A novel early Dark Energy model
AA novel early Dark Energy model
Luz Ángela García a,b , Leonardo Castañeda c and Juan Manuel Tejeiro c a [email protected] b Universidad ECCI, Cra. 19 No. 49-20, Bogotá, Colombia, Código Postal 11131 c Observatorio Astronómico Nacional, Universidad Nacional de Colombia
A R T I C L E I N F O
Keywords :Cosmology; Dark Energy; Numericalmethods.PACS numbers: 98.80.-k, 95.36.+x, 97.60.Bw
A B S T R A C T
We present a theoretical study of an early dark energy (EDE) model. The equation of state 𝜔 ( 𝑧 ) evolves during the thermal history in a framework of a Friedmann-Lemaitre-Robertson-Walker Uni-verse, following an effective parametrization that is a function of redshift 𝑧 . We explore the evolutionof the system from the radiation domination era to the late times, allowing the EDE model to have anon-negligible contribution at high redshift (as opposed to the cosmological constant that only playsa role once the structure is formed) with a very little input to the Big Bang Nucleosynthesis, and to doso, the equation of state mimics the radiation behaviour, but being subdominant in terms of its energydensity. At late times, the equation of state of the dark energy model asymptotically tends to the fidu-cial value of the De Sitter domination epoch, providing an explanation for the accelerated expansionof the Universe at late times, emulating the effect of the cosmological constant. The proposed modelhas three free parameters, that we constrain using SNIa luminosity distances, along with the CMBshift parameter and the deceleration parameter calculated at the time of dark energy - matter equal-ity. With full knowledge of the best fit for our model, we calculate different observables and comparethese predictions with the standard Λ CDM model. Besides the general consent of the community withthe cosmological constant, there is no fundamental reason to choose that particular candidate as darkenergy. Here, we open the opportunity to consider a more dynamical model, that also accounts forthe late accelerated expansion of the Universe.
1. Introduction
Observations of the luminosity distances of the Super-nova type Ia (SNIa; Riess et al., 2000) revealed that the ex-pansion of the Universe is speeding up at late times. Withinthe cosmological standard model, there is an unknown matter–energy component that contributes by about 70% of the crit-ical density, and this fluid is described as a smooth compo-nent with negative pressure. Although astronomers knowthe effect of this fluid, there is not a clear idea of how todetect it, mainly because it is a smooth component, dilutethroughout all the Universe and the parameter of the equa-tion of state today is most likely 𝜔 = −1 , even if 𝜔 = 𝜔 ( 𝑡 ) in the past.Different models have been proposed in the past years toexplain the nature of this component: the cosmological con-stant Λ that accounts for the quantum vacuum energy (Car-roll, 2001; Peebles and Ratra, 2003), scalar fields with dif-ferent 𝜔 ( 𝑡 ) : Quintessence fields (Ratra and Peebles, 1988;Caldwell et al., 1998; Sami and Padmanabhan, 2003) (withthe state equation 𝜔 = 𝑝 𝑄 𝜌 𝑄 = constant), K–essence (Armendáriz-Picón et al., 1999; Chiba et al., 2000; Armendariz-Picon et al.,2001; Chiba, 2002), Taquionic fields Sen (2002a,b); Gib-bons (2002), phantom fields (Caldwell, 2002; Cline et al.,2004), frustrated topological defects, extra–dimensions, mas-sive (or massless) fermionic fields, galileons, effective para-metrizations of the state equation, primordial magnetic fields,Chaplygin gas (Kamenshchik et al., 2000; Bento et al., 2004),holographic models (Hořava and Minic, 2000), Horndeski’stheory (Clifton et al., 2012), and, early dark energy models ORCID (s): (L.