Eur. Phys. J. C manuscript No. (will be inserted by the editor) A complete cosmological scenario from f(R,Tφ) gravity theory P.H.R.S. Moraesa,1, J.R.L. Santosb,2 1ITA- InstitutoTecnolo´gico deAerona´utica - Departamento deF´ısica, 12228-900, Sa˜o Jos´e dos Campos, Sa˜o Paulo, Brazil 2UFCG - UniversidadeFederal deCampina Grande- Departamento deF´ısica, 58109-970, Campina Grande, Para´ıba, Brazil 6 1 0 Received: date /Accepted: date 2 n a Abstract Recent elaborated by T. Harko and collab- second after the Big-Bang, named “inflationary era”. J orators,the f(R,T)theories of gravitycontemplate an It is common to describe this phenomenon via scalar 2 optimistic alternative to dark energy, for which R and fields [1]-[7], although another reputed form to do so 1 T standfortheRicciscalarandthetraceoftheenergy- comes from the f(R) gravity [8]-[11]. ] momentumtensor,respectively.Althoughtheliterature Recently, a more general theory of gravity, named c q has shown that the T dependence on the gravitational f(R,T) gravity,was proposed by T. Harko and collab- - part of the action - which is due to the considera- orators[12].A priori itcanalsocontributetoinflation- r g tion of quantum effects - may induce some novel fea- aryerastudiesthroughitsscalarfieldapproach,named [ tures in the scope of late-time cosmological dynamics, f(R,Tφ) gravity [12]. 1 in the radiation-dominated universe, when T = 0, no Although the late time acceleration of the universe v contributions seem to rise from such theories. Appar- expansion[13]-[15]hasbeenbroadlyinvestigatedinsuch 1 ently, f(R,T) contributions to a radiation-dominated a theory of gravity [16]-[25], the inflationary era still 1 universe may rise only from the f(R,Tφ) approach, presents a lack of examination. The same happens for 8 2 which is nothing but the f(R,T) gravity in the case of the radiation-dominatedera of the universe. 0 a self-interactingscalarfieldwhose traceofthe energy- For the radiation era, the lack of f(R,T) applica- 1. momentum tensor is Tφ. We intend, in this article, to tions is quite predictable for the following reason. The 0 show how f(R,Tφ) theories of gravity can contribute equation of state (EoS) of the universe is p = ρ/3 6 to the study of the primordial stages of the universe. at this stage, with p and ρ representing the pressure 1 Our results predict a graceful exit from inflationary and density of the universe, respectively. Such an EoS : v stagetoaradiation-dominatedera.Theyalsopredicta yields a null trace for the energy-momentum tensor of i X late-time cosmic accelerationafter a matter-dominated a perfect fluid. A null trace for the energy-momentum phase, making the f(R,Tφ) theories able to describe, tensor yields the f(R) formalism for the f(R,T) func- r a in a self-consistent way, all the different stages of the tionalformsfoundintheliterature(check,forinstance, universe dynamics. [12],[16]-[25]). Hence the study of the radiation era of theuniverseinf(R,T)gravityseemstobequitetricky. Keywords f(R,T) gravity self-interacting scalar · Apriori,itseemsreasonabletoaffirmthatthef(R,T) field primordial stages of the universe · gravitydoesnotcontributetothestudyoftheradiation- dominateduniverse,sincethecontributioncomingfrom the trace of the energy-momentum tensor in f(R,T) 1 Introduction vanishes at this stage. Specifically, such a shortcoming orincompletenesshasattractedattentionrecently[23]- Plentyofeffortshavebeenmadeinthetheoreticalframe- [26]. work with the purpose of explaining the accelerated In [23], the authors argued that the high redshift regime our universe has passed through a fraction of f(R,T)cosmologicalsolutionstendtorecoverthestan- ae-mail: [email protected] dardmodelofcosmologyifthef(R,T)functionalform be-mail: [email protected] is linear in R precisely because when z >>1, the radi- 2 ationwithEoSp=ρ/3dominatestheuniversedynam- throughout this article we will assume units such that ics, making the trace of the energy-momentum tensor 4πG = c = 1. Moreover, we are going to deal with tovanish.Therefore,nonovelcontributionswouldcome a standard Lagrangian density for a real scalar field, fromthef(R,T)theoriesofgravitationattheradiation whose form is era. 1 = ∂ φ∂µφ V(φ), (2) In[24],inordertomakef(R,T)gravitytheoryable L 2 µ − to contribute also to a radiation-dominateduniverse,a for which it has been considered a self-interacting po- compactified space-like extra dimension had to be in- tential V(φ). voked. Furthermore,since the energy-momentumtensor of In [25], with the purpose of obtaining well behaved the scalar field is given by solutions at the