Fortschritte der Physik

2020

DOI: 10.1002/prop.202000044

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Tension Between a Vanishing Cosmological Constant and Non‐Supersymmetric Heterotic Orbifolds

Stefan Groot Nibbelink

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³

et al.

Abstract: We investigate under which conditions the cosmological constant vanishes perturbatively at the one‐loop level for heterotic strings on non‐supersymmetric toroidal orbifolds. To obtain model‐independent results, which do not rely on the gauge embedding details, we require that the right‐moving fermionic partition function vanishes identically in every orbifold sector. This means that each sector preserves at least one, but not always the same Killing spinor. The existence of such Killing spinors is related to t… Show more

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Introduction2

Nonsupersymmetric Modular Flavor Symmetries1

N = 1 Susy In Ten Dimensions1

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Cited by 17 publications

(7 citation statements)

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“…Further, large classes of explicit string models similar to those presented in Section 5.5 with the exact spectrum of the SM and no SUSY have been built [155][156][157][158]. However, much more effort has to be devoted to better understand their details, including the stability of these models [157,159], the versions of discrete (traditional and modular) flavor symmetries that they exhibit, and hence the phenomenology they yield.…”

Section: Nonsupersymmetric Modular Flavor Symmetriesmentioning

confidence: 99%

Neutrino Flavor Model Building and the Origins of Flavor and CP Violation: A Snowmass White Paper

Chen²,

et al. 2022

Preprint

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The neutrino sector offers one of the most sensitive probes of new physics beyond the Standard Model of Particle Physics (SM). The mechanism of neutrino mass generation is still unknown. The observed suppression of neutrino masses hints at a large scale, conceivably of the order of the scale of a Grand Unified Theory (GUT), a unique feature of neutrinos that is not shared by the charged fermions. The origin of neutrino masses and mixing is part of the outstanding puzzle of fermion masses and mixings, which is not explained in the SM. Flavor model building for both quark and lepton sectors is important in order to gain a better understanding of the origin of the structure of mass hierarchy and flavor mixing, which constitute the dominant fraction of the SM parameters.Recent activities in neutrino flavor model building based on non-Abelian discrete flavor symmetries and modular flavor symmetries have been shown to be a promising direction to explore. The emerging models provide a framework that has a significantly reduced number of undetermined parameters in the flavor sector. In addition, such framework affords a novel origin of CP violation from group theory, due to the intimate connection between physical CP transformation and group theoretical properties of non-Abelian discrete groups.Model building based on non-Abelian discrete flavor symmetries and their modular variants enables the particle physics community to interpret the current and anticipated upcoming data from neutrino experiments. Non-Abelian discrete flavor symmetries and their modular variants can result from compactification of a higher-dimensional theory. Pursuit of flavor model building based on such frameworks thus also provides the connection to possible UV completions, in particular to string theory. We emphasize the importance of constructing models in which the uncertainties of theoretical predictions are smaller than, or at most compatible with, the error bars of measurements in neutrino experiments. While there exist proof-of-principle versions of bottom-up models in which the theoretical uncertainties are under control, it is remarkable that the key ingredients of such constructions were discovered first in top-down model building. We outline how a successful unification of bottom-up and top-down ideas and techniques may guide us towards a new era of precision flavor model building in which future experimental results can give us crucial insights in the UV completion of the SM.

“…Further, large classes of explicit string models similar to those presented in Section 5.5 with the exact spectrum of the SM and no SUSY have been built [155][156][157][158]. However, much more effort has to be devoted to better understand their details, including the stability of these models [157,159], the versions of discrete (traditional and modular) flavor symmetries that they exhibit, and hence the phenomenology they yield.…”

Section: Nonsupersymmetric Modular Flavor Symmetriesmentioning

confidence: 99%

Neutrino Flavor Model Building and the Origins of Flavor and CP Violation: A Snowmass White Paper

Chen²,

et al. 2022

Preprint

View full text Add to dashboard Cite

The neutrino sector offers one of the most sensitive probes of new physics beyond the Standard Model of Particle Physics (SM). The mechanism of neutrino mass generation is still unknown. The observed suppression of neutrino masses hints at a large scale, conceivably of the order of the scale of a Grand Unified Theory (GUT), a unique feature of neutrinos that is not shared by the charged fermions. The origin of neutrino masses and mixing is part of the outstanding puzzle of fermion masses and mixings, which is not explained in the SM. Flavor model building for both quark and lepton sectors is important in order to gain a better understanding of the origin of the structure of mass hierarchy and flavor mixing, which constitute the dominant fraction of the SM parameters.Recent activities in neutrino flavor model building based on non-Abelian discrete flavor symmetries and modular flavor symmetries have been shown to be a promising direction to explore. The emerging models provide a framework that has a significantly reduced number of undetermined parameters in the flavor sector. In addition, such framework affords a novel origin of CP violation from group theory, due to the intimate connection between physical CP transformation and group theoretical properties of non-Abelian discrete groups.Model building based on non-Abelian discrete flavor symmetries and their modular variants enables the particle physics community to interpret the current and anticipated upcoming data from neutrino experiments. Non-Abelian discrete flavor symmetries and their modular variants can result from compactification of a higher-dimensional theory. Pursuit of flavor model building based on such frameworks thus also provides the connection to possible UV completions, in particular to string theory. We emphasize the importance of constructing models in which the uncertainties of theoretical predictions are smaller than, or at most compatible with, the error bars of measurements in neutrino experiments. While there exist proof-of-principle versions of bottom-up models in which the theoretical uncertainties are under control, it is remarkable that the key ingredients of such constructions were discovered first in top-down model building. We outline how a successful unification of bottom-up and top-down ideas and techniques may guide us towards a new era of precision flavor model building in which future experimental results can give us crucial insights in the UV completion of the SM.

“…with arbitrary integers n i , satisfying n 1 + n 2 + n 3 = 0 mod 2N , so that N = 1 SUSY is preserved [106]. The boundary conditions may also involve non-trivial gauge transformations.…”

Section: N = 1 Susy In Ten Dimensionsmentioning

confidence: 99%

Sculpting the Standard Model from low-scale Gauge-Higgs-Matter $E_8$ Grand Unification in ten dimensions

Anda²,

et al. 2021

Preprint

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A model with complete supersymmetric unification of the Standard Model matter content, interactions and families replication into a single E 8 gauge superfield in ten dimensions is presented. The gauge and extended Poincaré symmetries are broken through compactification of the T 6 /(Z 3 × Z 3 ) orbifold with Wilson lines, which reduces the original symmetry and matter content into those of the Standard Model. Proton decay is strongly suppressed automatically, while the unification scale is required to be as low as 10 6 − 10 9 GeV so that the corresponding physics may be potentially accessible and testable by future collider measurements. Such a low-scale Grand Unification concept yields a highly-constrained and predictive New Physics framework in a minimal and phenomenologically testable and consistent way.

“…It is however possible, in a more refined construction, to stabilize the corresponding modulus, yielding a negative scalar potential [9]. In a subclass of models, which satisfy a classical Bose/Fermi degeneracy at the massless level, this one-loop potential turns out to be exponentially suppressed at low supersymmetry breaking scale [18][19][20][21][22][23][24][25][26][27][28][29][30], but not vanishing [31].…”

Section: Introductionmentioning

confidence: 99%

Geometry of orientifold vacua and supersymmetry breaking

¹

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²

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³

2021

J. High Energ. Phys.

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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 O± and anti-orientifold planes $$ {\overline{\mathrm{O}}}_{\pm } $$ O ¯ ± . 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, non-linearly 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.

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