´. García) (Wetterich, 2004; Doran and Robbers, 2006; Khoraminezhadet al., 2020), among others. All these models can be pre-dicted by the Friedmann equations in the framework of Gen-eral Relativity. Instead, modified gravity models impose theaccelerated expansion through a geometrical contribution,rather than an energy density (Faraoni and Capozziello, 2011;De Felice and Tsujikawa, 2010).The current paradigm in the standard model is the Λ CDMmodel, that has only a few free parameters, well-constrainedwith present observations. Nonetheless, the nature of thecosmological constant Λ is still unexplained. One can won-der if it is not more natural that the accelerated expansioncould have been produced by a different smooth field, thatevolves with redshift 𝑧 , having a non-null contribution in theearly Universe and emulating the action of the cosmologicalconstant Λ at late times.During the radiation domination epoch, the abundancesof light nuclei predicted by the Big Bang Nucleosynthesis(BBN Alpher et al., 1948; Gamow, 1946), in particular 𝑌 𝐻𝑒 ,can be used to quantify the degrees of freedom of the radia-tion components in the early Universe (García et al., 2011).At the matter domination era, when matter components arepredominant and structure was formed, baryonic acousticoscillations (BAO) and the anisotropies in temperature ofthe Cosmic Microwave Background also allow astronomersto constrain their dark energy (DE) models, although DE isnot the main contributor of the matter-energy density in thatstage.Additional tests, such as the calculation of the age of the L.A. García et al.:
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Page 1 of 9 a r X i v : . [ a s t r o - ph . C O ] S e p novel early dark energy model Universe or the
Statefinder parameters can tell us the devi-ation from a given DE model from the Λ CDM predictions,and how feasible a DE candidate is in the observed Universe.With the aim to give a plausible explanation of the acceler-ated expansion of the universe, we have proposed a model ofdark energy which has a non–null contribution at early timesto increase the Hubble radius during radiation dominationera and influence the Boltzmann equations that determinethe evolution of the light abundances. All the conditions thatallow us to describe the early dark energy are achieved withthe effective parametrization, which is characterized by itsequation of state that mimics the dominating component.Throughout the paper, we use the cosmological param-eters from the Planck Collaboration (Planck Collaborationet al., 2018) with Ω 𝑚 = ± Ω Λ = ± 𝐻 = ±
042 km s −1 Mpc −1 (or ℎ = Λ effect at late times. Section 3 shows themethod employed to find the best fitting parameters of themodel proposed as a different option to dark en al. In Sec-tion 4, we explore the evolution with redshift of the dark en-ergy density fraction and compare the observables predictedby our model with current cosmological observations. Sec-tion 5 discusses proxies that the model is submitted to con-strain it and compare it with the current paradigm, Λ , in thestandard model. Finally, Section 6 summarizes the findingsof this study and proposes perspectives for DE candidates,which evolution with redshift is not well constrained withobservations yet.