radiation stage of the universe, the ∂ f(R,T) gravity was generalized, by allowing the speed Tφ =2 L g , (3) µν ∂gµν − µνL of light c to vary. Moreover, a scenario alternative to inflation was obtained. its trace is Bydevelopingthef(R,Tφ)approach,whichissub- Tφ = ∂ φ∂µφ+4V(φ). (4) missivetof(R,T)gravity,weintend,here,tomakethe µ − f(R,T) theories able to contribute also to inflationary The f(R,Tφ) = R/4 + f(Tφ) gravity model is and radiation-dominated eras, in a self-consistent way. − defined in the following form: Recall that once T = 0 at the radiation stage, it is natural to expect that f(R,T) theories retrieve f(R) S = d4x√ g R +f(Tφ)+ (φ,∂ φ) , (5) µ gravityorevengeneralrelativity(GR)whenf(R) R, − −4 L ∼ Z (cid:20) (cid:21) in such a way one would not expect any new informa- forwhichwehaveinsertedthe gravitationalpartofthe tionsderivedfromf(R,T)gravity.Tomakethef(R,T) action. By minimizing the above action, we obtain gravity able to describe a radiation universe by itself, G =2[T g f(Tφ) 2f′(Tφ)∂ φ∂ φ], (6) withoutnecessarilyrecoveringthe f(R)formalismout- µν µν µν µ ν − − comes,willmakesuchatheoryabletocontributetoall whereG istheEinsteintensorandf′isthederivative µν the different stages of the universe dynamics. In order of f(Tφ) with respect to Tφ. to do so, we will implement the first-order formalism Fortheaction(5),aflatFriedmann-Robertson-Walker [27,28] to the f(R,Tφ) gravity. universe has the following Friedmann equations: We will not omit the recent dynamical features our 3 1 universehaspresented.Inotherwords,alate-time cos- H2 = 2f′(Tφ) φ˙2 f +V , (7) 2 2 − − mic acceleration,which is corroboratedby Type Ia Su- (cid:20) (cid:21) pernovae observations [13,14] and described in ΛCDM 3 φ˙2 cosmologybythepresenceofthecosmologicalconstant H˙ + H2 = +f(Tφ) +V , (8) 2 −" 2 # in standard Einstein’s field equations (FEs), shall also be described in our model. in which φ = φ(t), H = a˙/a is the Hubble parameter, a is the scale factor and dots denote derivation with respect to time. 2 The f(R,Tφ) Gravity We are also able to derive the equation of motion for such a system, which is given by Earlyandlatetimeaccelerationsoftheuniverseexpan- sion can be explained in the framework of scalar field [1 2f′(Tφ)](φ¨+3Hφ˙) (9) − models [1]-[7], [29]-[35]. The consideration of f(R,T) 2f˙′(Tφ)φ˙ +[1 4f′(Tφ)]V =0, φ gravity in the case of a self-interacting scalar field φ − − yields the f(R,Tφ) gravity [12]. where it was used the notation Vφ dV(φ)/dφ. ≡ Herewewillworkwiththecasef(R,Tφ)= R/4+ − f(Tφ), for which R stands for the Ricci scalar, while 3 First-Order Formalism Tφ is the trace of the energy-momentum tensor of the scalar field, so that Letusimplementthefirst-orderformalismtothemodel above,byfollowingtherecipepresentedin[27,28].Firstly Sφ = d4x√ g (φ,∂ φ) (1) − L µ it is straightforward to observe from (7) and (8) that Z the Hubble parameter obeys the differential equation is the action of such a field, with g being the deter- minant of the metric with signature (+, , , ) and H˙ = (1 2f′) φ˙2. (10) − − − − − 3 Then, the initial ingredient that we may consider in Here,foramatterofsimplicity,wefocusonthecase order to establish the first-order formalism is based on n=1, which leads to the definition φ˙ W , (11) ′ φ f =α. (19) ≡− with W dW(φ)/dφ and W is an arbitrary function φ ≡ of the field φ. Such a procedure is commonly used in Then, by substituting f′ in Eq.(14), we find cosmologicalscenarioscoupled with scalarfields, as we mayseein[29]andreferencestherein.Thisassumption implies that (10) is rewritten as h(φ)=(1 2α)a1 sin φ, (20) − H˙ = (1 2f′) W2. (12) − − φ which means that If we establish that H h(φ)+c, (13) ≡ H =(1 2α)a sin φ+c. (21) 1 where c is a real constant, then, Eq.(10) requires the − following constraint to the function h: Moreover, it is straightforward to obtain that the po- ′ h =(1 2f )W . (14) φ φ tential V is − Moreover,theFriedmannequationsimposethatthepo- tential V(φ) has to obey the relation 3 [(1 2α)a sin φ+c]2 1 α a2cos2 φ V = 2 − 1 − 2 − 1 .(22) 3 1 1 4α V = (h+c)2+f 2f′ W2. (15) − (cid:0) (cid:1) 2 − 2 − φ (cid:18) (cid:19) FromEq.(18)one cansee thatthe first-orderdiffer- 3.1 Examples ential equation for this scenario has the form We can apply the first-order formalism by consider- ing a specific form for the function f(Tφ). As in [28], φ˙ = a cos φ, (23) 1 let us deal with f(Tφ) = α(Tφ)n, with α as a con- − stant and n as an integer. Note that such a functional form for f(Tφ) straightforwardly yields the GR case whose analytical solution is when α = 0. Moreover, it is the analogous of the form f(T)=αTn in the f(R,T) gravity with no scalar field φ(t)=2tan−1 tanh 1(b a t) , (24) case, firstly suggested in [12] for deriving an acceler- 2 1− 1 (cid:26) (cid:20) (cid:21)(cid:27) ated cosmologicalscenario and then applied to a num- berofotherf(R,T)well-behavedcosmologicalmodels, such as [18,19], [24,25], among many others. Such an with b being a real constant. The previous solution 1 assumption yields allows us to rewrite Eq.