Temperature effects on the nuclear symmetry energy and symmetry free energy with an isospin and momentum dependent interaction Jun Xu,1 Lie-Wen Chen,1,2 Bao-An Li,3 and Hong-Ru Ma1 1Institute of Theoretical Physics, Shanghai Jiao Tong University, Shanghai 200240, China 2Center of Theoretical Nuclear Physics, National Laboratory of Heavy-Ion Accelerator, Lanzhou, 730000, China 3Department of Physics, Texas A&M University-Commerce, Commerce, TX 75429, and Department of Chemistry and Physics, P.O. Box 419, Arkansas State University, State University, AR 72467-0419, USA Within a self-consistent thermal model using an isospin and momentum dependent interaction (MDI)constrained bytheisospin diffusiondatainheavy-ioncollisions, weinvestigatethetempera- turedependenceof thesymmetryenergy Esym(ρ,T)and symmetry free energy Fsym(ρ,T)for hot, isospin asymmetric nuclear matter. It is shown that the symmetry energy Esym(ρ,T) generally 7 decreaseswithincreasingtemperaturewhilethesymmetryfreeenergyFsym(ρ,T)exhibitsopposite temperature dependence. The decrement of the symmetry energy with temperature is essentially 0 due to the decrement of the potential energy part of the symmetry energy with temperature. The 0 2 differencebetweenthesymmetryenergyandsymmetryfreeenergyisfoundtobequitesmallaround thesaturation density of nuclear matter. While at very low densities, they differ significantly from n each other. In comparison with theexperimental dataof temperaturedependent symmetry energy a extracted from the isotopic scaling analysis of intermediate mass fragments (IMF’s) in heavy-ion J collisions, the resulting density and temperature dependent symmetry energy Esym(ρ,T) is then 5 used to estimate theaverage freeze-out density of theIMF’s. 2 PACSnumbers: 25.70.-z,21.65.+f,21.30.Fe,24.10.Pa 2 v 5 I. INTRODUCTION tryenergytodecreaseasthePauliblockingbecomesless 3 importantwhenthenucleonFermisurfacesbecomemore 0 diffused at increasingly higher temperatures [13, 14, 15]. 9 Theequationofstate(EOS)ofisospinasymmetricnu- 0 clear matter, especially the nuclear symmetry energy, is Based on a simplified degenerate Fermi gas model at fi- 6 nite temperatures, two of present authors [15] have re- essential in understanding not only many aspects of nu- 0 cently studied the temperature dependence of the sym- clearphysics,butalsoanumberofimportantissuesinas- / metry energy and it was shown that the experimentally h trophysics[1,2,3,4,5,6,7,8,9]. Informationaboutthe -t symmetry energy at zero temperature is important for observed decrease of the nuclear symmetry energy with l determining ground state properties of exotic nuclei and the increasing centrality or the excitation energy in iso- c topic scaling analyses of heavy-ion reactions can be well u properties of cold neutron stars at β-equilibrium, while understood analytically within the degenerate Fermi gas n the symmetry energy or symmetry free energy of hot : neutron-rich matter is important for understanding the model. In particular, it was argued that the symmetry v energyextractedfromisotopicscalinganalysesofheavy- Xi liquid-gasphasetransitionofasymmetricnuclearmatter, ion reactions reflects the symmetry energy of bulk nu- the dynamical evolution of massive stars and the super- clear matter for the emission source. Furthermore, it r novaexplosionmechanisms. Heavy-ionreactionsinduced a wasfoundthatthe