2. Effective parametrization of 𝜔 𝜙 The goal of this work is to study a theoretical prescriptionthat describes dark energy. In order to do so, we make no as-sumption on the nature of the dark energy component in ourmodel, hence, it can be described as a non-interacting perfectfluid that evolves with other components of the plasma in theUniverse, and therefore, it could be supposed as scalar field 𝜙 . We do not discuss further the nature of the DE model butleave open the possibility to link it with a particular scalarfield in the literature.The prospective model takes into account that the Universeis experiencing an accelerated expansion at late times, fol-lowing a De Sitter attractor, hence −1 < 𝜔 𝑑𝑒 < − . As aconsequence, it should be compared with the cosmologicalconstant Λ . Ultimately, the motivation of this work is to findthe physical insight of the current expansion of the Universe,but also to give an alternative to Λ CDM model, since thereis a significantly large difference with the energy of vacuumfluctuations.In addition, we are interested to establish a realization that has a non-negligible contribution during the radiation dom-ination epoch, being subdominant with respect to the radi-ation energy fraction. Therefore, our model could have aninput to BBN, through effective degrees of freedom intro-duced in the Hubble parameter 𝐻 ( 𝑧 ) , as long as this actiondoes not overcome the observational upper limits.A contribution at high redshift ( 𝑧 ∼ ) can be achievedby imposing 𝜔 𝜙 = 1∕3 | 𝑣 𝑟𝑎𝑑 , and the following condition forour DE’ energy density: 𝜌 𝑑𝑒 | 𝑟𝑎𝑑 = 𝑏 ⋅ 𝜌 𝑟𝑎𝑑 ≤ 𝑏 < . (1)with 𝜌 𝑟𝑎𝑑 the radiation energy density. The equation (1) canbe described through the assumption 𝜌 𝑑𝑒 | 𝑟𝑎𝑑 ∝ 𝑎 −4 . As aresult, the early dark energy model would be characterizedby an effective parametrization, that evolves in time, withoutimpacting the hierarchy and chronology of the events in thecosmic history. The parametrization of the equation of state 𝜔 𝑑𝑒 should converge to the limits mentioned above.Different parametrizations have been proposed to describethe evolution of DE and/or a unified dark matter and darkenergy model Davari et al. (2018) or constraints at high red-shift Lorenz et al. (2017). In order to achieve a general solu-tion of the dynamical system established in previous section,we propose an effective parametrization of the state equationvalid up to very high redshift, towards to the Planck time: 𝜔 𝜙 ( 𝑧 ) = 4∕3 ( 𝑧 ∗ 𝑧 ) 𝑚 + 1 − 1 . (2)Here, 𝑚 is a factor that modules the transitions between theattractors, 𝑧 ∗ is a redshift in matter domination epoch definedby: 𝑧 ∗ = 𝑧 𝑒𝑞 + 𝑧 𝑑𝑒 (3)with 𝑧 𝑒𝑞 , the matter–radiation equality and the 𝑧 𝑑𝑒 , the red-shift when the De-Sitter domination (i.e. the accelerated ex-pansion of the Universe stage) begins.The parametrization (2) respects all the conditions previ-ously mentioned, thus, explores an alternative to the Λ CDMcurrent paradigm.The energy density of the dark energy component 𝜌 𝜙 isgiven by: ∫ 𝜌 𝜌 𝑑𝜌 ′ 𝜌 ′ = −3 ∫ 𝑎 (1 + 𝜔 𝜙 ( 𝑎 ′ )) 𝑎 ′ 𝑑𝑎 ′ , (4)integrating (4), it is obtained: 𝜌 = 𝜌 ⋅ (1 + 𝑧 ) ⎡⎢⎢⎢⎣ ( 𝑧 ∗ 𝑧 ) 𝑚 + 1 ( 𝑧 ∗ ) 𝑚 + 1 ⎤⎥⎥⎥⎦ 𝑚 = 𝜌 ⋅ 𝑓 ( 𝑧 ) . (5) L.A. García et al.:
