Your search keyword '"Daniel G. Figueroa"' showing total 6 results

1. Irreducible background of gravitational waves from a cosmic defect network: update and comparison of numerical techniques

Author

Jon Urrestilla, Mark Hindmarsh, Daniel G. Figueroa, Joanes Lizarraga, Ministerio de Economía y Competitividad (España), Ministerio de Ciencia, Innovación y Universidades (España), Helsinki Institute of Physics, and Department of Physics

Subjects

Physics, High Energy Physics - Theory, Phase transition, Cosmology and Nongalactic Astrophysics (astro-ph.CO), 010308 nuclear & particles physics, Cosmic microwave background, FOS: Physical sciences, General Relativity and Quantum Cosmology (gr-qc), Global symmetry, Scale invariance, 115 Astronomy, Space science, 01 natural sciences, Omega, 114 Physical sciences, General Relativity and Quantum Cosmology, High Energy Physics - Phenomenology, Amplitude, High Energy Physics - Phenomenology (hep-ph), High Energy Physics - Theory (hep-th), Lattice (order), 0103 physical sciences, 010306 general physics, Scaling, Mathematical physics, Astrophysics - Cosmology and Nongalactic Astrophysics

Abstract

Cosmological phase transitions in the early Universe may produce relics in the form of a network of cosmic defects. Independently of the order of a phase transition, topology of the defects, and their global or gauge nature, the defects are expected to emit gravitational waves (GWs) as the network energy-momentum tensor adapts itself to maintaining {scaling}. We show that the evolution of any defect network (and for that matter any scaling source) emits a GW background with spectrum $\Omega_{\rm GW} \propto f^3$ for $f \ll f_0$, $\Omega_{\rm GW} \propto 1/f^2$ for $f_0 \lesssim f \lesssim f_{\rm eq}$, and $\Omega_{\rm GW} \propto~const$ (i.e.~exactly scale-invariant) for $f \gg f_{\rm eq}$, where $f_0$ and $ f_{\rm eq}$ denote respectively the frequencies corresponding to the present and matter-radiation equality horizons. This background represents an irreducible emission of GWs from any scaling network of cosmic defects, with its amplitude characterized only by the symmetry breaking scale and the nature of the defects. Using classical lattice simulations we calculate the GW signal emitted by defects created after the breaking of a global symmetry $O(N) \rightarrow O(N-1)$. We obtain the GW spectrum for $N$ between 2 and 20 with two different techniques: integrating over unequal time correlators of the energy momentum tensor, updating our previous work on smaller lattices, and for the first time, comparing the result with the real time evolution of the tensor perturbations sourced by the same defects. Our results validate the equivalence of the two techniques. Using CMB upper bounds on the defects' energy scale, we discuss the difficulty of detecting this GW background in the case of global defects., Comment: 24 pages, 8 figures

Published

2020

2. Higgs field-curvature coupling and postinflationary vacuum instability

Author

Arttu Rajantie, Daniel G. Figueroa, and Francisco Torrenti

Subjects

Astrophysics and Astronomy, Particle physics, Cosmology and Nongalactic Astrophysics (astro-ph.CO), Physics beyond the Standard Model, High Energy Physics::Lattice, UNIVERSE, FOS: Physical sciences, Astronomy & Astrophysics, 01 natural sciences, Physics, Particles & Fields, High Energy Physics - Phenomenology (hep-ph), INFLATION, 0103 physical sciences, 010306 general physics, Eternal inflation, Particle Physics - Phenomenology, Physics, Gauge boson, Science & Technology, 010308 nuclear & particles physics, Electroweak interaction, High Energy Physics::Phenomenology, hep-ph, Inflaton, Renormalization group, High Energy Physics - Phenomenology, Higgs field, Physical Sciences, Higgs boson, astro-ph.CO, High Energy Physics::Experiment, Astrophysics - Cosmology and Nongalactic Astrophysics