(21) as f(Tφ)=α φ˙2+4V n =α W2+4V n , (16) − − φ f′ =αn (cid:16)φ˙2+4V n(cid:17)−1 =αn(cid:0) W2+4V(cid:1) n−1.(17) H =(1−2α)a1 tanh(b1−a1t)+c, (25) − − φ Inthis(cid:16)study,wea(cid:17)regoingtoc(cid:0)onsiderthat(cid:1)thefunc- whichispresentedindetailsintheupperpanelofFig.1 below, where we can see that H exhibits a kink-like tion W is given by profile as a direct consequence of the model defined in W(φ)=a1 sin φ, (18) Eq.(18). with a1 being a real constant. Such a form for W(φ) is We can use the last result to determine the expan- a sine-Gordon type of model, and it has been broadly sion parameter (or scale factor) a(t), whose explicit studied in the literature, specially in investigations re- form is given by lated with classical field theory, as one can see in [36] and references therein. Very recently, this model was a=ect [sech(b a t)](1−2α) . (26) applied in the context of braneworld scenarios for the 1 1 − f(R,T) gravity [28]. 4 Moreover,the analytical EoS parameter is [12(α 2)α+7] a2 3 (1 2α)2a2+c2 cosh[2(b a t)]+6(2α 1)a c sinh[2(b a t)] 3c2 ω = − 1− − 1 1− 1 − 1 1− 1 − , (27) [4(2 3α)α 3]a2+3[(1 2α)2a2+c2] cosh[2(b a t)]+6(1 2α)a c sinh[2(b a t)]+3c2 − − 1 (cid:2) − 1 (cid:3) 1− 1 − 1 1− 1 and its features can be observed in the central panel The last equation results in the following relation for of Fig.1. We can verify from the analytical cosmolog- the Hubble parameter ical parameters that small deviations on the values of theconstantsproducecosmologicalscenarioswhichare a1 H(t)=c (1 2α) 3sinh(a t+b ) (32) 1 1 similar to those presentedin Fig.1. Therefore,the time − 6 − (cid:26) evolution of our parameters are not so strongly depen- +sinh[3(a t+b )] sech3(a t+b ), dent on the initial conditions of the model. 1 1 1 1 (cid:27) Another interesting model is whichispresentedindetailsintheupperpanelofFig.2 φ3 below. As in the previous example, it is possible to W(φ)=a φ , (28) 1 3 − choosethearbitraryconstantsinordertoobtainakink- (cid:18) (cid:19) like profile for H. whose first-order differential equation is such that We can also show that the potential V for this an- φ˙ =a 1 φ2 , (29) alytical model is 1 − which is(cid:0)satisfie(cid:1)d by V = 1 1 (1 2α)a φ φ2 3 +3c 2 (33) 1 1 4α 6 − − φ=tanh(a1t+b1), (30) −1 α(cid:26) a(cid:2)2 φ2 1 2 .(cid:0) (cid:1) (cid:3) whereb isarealconstant.Thislastfirst-orderdifferen- − 2 − 1 − 1 (cid:18) (cid:19) (cid:27) tial equation representsthe so-calledφ4 type of model, (cid:0) (cid:1) Withal, the expansion parameter for such a case is which is also broadly investigated in classical field the- given by the following ory, as one can see in [37] and references therein. In the present case, we are dealing with f(Tφ) = 1 αTφ again.Therefore,wecancombinethepreviousin- a=exp ct+ (1 2α)sech2(a t+b ) (34) 1 1 6 − gredients to determine the following form for the func- (cid:20) (cid:21) tion h(φ): [cosh(a t+b )]32(2α−1) , 1 1 × φ2 while the EoS parameter reads h=(1 2α)a φ 1 . (31) 1 − 3 − (cid:18) (cid:19) ω = 1+192(1 4α)a2cosh2(a t+b ) 8[4α(5α 2)+5]a2+3 4(4(α 3)α+1)a2+45c2 cosh[2(a t+b )] − − 1 1 1 − − 1 − 1 1 1 (cid:26) + 6 4(1 2α)2a2+9c2 cosh[4(a t+b )]+16α2a2 cosh[6(a t+(cid:2)b )] 16αa2 cosh[6(a t+(cid:3)b )] − 1 1 1 1 1 1 − 1 1 1 + 4a2 cosh[6(a t+b )]+9c2 cosh[6(a t+b )]+216αa c sinh[2(a t+b )]+144αa c sinh[4(a t+b )] (cid:2)1 1 1 (cid:3) 1 1 1 1 1 1 1 1 −1 + 12(2α 1)a c sinh[6(a t+b )] 108a c sinh[2(a t+b )] 72a c sinh[4(a t+b )]+90c2 . (35) 1 1 1 1 1 1 1 1 1 − − − (cid:27) 5 ThelatterisplottedinthecentralpanelofFig.2.Again, it is worth checking if the cosmological parameters de- if we take small deviations of these parameters we de- rived previously indeed resemble, for small values of termine similar cosmological scenarios. time, what is expected for the primordial universe dy- namics. Intheprevioussectionwehavealsoplottedtheevo- 2 lution of the trace of the energy-momentum tensor of the scalar field, which shall be interpreted below. 