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Page 2 of 9 novel early dark energy model with: 𝑓 ( 𝑧 ) = (1 + 𝑧 ) ⎡⎢⎢⎢⎣ ( 𝑧 ∗ 𝑧 ) 𝑚 + 1 ( 𝑧 ∗ ) 𝑚 + 1 ⎤⎥⎥⎥⎦ 𝑚 . (6)Moreover, the fraction of the dark energy density Ω 𝜙 = 1 − 𝐹 = 𝜌 𝜙 𝜌 𝑐𝑟 : Ω 𝜙 ( 𝑧 ) = 𝜌 𝜌 cr = Ω 𝜙 ⋅ 𝑓 ( 𝑧 )Ω 𝜙 ⋅ 𝑓 ( 𝑧 ) + Ω 𝑚 ⋅ (1 + 𝑧 ) . (7)We remind the reader that we assume a spatially–flat Uni-verse and a Concordance model, hence, Ω 𝜙 +Ω 𝑚 +Ω rad =1 and Ω rad →
3. Best fitting parameters of the model
The formal solution of the parametrization (2) requiresthe estimation of the free parameters of the model {Ω 𝜙 , 𝑚, 𝑧 𝑑𝑒 } ,the fraction of the dark energy density, the module that reg-ulates the transition between the radiation to the De-Sitterdomination eras, and the dark energy domination redshift,respectively. A preliminary inspection of the parameter-spaceshows a large degeneracy between 𝑚 and 𝑧 𝑑𝑒 .We use observations of the luminosity distances of SNIafrom the survey S UPERNOVA C OSMOLOGY P ROJECT U NION , along with the CMB shift pa-rameter 𝑅 CMB and, the condition of the deceleration param-eter equals to zero at 𝑧 = 𝑧 𝑑𝑒 . Adopting 𝑅 CMB in this work,allow us to constrain the free parameters of the model at highredshift, during the matter domination era.We build an MCMC module to find the set of best-fittingparameters to the model. The priors of the model proposedcan be summarized as:• Ω 𝜙 should be strictly positive, [0 , in the Concor-dance model.• Negative values of 𝑚 lead to an inverted transition be-tween the radiation and the De-Sitter attractors (thelatter occurring first than the former), which is notconsequent with the thermal history of the Universe.On the other hand, 𝑚 = 𝑚 is strictly positive in the framework ofthe Standard Model. Furthermore, visual inspectionof the evolution of this parameter shows that 𝑚 > 𝑚 to an instantaneous transition) between the attractors.We discard these values of 𝑚 because they are unlikelyfrom the observational point of view. In fact, the struc-ture was formed during the matter domination epoch,which would not happen if there would not have ex-isted an extended transition between the radiation andDe-Sitter domination eras. • The redshift of matter – dark energy equality, 𝑧 𝑑𝑒 hasalready occurred since the Universe is experiencingan accelerated expansion ⇒ < 𝑧 𝑑𝑒 ≳ D FGRS , 6 D FGS , W IGGLE Z andthe Sloan Digital Sky Survey SDSS .We must break the large degeneracy between 𝑚 and 𝑧 𝑑𝑒 .To do such, as well as to find the best fitting values for {Ω 𝜙 , 𝑚, 𝑧 𝑑𝑒 } set, we use the luminosity distance 𝑑 𝐿 ( 𝑧 ) -equation (8) - andthe distance modulus 𝜇 -equation (9)- are built for our modelto compare these functions with the observational SNIa dis-tance modulus from SCP2.1, with 𝑧 up to 1.4. 𝑑 𝐿 ( 𝑧 ) = 𝑐 (1 + 𝑧 ) 𝐻 ∫ 𝑧 𝑑𝑧 ′ 𝐵 ( 𝑧 ′ ) , (8) 𝐵 ( 𝑧 ′ ) = (Ω 𝜙 𝑓 ( 𝑧 ′ ; 𝑚, 𝑧 ∗ ) + (1 − Ω 𝜙 )(1 + 𝑧 ′ ) ) ,𝜇 = 𝑚 − 𝑀 = 5( log 𝑑 𝐿 ( 𝑧 ) − 1) . (9)As mentioned above, the CMB shift parameter 𝑅 CMB isalso imposed as condition to constrain the set of free param-eters of the model. The function 𝑅 CMB measures the shiftingof the acoustic peaks from from the BAO (Bond et al., 1997;Efstathiou and Bond, 1999) and it is defined as the comov-ing distance between the last scattering surface and today: 𝑅 = (Ω 𝑚 𝐻 ) ∫ 𝑑𝑧𝐻 ( 𝑧 ) , (10)Neither Planck Collaboration et al. (2015) or Planck Collab-oration et al. (2018) calculate directly the value of this pa-rameter, different than the WMAP-7 that inferred the valueof the CMB shift parameter as 𝑅 = 1 .
