Pole dark energy

Linder, Eric V.

doi:10.1103/physrevd.101.023506

Cited by 16 publications

(11 citation statements)

References 41 publications

(52 reference statements)

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“…The first equation is close to the results in [83] and the second relation is compatible with the results discussed in [84,86]. The reason why these formulas are precise for different powers of the potential is that the field never rolls for long, thus it cannot see the full shape of the potential 13 .…”

Section: Case B: General Monomial Potentialsupporting

confidence: 87%

Cosmic Birefringence from Monodromic Axion Dark Energy

Gasparotto,

Obata

2022

Preprint

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The recently reported non-zero isotropic birefringence angle in Planck 2018 polarization data provides a tantalizing hint for new physics of axions. In this paper, we explain this by a string theory motivated axion with a monodromy potential that plays the role of dark energy. Upon using the birefringence measurement and the constraint on the equation of state for dark energy in this scenario, we find an upper bound on the axion decay constant as f a 10 16 GeV. This naturally gives an energy scale of order GUT and can resolve the theoretical issue of super-Planckian field range of the conventional axion dark energy model. We further study the implications of cosmic birefringence for the underlying theory and its consequences for the string swampland conjectures. We finally discuss oscillatory features in the dark energy sector and the expected cosmic birefringence tomography.

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Section: Case B: General Monomial Potentialsupporting

confidence: 87%

Cosmic Birefringence from Monodromic Axion Dark Energy

Gasparotto,

Obata

2022

Preprint

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“…Many theoretical models of dark energy have been investigated [6,8], in which dynamical models are very interesting [11][12][13][14][15][16][17][18], because they are related to the field theory associated with the primordial high-energy epoch of the universe and fundamental theories of theoretical physics [6,7,19]. Particularly interesting ones are the dynamical models based on the quantum fluctuations of ultralight scalar fields [12][13][14][15][16][17][18], which reveal an interesting connection to the string axiverse scenario [20][21][22][23][24][25][26].…”

Section: Introductionmentioning

confidence: 99%

“…As in the ΛCDM model and in many models of dark energy, a basic assumption of their property is spatial isotropy and homogeneity, which follows the cosmological principle. Nevertheless, since the late-time expansion of the universe is dominated by dark energy, some interesting outcomes may occur to affect cosmological observables if large-scale inhomogeneities of dark energy arise, which could be tested by various cosmological observations [19,[27][28][29][30].…”

Section: Introductionmentioning

confidence: 99%

Dark energy model with very large-scale inhomogeneity

Nan,

Yamamoto

2021

Preprint

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We consider a dynamical model for dark energy based on an ultralight mass scalar field with very large-scale inhomogeneities. This model may cause observable impacts on the anisotropic properties of the cosmic microwave background (CMB) intensity and luminosity distance. We formulate the model as the cosmological perturbations of the superhorizon scales, focusing on the local region of our universe. Moreover, we investigated the characteristic properties of the late-time evolution of inhomogeneous dark energy. Our numerical solutions show that the model can mimic the standard ΛCDM cosmology while including spatially dependent dark energy with flexible ranges of the model parameters. We put a constraint on the amplitude of these inhomogeneities of the dark energy on very large scales with the observations of the CMB anisotropies. We also discuss their influence on the estimation of the luminosity distance.

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“…Monotonic histories are represented by the single bin treatment named B1, that allows also for step like histories, and the minimal case with a single node with the constraint ṅion t rec = n H at z = a int that restricts reionization to a single burst. For Helium reionization we assume the default hyperbolic tangent provided by the Boltzmann code [55] (note however that the study of Helium reionization is in rapid development [56][57][58]).…”

Section: B Operational Configurationmentioning

confidence: 99%

Dark Twilight Joined with the Light of Dawn to Unveil the Reionization History

Paoletti,

Hazra,

Finelli

et al. 2021

Preprint

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Improved measurement of the Cosmic Microwave Background polarization from Planck allows a detailed study of reionization beyond the average optical depth. The lower value of the optical depth disfavours an early onset and an early completion of reionization in favour of a redsfhit range where different astrophysical probes provide sensible information on the sources of reionization and the status of the intergalactic medium. In this work we extend our previous study in which we constrained reionization by combining three different probes -CMB, UV luminosity density and neutral hydrogen fraction data [1] -in both treatment and data: we first allow variation in the UV source term varying the product of the efficiency of conversion of UV luminosity into ionizing photons and the escape fraction together with the reionization and cosmological parameters, and then we investigate the impact of a less conservative cut for the UV luminosity function. We find that the estimate for the efficiency is consistent within 95% C.L. with the fixed value we considered in our previous results and is mostly constrained by the QHII data. We find that allowing the efficiency to vary does not affect significantly our results for the average optical depth for monotonic reionization histories, recovering τ = 0.0519 +0.0010 −0.0008 at 68 %CL , consistent with our previous studies. Using a less conservative cut for the UV luminosity function, we find τ = 0.0541 +0.0013 −0.0016 at 68 % CL, due to the faint end of the luminosity function in the data we use, that also prefers a larger contribution from higher redshifts.

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Pole dark energy

Cited by 16 publications

References 41 publications

Cosmic Birefringence from Monodromic Axion Dark Energy

Cosmic Birefringence from Monodromic Axion Dark Energy

Dark energy model with very large-scale inhomogeneity

Dark Twilight Joined with the Light of Dawn to Unveil the Reionization History

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