1.5 The inflationary model states that early in the his- toryoftheuniverse,itsexpansionhasaccelerated.From H 1 standardFriedmannequations,this happensifthe uni- verseisdominatedbyacomponentwithEoSω < 1/3 0.5 − [38,39].Accordingto standardcosmology,duringinfla- tion, the energy density of the universe was dominated 0 by a constant, say, Λ , in such a way the Friedmann 0 5 10 15 20 25 ι equations read H2 Λ . The Hubble parameter was, t ι ∼ ι 0.4 0.2 0 2.5 -0.2 Ω 2 -0.4 -0.6 1.5 H -0.8 1 -1 0 5 10 15 20 25 30 0.5 t 0 0 5 10 15 20 25 4 t 0.4 3 0.01 0.2 Φ 0.005 0 T 2 -0.2 0 Ω 1 15 20 25 30 -0.4 -0.6 0 -0.8 0 5 10 15 20 25 30 -1 t 0 5 10 15 20 25 30 35 t Fig. 1 The upper panel shows the evolution of H(t), the central panel shows ω, and the lower panel shows Tφ, for 2 α = −1, a1 = 0.3, b1 = 3, and c = 0.988, in the W(φ) = 0.01 a1 sinφ model. 1.5 0.005 Φ T 1 0 15 20 25 30 35 0.5 4 Cosmological Interpretations 0 In Section 3, we were able to depict the time evolution 0 5 10 15 20 25 30 35 of H and ω derived from the first-order formalism ap- t plied to the f(R,Tφ) theory. Remind that our aim in this work is to make f(R,T) gravity able to induce a Fig. 2 The upper panel shows the evolution of H(t), the complete cosmologicalscenario,whichincludesthe pri- central panel shows ω, and the lower panel shows Tφ, for mordial eras of the universe, since the theory seems to α = −4, a1 = 0.2, b1 = −2.5, and c = 1.31, in the W(φ) = present some shortcomings at these stages. Therefore, a1(φ3/3−φ)model. 6 then,constantduringinflationaryera.Indeed,onemay Firstly, one can note that the values assumed by write, for inflation, aι eHιt [38,39]. sucha quantity are always 0,as they, indeed, should ∼ ≥ be. From the upper panels of Figs.1-2, the Hubble pa- The high values of density and temperature which rametervaluespredictedfromourmodelindeedremain are known to characterize the Big-Bang,together with approximately constant during a small period of time the inflationary EoS mentioned above, make us to ex- after the Big-Bang,in agreementwith inflationary sce- nario. In fact, H˙ 0.003 and 0.0003 at t = 0.01 pect to have the maximum values of the trace of the ∼ − ∼ − energy-momentum tensor of the scalar field during in- for Figs.1 and 2, respectively. flation, as corroboratedby Figs.1-2. Afterinflation,H mustevolveas t−1,witht be- ∝ H H At the radiation era, Tφ must vanish. We zoomed ingthe Hubble time [38,39],inaccordancewithFigs.1- in on Figs.1-2 lower panels in order to explicit such a 2. predictedfeature.Notethatafteraperiodassumingits StillintheupperpanelsofFigs.1-2,oneshouldnote maximum values, the trace of the energy-momentum that for high values of time, H behaves once again as tensor Tφ 0 at the same time scale ω 1/3 in → → a constant. From standard cosmology, it is well known Figs.1-2 central panels. Such a property reinforces the that for high values of time, H is proportional to ρΛ goodbehaviour of our solutions, specifically at the pri- (the densityofthe cosmologicalconstant),whichis,in- mordial stages of the universe evolution. deed, a constant. Therefore, the recent cosmic acceler- At matter-dominated era, Tφ must be = 0. The 6 ation our universe is undergoing can be described by a samehappensforthe secondperiodofacceleration.In- scalefactorwhichevolvesaseH0t,withtheconstantbe- deed,the plots ofTφ show that after the radiationera, haviourofH beingpredictedinFigs.1-2forhighvalues Tφ increasesits values.Still, suchvaluesare small,due of time. to the low density of the universe at these stages, spe- In the central panels of Figs.1-2, we have depicted cially when compared to the ρ values at inflation. the evolution of the EoS parameter ω with time. By Remarkably,Tφ remainsconstantforhighvalues of analysing it, one can see that for small values of time, time.SinceTφ ρ,thischaracterizesthelate-timeuni- ∝ ω 1. This is in agreement with some constraints verse dynamics to be dominated by a constant. Recall tha∼t h−ave been put to inflationary EoS recently [40]- thatinstandardcosmology,forhighvaluesoftime,the [42]. cosmologicalconstantΛdominatestheuniversedynam- ics. As argued above, ρ remains, indeed, constant as Λ After representing inflation, ω smoothly evolves to time passes by. Such an important feature of standard 1/3. This is the maximum value the EoS should ∼ cosmologyispredictedfromthef(R,Tφ)approachhere assume during the universe evolution. Moreover, 1/3 presented. is precisely the value of the EoS which describes the radiation-dominatederaoftheuniverse[38,39],i.e.,the model predicts a smooth transition from inflationary 5 Discussion and perspectives stage to radiation-dominated era. In this article we established a first-order formalism to As time passes by, the central panels of Figs.1-2 determinetwoanalyticalmodelsrelatedtothef(R,Tφ) show that ω 1. According to recent observations → − theory.Suchaformalismwasconstructedfromthedef- ofanisotropiesinthe temperatureofcosmicmicrowave inition observed in Eq.