719 ± 0 . (Pan-otopoulos, 2011). Nonetheless, Huang et al. (2015) use cos-mological parameters from Planck Collaboration et al. (2015)to compute an updated value of 𝑅 = ± 𝑞 ( 𝑧 𝑑𝑒 ) = 0 , i.e. the Universe starts it accelerated expan-sion at the time that the dark energy density overcomes othermatter-energy contributions. Although the deceleration pa-rameter is no longer used in the framework of the Concor-dance model, its definition and solution are quite handy to http://wigglez.swin.edu.au/ L.A. García et al.:
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Figure 1:
Posteriors of our free parameters Ω 𝜙 , 𝑚 and 𝑧 𝑑𝑒 , with shaded 68% intervals, fitting to SNIa luminosity distances datafrom SCP2.1, on top of the simultaneous constraints given by the CMB shift parameter 𝑅 CMB and the deceleration parameter 𝑞 ( 𝑧 𝑑𝑒 ) = 0 . The best values estimated with the MCMC method lay within the prior conditions. With our analysis, we are able torecover the best values of the free parameters: Ω 𝜙 = ± 𝑚 = ± 𝑧 𝑑𝑒 = ± 𝑚 and 𝑧 𝑑𝑒 . narrow down the degeneracy between 𝑚 and 𝑧 𝑑𝑒 . 𝑞 ( 𝑧 𝑑𝑒 ) = 0 with 𝑞 ( 𝑧 ) = (1 + 𝑧 ) 𝜕𝐻𝜕𝑧 − 1 . (11)The best-fitting parameters are obtained with an MCMC mod-ule that takes into account the three conditions previouslydescribed. Figure 1 shows the posteriors of Ω 𝜙 , 𝑚 , and 𝑧 𝑑𝑒 ,and it has been calculated with 3 walkers in the MCMC rou-tine built in python. It converges after 100000 steps aroundthe parameter–space. The 𝑅 CMB constrain at high redshift isdeterminant to break the degeneracy occurring in two of thethree free parameters. The corner plot 1 shows the best fitsto the early dark energy model in blue and then, the 68% in-terval regions allow us to determine the errors of the model. The best estimates for the free parameters of the model andtheir errors are displayed in Table 1, as well as some de-rived parameters relevant to cosmology. We compare thesebest-fitting values with the ones from the Λ CDM model fromPlanck Collaboration et al. (2018).Numerical calculations made with our background model,allow us to report the CMB shift parameter associated 𝑅 cal = + −0 . . The value is slightly larger than the one calculatedby Huang et al. (2015), but as claimed before, our model dif-fers from Λ CDM result, as expected. Besides, 𝑅 dependsstrongly on the factor 𝐻 ( 𝑧 ) , that changes with the modelconsidered. In addition, we remind the reader that we adoptthe Planck Collaboration et al. (2015) cosmological parame- L.A. García et al.:
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Table 1
Summary of the best values of the free parameters of the DEmodel and comparison with the Λ CDM. Column 1: parametername. Column 2: estimates for our model. Column 3: Λ CDMcomparison (Planck Collaboration et al., 2018).
Parameter Our model Λ CDM model Ω 𝜙 ± ± 𝑚 ± 𝑧 𝑑𝑒 ± Ω 𝑚 ± ± 𝜔 -0.976 ± ters for this particular observable, rather than Planck Collab-oration et al. (2018), since the value has not been reportedyet in the literature with the latter cosmological parameters.