Abstract

We study the post-inflationary dynamics of the Standard Model (SM) Higgs field in the presence of a non-minimal coupling $\xi|\Phi|^2R$ to gravity, both with and without the electroweak gauge fields coupled to the Higgs. We assume a minimal scenario in which inflation and reheating are caused by chaotic inflation with a quadratic potential, and no additional new physics is relevant below the Planck scale. By using classical real-time lattice simulations with a renormalisation group improved effective Higgs potential and by demanding the stability of the Higgs vacuum after inflation, we obtain upper bounds for $\xi$, taking into account the experimental uncertainty of the top-Yukawa coupling. We compare the bounds in the absence and presence of the electroweak gauge bosons, and conclude that the addition of gauge interactions has a rather minimal impact. In the unstable cases, we parametrize the time when such instability develops. For a top-quark mass $m_t \approx173.3 {\rm GeV}$, the Higgs vacuum instability is triggered for $\xi \gtrsim 4 -5$, although a slightly lower mass of $m_t \approx 172.1 {\rm GeV}$ pushes up this limit to $\xi \gtrsim 11 - 12$. This, together with the estimation $\xi \gtrsim 0.06$ for stability during inflation, provides tight constraints to the Higgs-curvature coupling within the SM., Comment: 15 pages, 13 figures. Minor changes to match version published in PRD

Published

2018

3. The Standard Model Higgs as the origin of the hot Big Bang

Author

Daniel G. Figueroa [0000-0002-4005-8915], Christian T. Byrnes [0000-0003-2583-6536], Daniel G. Figueroa, Christian T. Byrnes, Daniel G. Figueroa [0000-0002-4005-8915], Christian T. Byrnes [0000-0003-2583-6536], Daniel G. Figueroa, and Christian T. Byrnes

Abstract

If the Standard Model (SM) Higgs is weakly coupled to the inflationary sector, the Higgs is expected to be universally in the form of a condensate towards the end of inflation. The Higgs decays rapidly after inflation - via non-perturbative effects - into an out-of-equilibrium distribution of SM species, which thermalize soon afterwards. If the post-inflationary equation of state of the universe is stiff, $w \simeq +1$, the SM species eventually dominate the total energy budget. This provides a natural origin for the relativistic thermal plasma of SM species, required for the onset of the `hot Big Bang' era. The viability of this scenario requires the inflationary Hubble scale $H_*$ to be lower than the instability scale for Higgs vacuum decay, the Higgs not to generate too large curvature perturbations at cosmological scales, and the SM dominance to occur before Big Bang Nucleosynthesis. We show that successful reheating into the SM can only be obtained in the presence of a non-minimal coupling to gravity $\xi \gtrsim 1$, with a reheating temperature of $T_{\rm RH} \gtrsim \mathcal{O}(10^{10})\xi^{3/2}(H_*/10^{14}{\rm GeV})^2~{\rm GeV}$.

Published

2016

4. The Decay of the Standard Model Higgs after Inflation

Author

Daniel G. Figueroa [0000-0002-4005-8915], Juan Garcia-Bellido [0000-0002-9370-8360], Francisco Torrenti [0000-0003-1883-8365], Daniel G. Figueroa, Juan Garcia-Bellido, Francisco Torrenti, Daniel G. Figueroa [0000-0002-4005-8915], Juan Garcia-Bellido [0000-0002-9370-8360], Francisco Torrenti [0000-0003-1883-8365], Daniel G. Figueroa, Juan Garcia-Bellido, and Francisco Torrenti

Abstract

We study the nonperturbative dynamics of the Standard Model (SM) after inflation, in the regime where the SM is decoupled from (or weakly coupled to) the inflationary sector. We use classical lattice simulations in an expanding box in (3+1) dimensions, modeling the SM gauge interactions with both global and Abelian-Higgs analogue scenarios. We consider different post-inflationary expansion rates. During inflation, the Higgs forms a condensate, which starts oscillating soon after inflation ends. Via nonperturbative effects, the oscillations lead to a fast decay of the Higgs into the SM species, transferring most of the energy into $Z$ and $W^{\pm}$ bosons. All species are initially excited far away from equilibrium, but their interactions lead them into a stationary stage, with exact equipartition among the different energy components. From there on the system eventually reaches equilibrium. We have characterized in detail, in the different expansion histories considered, the evolution of the Higgs and of its dominant decay products, until equipartition is established. We provide a useful mapping between simulations with different parameters, from where we derive a master formula for the Higgs decay time, as a function of the coupling constants, Higgs initial amplitude and postinflationary expansion rate.