(11). background radiation [15], this is the present value of ThementionedexpressiontogetherwithEq.(7)and the universe EoS, and is responsible for the recent cos- (13) gave us a constraint for the potential V, which mic acceleration. canbeviewedin(15).Moreover,thearbitraryfunction Thefactthatnowadaystheuniverseispassingthrough h(φ) was introduced and its form is directly related to its second phase of acceleratedexpansion justifies such ′ f . an evolution for ω. Since an accelerated universe is de- The firstanalyticalmodelwas generatedbyconsid- scribedbyanegativeEoS,itisexpectedthatduringthe ering W = a sin φ and the specific form for f(Tφ) 1 whole universe evolution, the value of ω, coming from showedin(16).Suchdefinitionsleadedusto determine 1,whichisrelatedtotheinflationarystage,firstin- h(φ), besides the potential V, the Hubble parameter ∼− creases,tendingtoadeceleratingphase,thendecreases, H, as well as other cosmologicalquantities like the ex- returning to an accelerated phase. pansion and EoS parameters. In the second case, we Furthermore, the lower panels of Figs.1-2 show the adopted W = a (φ3/3 φ), and one more time we 1 − time evolution of the trace of the energy-momentum determinedthefunctionhandthecosmologicalparam- tensor of the scalar field for the models. eters for the model. 7 We can directly see that the field φ(t) satisfies the cosmicaccelerationtheuniverseisundergoing[13]-[15], equation of motion (9) for both models. Furthermore, from an EoS parameter whose late-time values agree this first-order formalism may help us to obtain other with WMAP cosmic microwave background observa- one-field analytical scenarios and also may lead us to tions [15]. hybridanalyticalmodels,whereitisconsideredthecou- Therefore, departing from a cosmological scenario pling betweenanf(R,Tφ,χ) function with a two scalar derivedfromGR,wehaveobtainedanEoSwhichvaries field Lagrangian. Such a scenario shall be derived and withtime, allowing,throughits evolution,the universe presented in near future. dynamics to be dominated by different components in Another further work may rise from an alternative a natural form. Moreover, in order to obtain a recent formforf(R,Tφ),suchasf(R,Tφ)=g(R)h(Tφ),with cosmicacceleration,we did nothave to inserta cosmo- g(R) and h(Tφ) being functions of R and Tφ, respec- logicalconstant in the model FEs, in this way, evading tively. Such a functional form suggests a high coupling the cosmologicalconstant problem [49,50,51]. betweenmatterandgeometry,andthereforemayimply The f(R,Tφ) cosmological scenario derived in this some novelties in gravitational and cosmological per- work is somehow similar to a decaying vacuum Λ(t) spectives.Wecanconjecturethatbycouplingsuchkind model, such as those presented in [45,46], for instance. oftheorieswithascalarfieldlagrangianmayleadusto Firstly, it should be stressed that recently in [26], the anewsetofFriedmannequationsandtodifferentequa- f(R,T) theories have been interpreted as a generaliza- tionsofmotion.Oncewehavetheseingredientswemay tion of the Brans-Dicke model [52]-[56]. As argued by try to apply the first-order formalism and then com- the authors in [26], the extra terms in the f(R,T)FEs pute the constraints that the superpotential will obey. may play the role of additional terms of effective grav- In fact, the analogous of that model for the f(R,T) itational and cosmological“constants” G and Λ . eff eff gravitywithnoscalarfieldcasewasinvestigatedin[16]. ThoseextratermsinΛ aretheresponsibleforavac- eff Wehaveobtainedfromthefirst-orderformalismap- uum decay in Λ(t)-like models. plied to the f(R,Tφ) gravity, two models able to de- Second,inbothdecayingvacuumandf(R,T)mod- scribeallthedifferentdynamicalstagesoftheuniverse, els, the covariant derivative of the energy-momentum from inflation, to radiation, matter and dark-energy tensor µT doesnotvanish.Indecayingvacuummod- µν ∇ dominated eras. els, this requires necessarily some energy exchange be- For the first time, an f(R,T) cosmological model tween matter and vacuum, throughvacuum decay into was able to describe all the dynamical stages of the matter or vice versa. universe continuously, including the primordial ones. The vacuum-decay models presented in [45,46], for There was no need of invoking different EoS or func- instance,arecapableofdescribingthecompletehistory tionalformsfor f(Tφ) indifferentstagesin orderto be ofthe universeinaneffective