4. Evolution of the observables associated tothe DE model
Once the set of free parameters has been constrained withthe MCMC method, the evolution of the dark energy modelis complete and can be studied in the different cosmologicaleras.Figure 2 shows the evolution of the equation of state 𝜔 asfunction of 𝑧 . The early DE model emulates radiation du-ring this epoch and then, it evolves to the De-Sitter era. Atlate times, our theoretical description emulates the cosmo-logical constant. In fact, dark energy relaxes to the asymp-totic Λ CDM model during De-Sitter epoch. The blue curveshows the equation of state for our model, and the dashedlines represent the upper and lower limits imposed by theerrors of the set of parameters {Ω 𝜙 , 𝑚, 𝑧 𝑑𝑒 } and the shadedcyan region display the possible range where 𝜔 ( 𝑧 ) can evolveinside the error bars.On the other hand, Figure 3 presents the behaviour of 𝑓 ( 𝑧 ) . This function characterizes the evolution of the darkenergy density in our model. During radiation dominationepoch, the field scales as radiation 𝜌 ∝ (1 + 𝑧 ) until 𝑧 𝑒𝑞 .After that, 𝜌 has a complex behaviour which guarantees thelate convergence to accelerated expansion. At this point,the model evolves asymptotically to −1 (as the cosmolog-ical constant). At 𝑧 =
0, the function 𝑓 ( 𝑧 = 0) =
1, byconstruction, indicating that the dark energy density of thefield is dominant over matter and the dark energy candidatesatisfies the current observations and is in agreement withthe predictions from the Concordance model.The evolution of the dark energy density fraction is shownin Figure 4. In the plot, it is possible to distinguish that Ω 𝜙 = 𝑧 ), the en-ergy density of the field decreases, being subdominant dur-ing matter and radiation epoch, as imposed by constructionwith the parametrization of the equation of state. Nonethe-less, the value of the energy density fraction of the modelhas a non-negligible contribution of the field energy density. Figure 2:
Equation of state 𝜔 ( 𝑧 ) as a function of redshift 𝑧 .The parameterization is valid up to the Planck time. The blueline represents the equation of state of the field, the dashedlines show the upper and lower limits of 𝜔 ( 𝑧 ) , whereas the cyanregion displays all the possible values that the equation of statecould take inside the parameter-space allowed within the errorbars. The purple line shows a comparison of the evolution ofthe equation of state in the case of the Λ CDM model.
Moreover, we analyse the luminosity distance in our modelwith the best fitting parameters found in the previous section.Figure 5 displays the distance modulus in our model in a blueline (with the boundaries inside the parameter-space in bluedashed lines), the prediction with the Λ CDM model in ma-genta. To complement the study, we plot the observations ofSNIa from SCP2.1 in black points with their correspondingerrors.The predictions for the distance modulus of Λ CDM and theEDE models lay quite close, especially at high redshift, andboth are below the observations from 𝑧 ∼
1. Interestingly,both models fit very well at low redshift, when the luminos-ity distance grows linearly with redshift, independently ofthe model chosen.It is worth mentioning that the Λ CDM standard model wasoriginally fitted to the data with WMAP-7 cosmological pa-rameters, but with current cosmology, and particularly, thevalue for 𝐻 , there is a slight discrepancy with SCP2.1 dataat redshifts higher than 1.Additional analysis is carried out with measurements of 𝐻 ( 𝑧 )∕(1+ 𝑧 ) vs. 𝑧 and our model prediction. Figure 6 drawsa comparison among our model (blue solid line) with BAOobservations from BOSS DR12 from Alam et al. (2017) inyellow diamonds, from BOSS DR14 quasars by Zarrouk et al.(2018) in the pink inverted triangle, BOSS DR14 Ly 𝛼 auto-correlation at 𝑧 = 𝛼 auto-correlation and cross- L.A. García et al.:
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Figure 3:
Dark energy density factor 𝑓 ( 𝑧 ) as a function ofredshift 𝑧 . The factor grows with redshift, differently from theevolution of the dark energy density Ω 𝜙 . The blue continuousline shows the evolution of 𝑓 ( 𝑧 ) , whereas the dashed lines theupper and lower limits of the function inside the error barsof the parameters. The cyan shaded region, all the possiblevalues of 𝑓 ( 𝑧 ) within the parameter-space. correlation with quasars from Blomqvist et al. (2019) in thedark red square. All the previous observations have com-puted with Planck Collaboration et al. (2018) cosmologicalparameters. Finally, the inferred Hubble measurement todayfrom Riess et al. (2019) is shown with the cyan right tiltedtriangle. Λ CDM is plotted as a reference in a magenta line.
