we set up here the formalism in which we can study the evolution of metric fluctuations across such an S-brane. Our work shows that the specific nature of the S-brane, which is sourced by non-trivial massless thermal string states and appears when the universe reaches a maximal critical temperature, allows for a scale invariant spectrum of curvature fluctuations to manifest at late times via a stringy realization of the matter bounce scenario. The finite energy density at the transition from contraction to expansion provides calculational control over the propagation of the curvature perturbations through the bounce, furnishing a working proof of concept that such a stringy universe can result in viable late time cosmology., Comment: 30 pages, 3 appendices, typos corrected, references added, matches version to appear in JCAP

Published

2013

39. One-loop masses of Neumann-Dirichlet open strings and boundary-changing vertex operators

Author

Coudarchet, Thibaut and Partouche, Hervé

Published

2021

40. On The Real Part of a Conformal Field Theory

Author

Gepner, Doron and Partouche, Herve

Subjects

High Energy Physics - Theory

Abstract

Every conformal field theory has the symmetry of taking each field to its adjoint. We consider here the quotient (orbifold) conformal field theory obtained by twisting with respect to this symmetry. A general method for computing such quotients is developed using the coulomb gas representation. Examples of parafermions, $SU(2)$ current algebra and the $N=2$ minimal models are described explicitly. The partition functions and the dimensions of the disordered fields are given. This result is a tool for finding new theories., Comment: 9 pages

Published

2013

41. Moduli stabilization in type II Calabi-Yau compactifications at finite temperature

Author

Liu, Lihui and Partouche, Herve

Subjects

High Energy Physics - Theory

Abstract

We consider the type II superstring compactified on Calabi-Yau threefolds at finite temperature. The latter is implemented at the string level by a free action on the Euclidean time circle. We show that all Kahler and complex structure moduli involved in the gauge theories geometrically engineered in the vicinity of singular loci are lifted by the stringy thermal effective potential. The analysis is based on the effective gauged supergravity at low energy, without integrating out the BPS states becoming massless at the singular loci. The universal form of the action in the weak coupling regime at low enough temperature is determined in two cases. Namely the conifold locus, as well as a locus where the internal space develops a genus-g curve of A{N-1} singularities, realizing an SU(N) gauge theory coupled to g hypermultiplets in the adjoint. In general, the favored points of stabilization sit at the intersection of several singular loci. Thus the entire vector multiplet moduli space can be lifted, together with hypermultiplet moduli. The scalars are dynamically stabilized during the cosmological evolution induced by the back-reaction of the thermal effective potential. When the universe expands and the temperature T drops, the scalars converge to minima, with damped oscillations. Moreover, they store an energy density that scales as T^4, which never dominates over radiation. The reason for this is that the mass they acquire at one-loop is of order the temperature scale, which is time-dependent. As an example we analyze the type IIA compactification on a Calabi-Yau space with Hodge numbers h{11}=2 and h{12}=128. In this case, both Kahler moduli are stabilized, where the internal space develops a node and an enhanced SU(2) gauge theory coupled to 2 adjoint hypermultiplets. This shows that in the dual thermal heterotic picture on K3xT^2, the torus modulus and the axio-dilaton are stabilized., Comment: 59 pages, comments added in the introduction on how moduli stabilization by thermal effects in the early universe is related to late time moduli stabilization by non-thermal effects

Published

2011

42. S-brane to thermal non-singular string cosmology

Author

Kounnas, Costas, Partouche, Herve, and Toumbas, Nicolaos

Subjects

High Energy Physics - Theory, General Relativity and Quantum Cosmology, High Energy Physics - Phenomenology

Abstract

We present a new class of non-singular string cosmologies in d space-time dimensions. At very early times, \tau << \tau_c, the Universe is described by a flat \sigma-model metric, a constant maximal temperature T_c and super-weak string interactions, g_str << 1. During the evolution, the metric remains flat up to \tau_c, while the string coupling grows and reaches a critical value g*_str at \tau_c. This phase is characterized by a uniform temporal distribution of spacelike branes. At later times, \tau > \tau_c, the Universe enters in a new phase of expansion, with radiation. The string coupling decreases due to the dilaton motion and asymptotes to a constant for \tau >> \tau_c. Throughout the evolution, the string coupling remains smaller than g*_str. In the Einstein frame, the cosmologies describe bouncing Universes, where two distinct phases are connected at \tau_c. In the initial contracting phase, the evolution of the scale factor is identical to that of a negatively curved Universe filled with radiation. At later times, the Universe enters in an expanding thermal phase with a running dilaton. Explicit examples are presented in a large class of thermal (4,0) type II superstring vacua, with non-trivial "gravito-magnetic" fluxes., Comment: 1+35 pages