unifiedframework,inthe abletoaccountforallthe transienterasoftheuniverse same way the present f(R,Tφ) model does. In those dynamics, as made in [26], [43] and [44], for instance. models,the vacuumalwaysdecaysinthe dominantdy- In fact, there was no need of invoking any EoS at all. namicalcomponent of eachstage.However,in order to Such a quantity was obtained simply by dividing the be able to describe the various phases of the universe solutions p by ρ. dynamics, the functional form taken for Λ(t) is pro- Itisremarkablethefactthattheinflationaryscenar- posed on phenomenological grounds, by extrapolating iosofourmodelshavesmoothlydecayedtoaradiation- backwards in time the present available cosmological dominated era. This phenomenon is sometimes called data. On the other hand, the f(R,Tφ) scenario is free “gracefulexit”anditisnottrivialtobeobtained(check of ansatz or phenomenology. [45,46]forthegracefulexitachievementthroughdecay- Note also that the Λ(t) model presentedin [45] was ing vacuum models). In fact, an ideal inflationary sce- mimic through a scalar field model (check Section 4 of nario must naturally decay to a radiation-dominated sucha reference).This corroboratesthe argumentthat era [47,48], as in the present case. itmighthavesomefundamentalanalogybetweenscalar Alsoremarkableisthefactthatthemodelsarewell- field and decaying vacuum models. behaved at radiation stage. The match between the In this article, we have also formally brought to time scales for ω = 1/3 e Tφ =0 in Figs.1-2 reinforces thescientificcommunityattentiontheshortcomingsur- that. rounding the f(R,T) theories of gravity in the regime Not just the presentmodels were able to describe a T = 0. It is, indeed, straightforward to realize that in smooth transition between inflationary and radiation- such a regime of f(R,T) gravity one automatically re- dominated eras, but they were also able to predict the coversthe f(R) theories, or GR when f(R) is linear in matter dominated phase, with ω = 0, and the recent R [23]. We have shown, as an unprecedented outcome, 8 thatitispossibletodescriberadiationinf(R,T)grav- tensor T is then set to zero in order to obtain the µν itynotnecessarilybytherecoveringofGR,butthrough wave equation for vacuum [65]-[67]. In the same way extradynamicaltermscomingfromascalarfieldinthe the EoS ω = 1/3 yields a null trace for the energy- f(R,Tφ) approach. momentum tensor, this will happen for vacuum, with If one focus specifically on the radiation era pre- T = 0. Therefore it is expected that the study of µν dicted by the f(R,Tφ) model here presented, one is GWs, as the derivation of their primordial spectrum, able to obtain a scale factor which evolves as the one for instance, in the f(R,T) formalism yields the same of standard cosmology purely from the f(Tφ) contri- predictions as those obtained via f(R) gravity [68]. bution, which is a complementary novel feature of the ApowerfultooltostudythepropertiesofGWswas f(R,T) gravity that we will show below. developed in [69]. It consists in characterizing the po- BytakingTφ =0in(4)yieldsφ˙2 =4V(φ).Sincein larizationstates ofGWs ina giventheory1.Inorderto this case f(Tφ)=α(Tφ)n =0, one obtains, from (10), doso,oneevaluatestheNewman-Penrose(NP)quanti- ties[70,71].In[63],fromtheNPquantitiescalculation, H˙ = 4V(φ). (36) − theauthorshavefoundextrapolarizationstatesforthe FromEqs.(11),(15)and(36),onecanwriteH˙ = 2H2, f(R) gravity. Those extra states may be corroborated − which integrated for the scale factor a yields a t1/2. by experiment once the advanced GW detectors, such ∼ From standard cosmology [38,39], this is exactly the as LIGO [57] and VIRGO [58], start they next run. time proportionality of the scale factor of a radiation- Since the NP formalism is applied to the vacuum FEs dominateduniverse.Thereforetheformalismpresented of a given theory, such an application to the f(R,T) in this article surpasses the f(R,T = 0) issue since theory is expected to yield the same extra polarization it makes f(R,T) gravity able to describe a radiation- states as those of the f(R) formalism [63]. dominated universe purely from its dependence on Tφ. TheKerrmetricdescribesthegeometryofanempty Besides some questions exposed in the Introduc- space(T =0)aroundarotatingunchargedblackhole µν tion,veryrecently,the drawbackinf(R,T)theorywas (BH)withaxialsymmetry.KerrBHsstudieshavebeen raisedin[26],inwhichtheauthorshavesearchedfordif- constantly seen in the literature (check, for instance, ferentformsforf(T)indifferentstagesoftheuniverse. [72]-[75]). Since BHs are characterizedby strong