5. Standard Cosmological Probes
Age of the Universe with this model
The age of the Universe for a given model in a standardcosmology is given by the expression: 𝑡 = 1 𝐻 ∫ ∞0 𝑑𝑧 ′ (1 + 𝑧 ′ ) √ Ω 𝜙 ⋅ 𝑓 ( 𝑧 ) + Ω 𝑚 ⋅ (1 + 𝑧 ) , (12)In our model, with the parameters in Table 1, the calculatedage of the Universe is: 𝑡 = 13 .
441 ± 0 . Gyr . (13)As an important remark, (13) is only an approximation ofthe age of the Universe today, since the parametrization (2)needs further constraints with high redshift observables. How-ever, the result is quite outstanding, taking into account thatour model differs significantly at high redshift from the stan-dard one. Figure 4:
Dark energy density fraction Ω 𝜙 with redshift 𝑧 .The blue line presents the evolution of the energy density ofthe field. The dashed lines show the upper and lower limitsof the dark energy density inside the error bars of the parame-ters. Within these boundaries, in the cyan shaded region, thepossible values of Ω 𝜙 within the parameter-space. It is worthnoticing that at 𝑧 ∼ , Ω 𝜙 raises from a value close to zero,indicating that our model is an EDE and it energy density frac-tion could contribute with some effective degrees of freedomin the Hubble parameter at radiation domination era. One way that the result can be interpreted is that the exis-tence of early dark energy makes the Universe evolve fasterthan in the standard model. In this picture, the more negative 𝜔 is, the more accelerated is the expansion. Also, the Uni-verse is “younger” if the dark energy component is preciselythe one here proposed, given a value of 𝐻 . Statefinder parameters
In order to distinguish between a dark energy model and Λ CDM, Gao and Yang (2010) proposes a test using the
Sta-tefinder parameters, defined as: 𝑟 = 1 + 92 Ω 𝜙 𝜔 𝜙 (1 + 𝜔 𝜙 ) − 32 Ω 𝜙 ̇𝜔 𝜙 𝐻 , (14) 𝑠 = 1 + 𝜔 𝜙 − 13 ̇𝜔 𝜙 𝐻𝜔 𝜙 , (15)The values of these parameters with the Standard model are { 𝑟, 𝑠 } = {1 , −1} today (i.e. at 𝑧 = Λ CDM, and the departureof the former and the latter models in the space parameterat 𝑧 = Statefinder space. The purple square andthe golden star represent the Λ CDM and our DE model to-day, respectively. The black line shows the evolution of ourmodel from the past ( { 𝑟, 𝑠 } = {0 , ) to the future ( 𝑟 > L.A. García et al.:
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Figure 5:
Distance modulus vs. redshift 𝑧 computed withour model and Λ CDM. We compare the theoretical predictionswith observational data of SNIa from SCP2.1. We present ourmodel, Λ CDM and SNIa from SCP release in the blue line,magenta line and black points, respectively. 𝑠 < 𝑧 =
0, however, the equation of statehas not reached the value 𝜔 𝜙 = − Λ CDM, becausethe prediction of the values Ω 𝑚 , Ω 𝜙 and 𝑧 ∗ slightly differfrom the standard model. Nevertheless, as discussed alongthis section, the equation of state relaxes and tends to Λ CDMmodel, once the field reaches the de-Sitter era.