Published

2011

43. Non-singular superstring cosmology in two dimensions

Author

Partouche, Herve

Subjects

High Energy Physics - Theory, General Relativity and Quantum Cosmology, High Energy Physics - Phenomenology

Abstract

We review a recently proposed approach to construct superstring cosmological evolutions, which are free of Hagedorn instabilities and initial singularities. We illustrate these ideas in hybrid models in two dimensions., Comment: 8 pages. Based on a talk given at the "10th Hellenic School and Workshops on Elementary Particle Physics and Gravity", Corfu, Greece, September 4 - 18, 2010

Published

2011

44. Thermal duality and non-singular cosmology in d-dimensional superstrings

Author

Kounnas, Costas, Partouche, Herve, and Toumbas, Nicolaos

Subjects

High Energy Physics - Theory, General Relativity and Quantum Cosmology, High Energy Physics - Phenomenology

Abstract

We are presenting the basic ingredients of a stringy mechanism able to resolve both the Hagedorn instabilities of finite temperature superstrings as well as the initial singularity of the induced cosmology in arbitrary dimensions. These are shown to be generic in a large class of (4,0) type II superstring vacua, where non-trivial "gravito-magnetic" fluxes lift the Hagedorn instabilities of the thermal ensemble and the temperature duality symmetry is restored. This symmetry implies a universal maximal critical temperature. In all such models there are three characteristic regimes, each with a distinct effective field theory description: Two dual asymptotically cold regimes associated with the light thermal momentum and light thermal winding states, and the intermediate regime where additional massless thermal states appear. The partition function exhibits a conical structure as a function of the thermal modulus, irrespective of the space-time dimension. Thanks to asymptotic right-moving supersymmetry, the genus-1 partition function is well-approximated by that of massless thermal radiation in all of the three effective field theory regimes. The resulting time-evolution describes a bouncing cosmology connecting, via spacelike branes, a contracting thermal "winding" Universe to an expanding thermal "momentum" Universe, free of any essential curvature singularities. The string coupling remains perturbative throughout the cosmological evolution. Bouncing cosmologies are presented for both zero and negative spatial curvature., Comment: 39+1 pages, 2 figures

Published

2011

45. Massless D-strings and moduli stabilization in type I cosmology

Author

Estes, John, Liu, Lihui, and Partouche, Herve

Subjects

High Energy Physics - Theory

Abstract

We consider the cosmological evolution induced by the free energy F of a gas of maximally supersymmetric heterotic strings at finite temperature and weak coupling in dimension D>=4. We show that F, which plays the role of an effective potential, has minima associated to enhanced gauge symmetries, where all internal moduli can be attracted and dynamically stabilized. Using the fact that the heterotic/type I S-duality remains valid at finite temperature and can be applied at each instant of a quasi-static evolution, we find in the dual type I cosmology that all internal NS-NS and RR moduli in the closed string sector and the Wilson lines in the open string sector can be stabilized. For the special case of D=6, the internal volume modulus remains a flat direction, while the dilaton is stabilized. An essential role is played by light D-string modes wrapping the internal manifold and whose contribution to the free energy cannot be omitted, even when the type I string is at weak coupling. As a result, the order of magnitude of the internal radii expectation values on the type I side is (lambda_I alpha')^{1/2}, where lambda_I is the ten-dimensional string coupling. The non-perturbative corrections to the type I free energy can alternatively be described as effects of "thermal E1-instantons", whose worldsheets wrap the compact Euclidean time cycle., Comment: 39 pages, 1 figure

Published

2011

46. Non-singular string cosmology in a 2d Hybrid model

Author

Florakis, Ioannis, Kounnas, Costas, Partouche, Herve, and Toumbas, Nicolaos

Subjects

High Energy Physics - Theory, General Relativity and Quantum Cosmology, High Energy Physics - Phenomenology

Abstract

The existence of non-singular string cosmologies is established in a class of two-dimensional supersymmetric Hybrid models at finite temperature. The left-moving sector of the Hybrid models gives rise to 16 real (N_4=4) spacetime supercharges as in the usual superstring models. The right-moving sector is non-supersymmetric at the massless level, but is characterized by MSDS symmetry, which ensures boson/fermion degeneracy of the right-moving massive levels. Finite temperature configurations, which are free of Hagedorn instabilities, are constructed in the presence of non-trivial "gravito-magnetic" fluxes. These fluxes inject non-trivial winding charge into the thermal vacuum and restore the thermal T-duality symmetry associated with the Euclidean time circle. Thanks to the unbroken right-moving MSDS symmetry, the one-loop string partition function is exactly calculable beyond any alpha'-approximation. At the self-dual point new massless thermal states appear, sourcing localized spacelike branes, which can be used to connect a contracting thermal Universe to an expanding one. The resulting bouncing cosmology is free of any curvature singularities and the string coupling remains perturbative throughout the cosmological evolution., Comment: 38 pages