gravi- Intheradiation-dominatedstage,theyfoundthatf(T) tational fields in quantum length scales, it is expected should be a non-null constant. As the authors have that their physics bring up some new insights about considered the f(R,T) theories as a generalization of quantum theories of gravity [76,77]. Once again, one Brans-Dicke gravity,the f(T) cte case leads to Geff wouldnotobtainnew contributionsto the study ofthe ∼ and Λeff to be, indeed, constants, as it may be seen space-timearounda KerrBHfromthe f(R,T)formal- in [26]. Therefore no contributions to a T =0 universe ism, in such a way the f(R) theories outcomes should would come from the f(R,T) formalism on this ap- be expected [78]-[81]. proach,departing from the results of the presentwork. Hence, one can see that the lack of contributions One could argue that the f(R) formalism retrieval fromf(R,T)gravitywillappearnotonlyinaradiation- in f(R,T) theories when T = 0 is not a shortcoming, dominateduniverse,butalsoinstudiesmadeinthevac- being just an intrinsic property of such theories. How- uumregime,sinceT =0 T =0.Inotherwords,in µν ever,belowwebringtothereader’sattentionsomefun- the absence of the f(R,Tφ→) approach presented here, damental areas of knowledge which will have to be ne- onewouldexpectthe f(R)formalismfeatures retrieval glected if the f(R,T) theories, indeed, simply recovers in the study, not only of a radiation-dominated uni- the f(R) formalism when T =0. verse, but also in those of GWs and space-times sur- Many contributions to Physics, Astrophysics and rounding BHs. Cosmology will come from the imminent detection of Forinstance,inthesearchfornewpolarizationstates gravitationalwaves(GWs)[57,58].Theirdetectionwill of GWs mentioned above, one works with the vacuum clarify some persistent and important issues, such as FEs of a theory. It is expected that if one considers the absolute ground state of matter [59], and also con- the vacuum on the rhs of standard f(R,T) FEs (check templates a powerful tool in estimating parameters of Eq.(11)of[12]),onegets,aftertheNPformalismappli- compactbinarysystems[60],constrainingthe equation cation,the same polarizationstates of the f(R) theory of state of neutron stars [61] and brane cosmological [63]. On the other hand, by taking T = 0 (and con- parameters values in braneworld models [62], and dis- µν tinguishingGRfromalternativetheoriesofgravity[63]. The study of the propagationof GWs is made once 1In general relativity, there are two polarization states of they have been generated [64]. The energy-momentum gravitational waves, knownas plusand cross polarizations. 9 sequently T = 0) in the present model FEs (6)2, one 12. T. Harko etal., Phys.Rev. D84(2011) 024020. expects the thirdterm inside the bracketsto survivein 13. A. G. Riessetal., Astron. J. 116(1998) 1009. 14. G. Perlmutter etal., Astrophys.J. 517 (1999) 565. the vacuum regime. This term should naturally yield 15. G. Hinshawetal., Astrophys.J. 208(2013) 19. some departure from both GR and f(R) gravity in the 16. H. Shabani and M. Farhoudi, Phys. Rev. D 88 (2013) study of GWs polarization states. Moreover, it could 044048. be responsiblefornoveltiesinotherastrophysicalareas 17. M.Jamil etal., Eur. Phys.J. C 72(2012) 1999. 18. C.P.SinghandP.Kumar, Eur.Phys.J.C74(2014) 11. submissive to the GW subject, such as the characteri- 19. P.H.R.S.Moraes, Eur.Phys.J. C75 (2015) 168. zation of the GW spectrum [64], the evolution of cos- 20. M.F.Shamir, Eur. Phys.J. C75(2015) 354. mological perturbations [82] and the GW background 21. I. Noureen etal., Eur. Phys.J. C75(2015) 323. from cosmologicalcompact binaries [83]. 22. M.ZubairandI.Noureen,Eur.Phys.J.C75(2015)265. 23. E.H.Baffouetal.,Astrophys.SpaceSci.356(2015)173. Furthermore,anothervacuumstudiesinf(R,T)grav- 24. P.H.R.S.Moraes, Astrophys.Space Sci.352 (2014) 273. itywillbeallowedtobeinvestigated,suchastheTolman- 25. P.H.R.S. Moraes, Int. J. Theor. Phys. (2015) DOI: Oppenheimer-Volkoff-de Sitter equation [84] and the 10.1007/s10773-015-2771-3. vacuumpolarizationby topologicaldefects [85],among 26. G.SunandY.-C.Huang,Thecosmologyinf(R,T)grav- ity without dark energy,arXiv: 1510.01061. many others. Those points above justify the search for 27. D. Bazeia et al., Phys.Lett. B633(2006) 415. evading the f(R,T = 0) issue, which was presented in 28. D. Bazeia et al., Phys.Lett. B743(2015) 98. this article. 29. P.H.R.S. Moraes and J.R.L. Santos, Phys. Rev. D 89 (2014) 083516. Thecontributionsfromthepresentworkareableto 30. J.R.L. Santos and P.H.R.S. Moraes, Fast-roll solutions motivatenewbranchesinthestudyoftheradiationuni- from two scalar field inflation,arXiv: 1504.07204. verse and vacuum in f(R,T) gravity. The present for- 31. B. Ratra and P.J.E. Peebles, Phys. Rev. D 37 (1988) malismmakespossibletomakethemostofthef(R,T) 3406. 