6. Conclusions and perspectives
We have proposed a model of dark energy that causes anaccelerated expansion of the Universe at late times, but also,has a non-negligible contribution during the radiation dom-ination epoch. This dark energy candidate evolves from aradiation domination era to the De-Sitter time and emulatesthe behaviour of the cosmological constant. The propertiesof the dark energy component and it evolution in time (orredshift) have been extensively discussed, using an effectiveparametrization of the equation of state of the perfect fluidthat could describe a scalar field.Using distance modulus of SNIa up to 𝑧 ∼ 𝑅 CMB and, the condition of thedeceleration parameter equals to zero at 𝑧 = 𝑧 𝑑𝑒 , we con-strained the free parameters of our model: Ω 𝜙 , the dark en-ergy density of the field today, 𝑚 , a factor that modules thetransition between the radiation to the dark energy domina- Figure 6:
Prediction for 𝐻 ( 𝑧 )∕(1 + 𝑧 ) as a function of 𝑧 . Wecompare our model (blue solid line) with Λ CDM model (ma-genta solid line) and BAO observations derived with BOSSDR12 from Alam et al. (2017) in yellow diamonds, from BOSSDR14 quasars by Zarrouk et al. (2018) in the pink invertedtriangle, BOSS DR14 Ly 𝛼 autocorrelation at 𝑧 = 𝛼 auto-correlation and cross-correlation with quasars fromBlomqvist et al. (2019) in the dark red square. All the pre-vious observations have computed with Planck Collaborationet al. (2018) cosmological parameters. The inferred Hubblemeasurement at 𝑧 = tion era, and, 𝑧 𝑑𝑒 , the redshift when the Universe reachesthe De-Sitter era and its energy density overtakes the matterdensity (ending up the matter domination era).The complete solution of the parametrization allows us tostudy the dynamical evolution of the equation of state andthe associated energy density fraction of the EDE candidate.Also, with the proposed method, we break the inner degen-eracies among the free parameters.Ongoing work will impose additional constraints on themodel by computing the energy density of the field duringradiation, when the Universe is about a few minutes old, tostudy Big Bang Nucleosynthesis (BBN) and inferred param-eters at this time. BBN is a well defined cosmological probethat can be used to rule out alternative models of dark matterand energy. Our model would not struggle in this cosmo-logical regime since its energy contribution during radiationdomination era is quite a subdominant, but non-negligible,therefore, it can play an important role as an effective degreeof freedom of energy in the Hubble factor.Future efforts will be also focused on the most generalfamily of solutions for the equation of state 𝜔 ( 𝑧 ) , using Heav- L.A. García et al.:
Preprint submitted to Elsevier
Page 7 of 9 novel early dark energy model
Figure 7:
Statefinder parameters space. The set of parameterstoday for Λ CDM is presented with a purple square { 𝑟, 𝑠 } ={1 , −1} , while the values for our DE model are shown with thegolden star. The black line exhibits the evolution with redshiftof the Statefinder parameters given our model. The effectiveparametrization evolves from high redshift (early times) in theright lower side to the future in the left upper corner. iside step functions, that move between the cosmologicaldomination epochs, and in the case of study, from the radi-ation to the De-Sitter era, satisfying different observationalproxies. One of the crucial questions that arise with the in-troduction of these kind of equations for 𝜔 𝜙 is the nature ofdark energy and the interpretation of the energy density asso-ciated with the field 𝜌 𝑑𝑒 ( 𝑧 ) = 𝜌 𝑑𝑒 exp [ ∫ 𝑧 𝑧 ′ (1+ 𝜔 ( 𝑧 ′ )) 𝑑𝑧 ′ ] .Finally, our goal is to fully understand if these alterna-tive models for dark energy are competitive candidates to ex-plain the accelerated expansion of the Universe at late times,avoiding the discrepancies that appear with the cosmologicalconstant Λ , the fine-tuning after inflation and an unnecessarynumber of free parameters that have no physical interpreta-tion. Our model has shown to provide compelling results asan early dark energy model. Ultimately, it seems about natu-ral to have an evolving equation of state in the cosmologicalcontext, hence this study makes progress in this direction. Acknowledgments
This work was partly supported by the Observatorio As-tronómico Nacional from Universidad Nacional de Colom-bia. L.A. García thanks Universidad ECCI for its funding.
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