Classical decay rates of oscillons

Zhang, Hongyi; Amin, Mustafa A.; Copeland, Edmund J.; Saffin, Paul M.; Lozanov, Kaloian D.

doi:10.1088/1475-7516/2020/07/055

Cited by 76 publications

(147 citation statements)

References 84 publications

(159 reference statements)

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“…In particular, for M M P , as the field explores the flatter-than-quadratic region of the potential (φ M with α < 2), broad self-resonance drives copious production of oscillons [117,118,119,120,121,122,123]. Oscillons are highly overdense, spatially localized, exceptionally long-lived field configurations [124,125,126,127,128,129,130] where the field amplitude in their cores does not redshift as the universe expands. The rapid formation of oscillons from an almost homogeneous condensate at the end of inflation, and their slower gravitational clustering [79] is shown in Fig.…”

Section: The Modelmentioning

confidence: 99%

See 1 more Smart Citation

The First Three Seconds: a Review of Possible Expansion Histories of the Early Universe

Allahverdi¹,

Amin²,

Berlin³

et al. 2021

TheOJA

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183

138

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It is commonly assumed that the energy density of the Universe was dominated by radiation between reheating after inflation and the onset of matter domination 54,000 years later. While the abundance of light elements indicates that the Universe was radiation dominated during Big Bang Nucleosynthesis (BBN), there is scant evidence that the Universe was radiation dominated prior to BBN. It is therefore possible that the cosmological history was more complicated, with deviations from the standard radiation domination during the earliest epochs. Indeed, several interesting proposals regarding various topics such as the generation of dark matter, matter-antimatter asymmetry, gravitational waves, primordial black holes, or microhalos during a nonstandard expansion phase have been recently made. In this paper, we review various possible causes and consequences of deviations from radiation domination in the early Universe -taking place either before or after BBN -and the constraints on them, as they have been discussed in the literature during the recent years.

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Section: The Modelmentioning

confidence: 99%

“…Note that oscillons are long-lived (with lifetimes ∼ 10 8 oscillations of the field[130] in some models) but not perfectly stable and will evolve by slowly emitting scalar radiation.…”

mentioning

confidence: 99%

The First Three Seconds: a Review of Possible Expansion Histories of the Early Universe

Allahverdi¹,

Amin²,

Berlin³

et al. 2021

TheOJA

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183

138

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“…For potentials that have V (φ) ≈ (1/2)m 2 φ 2 where φ f and V (φ) ∝ φ α<2 where φ f (see figure 1), exceptionally long lived spatially localized configurations of the above form exist, and are called oscillons (setting g aγ → 0 for the moment). Typically, for very longlived oscillons, we have a field amplitude ϕ 0 ∼ f , a spatial width R ∼ few × m −1 and an oscillation frequency ω m [83]. In detail, there is a one parameter family of long lived configurations for a given potential V (φ).…”

Section: Self-interaction Supported Solitonsmentioning

confidence: 99%

“…This lifetime depends sensitively on the scalar potential JHEP06(2021)182 V (φ). For example, a cosine potential leads to a lifetime τ ∼ 10 3 m −1 , whereas some other potentials shown in figure 1 give much longer lifetimes τ 10 12 m −1 [83,85,86]. The formation of such oscillons from cosmological initial conditions (especially in the early universe) has been explored in detail before [87][88][89][90][91], and typically happens when H ∼ m. An almost homogeneous, oscillating condensate naturally fragments into oscillons.…”

Section: Self-interaction Supported Solitonsmentioning

confidence: 99%

Dipole radiation and beyond from axion stars in electromagnetic fields

Amin

Long

Mou

et al. 2021

J. High Energ. Phys.

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We investigate the production of photons from coherently oscillating, spatially localized clumps of axionic fields (oscillons and axion stars) in the presence of external electromagnetic fields. We delineate different qualitative behaviour of the photon luminosity in terms of an effective dimensionless coupling parameter constructed out of the axion-photon coupling, and field amplitude, oscillation frequency and radius of the axion star. For small values of this dimensionless coupling, we provide a general analytic formula for the dipole radiation field and the photon luminosity per solid angle, including a strong dependence on the radius of the configuration. For moderate to large coupling, we report on a non-monotonic behavior of the luminosity with the coupling strength in the presence of external magnetic fields. After an initial rise in luminosity with the coupling strength, we see a suppression (by an order of magnitude or more compared to the dipole radiation approximation) at moderately large coupling. At sufficiently large coupling, we find a transition to a regime of exponential growth of the luminosity due to parametric resonance. We carry out 3+1 dimensional lattice simulations of axion electrodynamics, at small and large coupling, including non-perturbative effects of parametric resonance as well as backreaction effects when necessary. We also discuss medium (plasma) effects that lead to resonant axion to photon conversion, relevance of the coherence of the soliton, and implications of our results in astrophysical and cosmological settings.

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“…Given the rich dynamics of non-linear field theories, we leave a detailed investigation of the properties of the produced oscillons and other localized over-densities in the various potentials that we examined for future work (for recent work on the lifetime of oscillons see refs. [27,49]). Figure 19.…”

mentioning

confidence: 99%

Gravitational wave spectra from oscillon formation after inflation

Hiramatsu

Sfakianakis

Yamaguchi

2021

J. High Energ. Phys.

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We systematically investigate the preheating behavior of single field inflation with an oscillon-supporting potential. We compute both the properties of the emitted gravitational waves as well as the number density and characteristics of the produced oscillons. By performing numerical simulations for a variety of potential types, we divide the analyzed potentials in two families, each of them containing potentials with varying large- or small-field dependence. We find that the shape of the spectrum and the amplitude of emitted gravitational waves have a universal feature with the peak around the physical wavenumber k/a ∼ m at the inflaton oscillation starting period, irrespective of the exact potential shape. This can be used as a smoking-gun for deducing the existence of a violent preheating phase and possible oscillon formation after inflation. Despite this apparent universality, we also find differences in the shape of the spectrum of emitted gravitational waves between the two families of potentials, leading to discriminating features between them. In particular, all potentials show the emergence of a two-peak structure in the gravitational wave spectrum, arising at the time of oscillon formation. However, potentials that exhibit efficient parametric resonance tend to smear out this structure and by the end of the simulation the two-peak structure is replaced by one broad peak in the GW spectrum. We further compute the number density and properties of the produced oscillons for each potential choice, finding differences in the number density and size distribution of stable oscillons and transient overdensities. We also perform a linear fluctuation analysis and use the corresponding Floquet charts to relate the results of our simulations to the structure of parametric resonance for the various potential types. We find that the growth rate of the scalar perturbations and the associated oscillon formation time are sensitive to the small-field shape of a potential while the macroscopic physical properties of oscillons such as the total number depend on the large-field shape of a potential.

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Classical decay rates of oscillons

Cited by 76 publications

References 84 publications

The First Three Seconds: a Review of Possible Expansion Histories of the Early Universe

The First Three Seconds: a Review of Possible Expansion Histories of the Early Universe

Dipole radiation and beyond from axion stars in electromagnetic fields

Gravitational wave spectra from oscillon formation after inflation

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