Published

2015

5. Preheating in the Standard Model with the Higgs-Inflaton coupled to gravity

Author

Daniel G. Figueroa, Javier Rubio, and Juan Garcia-Bellido

Subjects

High Energy Physics - Theory, Nuclear and High Energy Physics, Particle physics, High Energy Physics::Lattice, FOS: Physical sciences, Technicolor, Astrophysics, Standard Model, symbols.namesake, General Relativity and Quantum Cosmology, High Energy Physics::Theory, High Energy Physics - Phenomenology (hep-ph), Boson, Physics, Condensed Matter::Quantum Gases, Gauge boson, Astrophysics (astro-ph), High Energy Physics::Phenomenology, Inflaton, Higgs field, High Energy Physics - Phenomenology, High Energy Physics - Theory (hep-th), Quantum electrodynamics, Higgs boson, symbols, Higgs mechanism

Abstract

We study the details of preheating in an inflationary scenario in which the standard model Higgs, strongly nonminimally coupled to gravity, plays the role of the inflaton. We find that the Universe does not reheat immediately through perturbative decays, but rather initiates a complex process in which perturbative and nonperturbative effects are mixed. The Higgs condensate starts oscillating around the minimum of its potential, producing W and Z gauge bosons nonperturbatively, due to violation of the so-called adiabaticity condition. However, during each semioscillation, the created gauge bosons partially decay (perturbatively) into fermions. The decay of the gauge bosons prevents the development of parametric resonance, since bosons cannot accumulate significantly at the beginning. However, the energy transferred to the decay products of the bosons is not enough to reheat the Universe, so after about a hundred oscillations, the resonance effects will eventually dominate over the perturbative decays. Around the same time (or slightly earlier), backreaction from the gauge bosons into the Higgs condensate will also start to be significant. Soon afterwards, the Universe is filled with the remnant condensate of the Higgs and a nonthermal distribution of fermions and bosons (those of the standard model), which redshift as radiation and matter, respectively. We compute the distribution of the energy budget among all the species present at the time of backreaction. From there until thermalization, the evolution of the system is highly nonlinear and nonperturbative, and will require a careful study via numerical simulations., We would like to thank Geneva University, SISSA-Trieste and MPI-Munich for hospitality during the development of parts of this research. DGF is supported by a FPU contract with Ref. AP2005-1092 and JR by an I3P contract. We also acknowledge financial support from the Madrid Regional Government (CAM) under the program HEPHACOS P-ESP-00346, and the Spanish Research Ministry (MEC) under contract FPA2006-05807. The authors participate in the Consolider-Ingenio 2010 CPAN (CSD2007-00042) and PAU (CSD2007-00060), as well as in the European Union 6th Framework Marie Curie Network “UniverseNet” under contract MRTN-CT-2006-035863.

Published

2009

6. Gravitational Waves from Abelian Gauge Fields and Cosmic Strings at Preheating

Author

Jean-Francois Dufaux, Daniel G. Figueroa, Juan Garcia-Bellido, Jean-Francois Dufaux, Daniel G. Figueroa, and Juan Garcia-Bellido

Abstract

Primordial gravitational waves provide a very important stochastic background that could be detected soon with interferometric gravitational wave antennas or indirectly via the induced patterns in the polarization anisotropies of the cosmic microwave background. The detection of these waves will open a new window into the early Universe, and therefore it is important to characterize in detail all possible sources of primordial gravitational waves. In this paper we develop theoretical and numerical methods to study the production of gravitational waves from out-of-equilibrium gauge fields at preheating. We then consider models of preheating after hybrid inflation, where the symmetry breaking field is charged under a local U(1) symmetry. We analyze in detail the dynamics of the system in both momentum and configuration space, and show that gauge fields leave specific imprints in the resulting gravitational wave spectra, mainly through the appearence of new peaks at characteristic frequencies that are related to the mass scales in the problem. We also show how these new features in the spectra correlate with string-like spatial configurations in both the Higgs and gauge fields that arise due to the appearance of topological winding numbers of the Higgs around Nielsen-Olesen strings. We study in detail the time evolution of the spectrum of gauge fields and gravitational waves as these strings evolve and decay before entering a turbulent regime where the gravitational wave energy density saturates.

Published

2010