32. E.J.Copelandetal.,Int.J.Mod.Phys.D15(2006)1753. theories. Although the f(R) formalism retrieval in the 33. A.Bandyopadhyayetal.,Eur.Phys.J.C72(2012)1943. T = 0 regime would not necessarily be a critical fea- 34. T. Harko etal., Eur. Phys.J. C74(2014) 2784. ture of the f(R,T)theories,it would make us overlook 35. S.Das andN. Banerjee, Gen.Rel. Grav. 38 (2006) 785. plentyofapplicationsofthosetheories,whichmaygen- 36. D. Bazeia, et al., Eur.Phys.J. C71 (2011) 1767. 37. D. Bazeia et al., Phys.Scr. 87 (2013) 045101. eratesomeremarkableoutcomes.Someofthose,aspos- 38. B. Ryden, Introduction to Cosmology (Addison Wesley, sible extra polarizationstates of GWs, maybe inferred San Francisco, USA, 2003). by experiment soon. 39. S.Dodelson, Modern Cosmology(Academic Press,Ams- terdan, Netherlands, 2003). 40. K. Bamba et al., Class.Quant. Grav. 30(2013) 015008. 41. L. Ackerman etal., JCAP 1105 (2011) 024. Acknowledgements PHRSMwouldliketothankSa˜oPaulo 42. R. Aldrovani etal., Eur. Phys.J. C58(2008) 483. Research Foundation (FAPESP), grant 2015/08476-0, for fi- 43. D.R.K. Reddy and R. Santhi Kumar, Astrophys. Space nancial support. The authors are grateful to Drs. M.E.S. Sci. 344(2013) 253. AlvesandJ.C.N.deArau´jofortheirsuggestionsinwhatcon- 44. S. Ram and Priyanka, Astrophys.SpaceSci. 347 (2013) cernsthephysicalinterpretationofthepresentmodel andto 389. theanonymousrefereeforhis/hersuggestionswhichcertainly 45. J.A.S. Limaet al., MNRAS 431(2013) 923. enriched thephysicaland cosmological content of thepaper. 46. E.L.D.Perico etal., Phys.Rev.D 88(2013) 063531. 47. J.A.S. Lima et al, Int. J. Mod. Phys. D 25 (2015) 1541006. 48. S. Basilakos et al, Int. J. Mod. Phys. D 22 (2013) References 1342008. 49. S.Weinberg, Rev. Mod. Phys.61(1989) 1. 1. A.H. Guth,Phys.Rev. D23 (1981) 347. 50. P.J. Peebles and Bharat Ratra, Rev. Mod. Phys. 75 2. A.A. Starobinsky,Phys.Lett. B117 (1982) 175. (2003) 559. 3. A.D. Linde,Phys.Lett. B116(1982) 335. 51. T. Padmanabhan, Phys.Rep. 380(2003) 235. 4. L.A.Kofman etal., Phys.Lett. B157 (1985) 361. 52. C. Brans and R.H. Dicke, Phys.Rev. 124 (1961) 925. 5. V.A. Belinskyet al., Phys.Lett. B155 (1985) 232. 53. H.W. Leeet al., Eur.Phys.J. C71 (2011) 1585. 6. K.NakayamaandM.Takimoto,Phys.Lett.B748(2015) 54. M.SharifandS.Waheed,Eur.Phys.J.C72(2012)1876. 108. 55. L. Xuet al., Eur. Phys.J. C60 (2009) 135. 7. F. Berzukov and M. Shaposhnikov, Phys. Lett. B 734 56. S.K.Tripathy etal., Eur. Phys.J. C75(2015) 149. (2014) 249. 57. J. Aasi, Class. Quant. Grav.32 (2015) 074001. 8. S.NojiriandS.D.Odintsov,Phys.Lett.B657(2007)238. 58. F. Acernese, Class. Quant. Grav. 32(2015) 024001. 9. S.NojiriandS.D.Odintsov,Phys.Lett.B659(2009)821. 59. P.H.R.S. Moraes and O.D. Miranda, MNRAS Lett. 445 10. M. Rinaldiet al., JCAP 08 (2014) 015. (2014) L11. 11. K. Bamba et al., Phys.Rev. D 90(2014) 124061. 60. C.P.L.Berry etal., Astrophys.J. 804 (2015) 114. 61. K. Takami etal., Phys.Rev.Lett. 113(2014) 091104. 2Remindthatwehaveassumedf(R,T)islinearinR,sothat 62. P.H.R.S. Moraes and O.D. Miranda, Astrophys. Space the lhs of Eq.(6) is purely the Einstein tensor, as in general Sci. 354(2014) 645. relativity. 63. M.E.S.Alveset al., Phys.Lett. B679 (2009) 401. 10 64. A. Buonanno, Gravitational Waves,arXiv:0709.4682. 76. C. Rovelli, Phys.Rev. Lett. 77 (1996) 3288. 65. D. Wang etal., Eur. Phys.J. C64(2009) 439. 77. A. Ashtekaretal., Phys.Rev. Lett. 80(1998) 904. 66. A.H. Abassi etal., Eur. Phys.J. C 73(2013) 2592. 78. Y.S.Myung,Phys.Rev. D84(2011) 024048. 67. V. Dzhunushaliev and V. Folomeev, Eur. Phys. J. C 74 79. Y.S.Myung,Phys.Rev. D88(2013) 104017. (2014) 3057. 80. S.G.Ghoshet al., Eur.Phys.J. C73 (2013) 2473. 68. C. Corda, Eur. Phys.J. C65(2010) 257. 81. J.A.R. Cembranos et al., Kerr-Newman black holes in 69. D.M. Eardley etal., Phys.Rev. D8(1973) 3308. f(R) theories,arXiv: 1109.4519. 70. E.NewmanandR.Penrose,J.Math.Phys.3(1962)566. 82. V.F. Mukhanovet al., Phys.Rep. 215 (1992) 203. 71. E.NewmanandR.Penrose,J.Math.Phys.4(1962)998. 83. A.J.FarmerandE.S.Phinney,MNRAS346(2003)1197. 72. C.A.R. Herdeiro and E. Radu, Phys. Rev. Lett. 112 84. T.Makino,Onthe Tolman-Oppenheimer-Volkoff-deSit- (2014) 221101. ter equation,arXiv:1508.06506. 73. S.G.GhoshandS.D.Maharaj,Eur.Phys.J.C75(2015) 85. E.R. Bezerra de Mello and A.A. Saharian, JHEP 04 7. (2009) 046. 74. S. Hussainetal., Eur. Phys.J. C74(2014) 3210. 75. J. Bhadra and U. Debnath, Eur. Phys. J. C 72 (2012) 1912.