Published

2010

47. Attractions to radiation-like eras in superstring cosmologies

Author

Partouche, Herve

Subjects

High Energy Physics - Theory

Abstract

We review the cosmology induced by finite temperature and quantum effects on non-supersymmetric string models. We show the evolution is attracted to radiation-like solutions after the Hagedorn era and before the electroweak phase transition. This mechanism generates a hierarchy between the Planck mass and the supersymmetry breaking scale. A dynamical change of space-time dimension can take place., Comment: 8 pages

Published

2010

48. Superstring cosmology for N_4 = 1 -> 0 superstring vacua

Author

Estes, John, Kounnas, Costas, and Partouche, Herve

Subjects

High Energy Physics - Theory

Abstract

We study the cosmology of perturbative heterotic superstring theory during the radiation-like era for semi-realistic backgrounds with initial $\N=1$ supersymmetry. This analysis is valid for times after the Hagedorn era (or alternatively inflation era) but before the electroweak symmetry breaking transition. We find an attraction to a radiation-like era with the ratio of the supersymmetry breaking scale to temperature stabilized. This provides a dynamical mechanism for setting the supersymmetry breaking scale and its corresponding hierarchy with the Planck scale. For the internal space, we find that orbifold directions never decompactify, while toroidal directions may decompactify only when they are wrapped by certain geometrical fluxes which break supersymmetry. This suggests a mechanism for generating spatial directions during the radiation-like era. Moreover, we show that certain moduli may be stabilized during the radiation-like era with masses near the supersymmetry breaking scale. In addition, the moduli do not dominate at late times, thus avoiding the cosmological moduli problem., Comment: 54 pages, 3 figures

Published

2010

49. Cosmological Phases of the String Thermal Effective Potential

Author

Bourliot, Francois, Estes, John, Kounnas, Costas, and Partouche, Herve

Subjects

High Energy Physics - Theory

Abstract

In a superstring framework, the free energy density, F, can be determined unambiguously at the full string level once supersymmetry is spontaneously broken via geometrical fluxes. We show explicitly that only the moduli associated to the supersymmetry breaking may give relevant contributions. All other spectator moduli \mu_I give exponentially suppressed contributions for relatively small (as compared to the string scale) temperature, T, and supersymmetry breaking scale, M. More concisely, for \mu_I > T and M, F takes the form F(T,M; \mu_I)=F(T,M)+O[exp(- {\mu_I\over T}), exp(- {\mu_I\over M})] We study the cosmological regime where T and M are below the Hagedorn temperature scale T_H. In this regime, F remains finite for any values of the spectator moduli \mu_I. We investigate extensively the case of one spectator modulus \mu_d corresponding to R_d, the radius-modulus field of an internal compactified dimension. We show that its thermal effective potential admits five phases, each of which can be described by a distinct but different effective field theory. For late cosmological times, the Universe is attracted to a "Radiation-like evolution" with M(t) ~ T(t)~ 1/a(t)~ t^{-2/d}. The spectator modulus \mu(t) is stabilized either to the stringy enhanced symmetry point where R_d=1, or fixed at an arbitrary constant \mu_0>T,M. For arbitrary boundary conditions at some initial time, t_E, \mu(t) may pass through more than one effective field theory phase before its final attraction., Comment: 60 pages, 1 figure

Published

2009

50. Attraction to a radiation-like era in early superstring cosmologies

Author

Bourliot, Francois, Kounnas, Costas, and Partouche, Herve

Subjects

High Energy Physics - Theory, General Relativity and Quantum Cosmology, High Energy Physics - Phenomenology

Abstract

Starting from an initial classical four dimensional flat background of the heterotic or type II superstrings, we are able to determine at the string one-loop level the quantum corrections to the effective potential due to the spontaneous breaking of supersymmetry by "geometrical fluxes". Furthermore, considering a gas of strings at finite temperature, the full "effective thermal potential" is determined, giving rise to an effective non-trivial pressure. The backreaction of the quantum and thermal corrections to the space-time metric as well as to the moduli fields induces a cosmological evolution that depends on the early time initial conditions and the number of spontaneously broken supersymmetries. We show that for a whole set of initial conditions, the cosmological solutions converge at late times to two qualitatively different trajectories: They are either attracted to (i) a thermal evolution similar to a radiation dominated cosmology, implemented by a coherent motion of some moduli fields, or to (ii) a "Big Crunch" non-thermal cosmological evolution dominated by the non-thermal part of the effective potential or the moduli kinetic energy. During the attraction to the radiation-like era, periods of accelerated cosmology can occur. However, they do not give rise to enough inflation (e-fold < 0.2) for the models we consider, where N>1 supersymmetry is spontaneously broken to N=0., Comment: 38 pages, 4 figures, added references, added comments in the abstract

Published

2009