evolutionofthesymmetryenergyex- byneutron-richnucleiprovideauniquemeanstoinvesti- tractedfromtheisotopicscalinganalysisismainlydueto gate the symmetry energy [1, 2, 7]. In particular, recent the variation in the freeze-out density rather than tem- analyses of the isospin diffusion data in heavy-ion reac- peraturewhenthefragmentsareemittedinthereactions tions [10, 11, 12] have already put a stringent constraint carried out under different conditions. on the symmetry energy of cold neutron-rich matter at sub-normal densities. On the other hand, the temper- In the present work, within a self-consistent thermal ature dependence of the symmetry energy or symmetry model using an isospin and momentum dependent inter- free energy for hot neutron-rich matter has received so action(MDI)constrainedbytheisospindiffusiondatain far little theoretical attention [13, 14, 15]. heavy-ioncollisions,westudysystematicallythetemper- For finite nuclei at temperatures below about 3 MeV, ature dependence of the nuclear matter symmetry en- the shell structure and pairing as well as vibrations of ergy E (ρ,T) and symmetry free energy F (ρ,T). sym sym nuclear surfaces are important and the symmetry en- It is shown that the nuclear matter symmetry energy ergywaspredictedtoincreaseslightlywiththeincreasing E (ρ,T) generally decreases with increasing tempera- sym temperature [16, 17]. Interestingly, an increase by only ture while the symmetry free energy F (ρ,T) exhibits sym about8%inthesymmetryenergyintherangeofT from oppositetemperaturedependence. Thedecrementofthe 0 to 1 MeV was found to affect appreciably the physics symmetry energy with temperature is essentially due to ofstellar collapse,especially the neutralizationprocesses thedecrementofthepotentialenergypartofthesymme- [16]. At higher temperatures, one expects the symme- tryenergywithtemperature. Furthermore,thedifference 2 betweenthenuclearmattersymmetryenergyEsym(ρ,T) Au(x),Al(x),B,Cτ,τ,Cτ,−τ and Λ have been assumed andsymmetryfreeenergyF (ρ,T)isfoundtobequite to be temperature independent and are obtained by fit- sym small around nuclear saturation density. Using the re- ting the momentum-dependence of U(ρ,T =0,δ,~p,τ) to sultingdensityandtemperaturedependentsymmetryen- that predicted by the Gogny Hartree-Fock and/or the ergyE (ρ,T),weestimate the averagefreeze-outden- Brueckner-Hartree-Fock calculations, the zero tempera- sym sity of the fragment emission source based on the mea- ture saturation properties of symmetric nuclear matter suredtemperaturedependentsymmetryenergyfromthe andthesymmetryenergyof31.6MeVatnormalnuclear isotopic scaling analysis in heavy-ioncollisions. matter density ρ =0.16 fm−3 [18]. The incompressibil- 0 Thepaperisorganizedasfollows. InSectionII,wein- ity K of cold symmetric nuclear matter at saturation 0 troduce the isospin and momentum dependent MDI in- density ρ is set to be 211 MeV. The parameters A (x) 0 u teraction and the detailed numerical method to obtain and A (x) depend on the x parameter according to l the EOS of the symmetric nuclear matter and pure neu- tron matter at finite temperatures. Results on the tem- 2B 2B A (x)=−95.98−x , A (x)=−120.57+x . perature dependence of the symmetry energy and sym- u σ+1 l σ+1 metry free energy are presented in Section III. In Sec- (3) tion IV, we discuss the experimentaldata of the isotopic The different x values in the MDI interaction are in- scaling in heavy-ion collisions by means of the obtained troduced to vary the density dependence of the nuclear densityandtemperaturedependentsymmetryenergy. A symmetry energy while keeping other properties of the summary is given in Section V. nuclear equation of state fixed [11] and they can be ad- justedtomimicpredictionsonthedensitydependenceof nuclear matter symmetry energy by microscopic and/or II. HOT NUCLEAR MATTER EOS IN phenomenological many-body theories. The last two MOMENTUM DEPENDENT INTERACTION terms of Eq. (2) contain the momentum-dependence of thesingle-particlepotential. Themomentumdependence Our study is based on a self-consistent thermal model of the symmetry potential stems from the different in- usingamodifiedfinite-rangeGognyeffectiveinteraction, teraction strength parameters Cτ,−τ and Cτ,τ for a nu- i.e., the isospin- and momentum-dependent MDI inter- cleon of isospin τ interacting, respectively, with unlike action[18]. In the MDI interaction,the potential energy and like nucleons in the background fields. More specif- density V(ρ,T,δ) of a thermal equilibrium asymmetric ically, we use Cτ,−τ = −103.4 MeV and Cτ,τ = −11.7 nuclear matter at total density ρ, temperature T and MeV. We note that the MDI interactionhas been exten- isospin asymmetry δ is expressed as follows [11, 18], sivelyusedinthetransportmodelforstudyingisospinef- fects in intermediate energy heavy-ion collisions induced V(ρ,T,δ) = Auρnρp + Al (ρ2 +ρ2) by neutron-rich nuclei [11, 12, 19, 20, 21, 22, 23, 24]. In ρ0 2ρ0 n p particular, the isospin diffusion data from NSCL/MSU B ρσ+1 have constrained the value of x to be between 0 and −1 + σ+1 ρσ (1−xδ2) fornuclearmatterdensitieslessthanabout1.2ρ0[11,12], 0 we will thus in the present work consider the two values ′ + ρ10 Xτ,τ′Cτ,τ′Z Z d3pd3p′1fτ+(~r(,p~~p−)fτp~′′()~r2,/p~Λ(1)2). ofAxt=ze0roantdemxp=er−at1u.re, fτ(~r,p~) = h23Θ(pf(τ)−p) and the integralinEqs.(1) and(2) canbe calculatedanalyt- Inmeanfieldapproximation,Eq. (1)leadsto thefollow- ically[18]. For anasymmetricnuclearmatter atthermal ingsingleparticlepotentialforanucleonwithmomentum equilibriumwitha finite temperatureT,the phasespace p~ and isospin τ in the thermal equilibrium asymmetric distribution function becomes the Fermi distribution nuclear matter, i.e., [11, 18] 2 1 f (~r,p~)= (4) U(ρ,T,δ,~p,τ) = A (x)ρ−τ +A(x)ρτ τ h3exp(ǫ(ρ,T,δ,Tp~,τ)−µτ)+1 u l ρ ρ 0 0 + B(ρρ )σ(1−xδ2)−8τxσB+1ρρσ−σ1δρ−τ twhheetroetaµlτsiinsgtlheepachrteimcleicaenleprogtyenfotriaal nauncdleǫo(nρ,wTi,tδh,~pis,oτs)piins 0 0 τ and momentum ~p, which includes the kinetic energy ′ 2C f (~r,p~) + τ,τ d3p′ τ and the single particle potential U(ρ,T,δ,~p,τ), i.e., ρ 1+(p~−~p′)2/Λ2 0 Z ′ + 2Cρτ0,−τ Z d3p′1+f(−p~τ−(~r~p,′~p)2)/Λ2. (2) ǫ(ρ,T,δ,~p,τ) = 2pm2τ +Auρρ−0τ +Alρρτ0 Iσn=th4e/a3b;ofvτe(~rτ,~p)=is1/th2e(−ph1a/s2e)sfpoarceneduitsrtornibsut(ipornotfounnsc)-; + B(ρρ0)σ(1−xδ2)−8τxσB+1ρρσ−σ01δρ−τ tion at coordinate ~r and momentum ~p. The parameters + Rτ,τ(ρ,p~)+Rτ,−τ(ρ,~p) (5) 3 with Furthermore, we can obtain the entropy per nucleon Rτ1,τ2(ρ,p~)= 2Cρτ1,τ2 d3p′1+f(p~τ2−(~r,p~p~′)′2)/Λ2 (6) Smτa(tρt,eTr,aδs)ofthethermalequilibriumasymmetricnuclear 0 Z ∞ 8π where τ1 and τ2 can be chosen as the same or different S (ρ,T,δ)=− p2[n lnn +(1−n )ln(1−n )]dp to mimic the last two terms of Eq. (2). τ ρh3 τ τ τ τ Z0 The chemical potential µ is therefore independent of (10) τ the nucleon momentum p~ and can be determined from with the occupation probability 8π ∞ p2dp 1 ρ = . (7) n = . (11) τ h3Z0 exp(ǫ(ρ,T,δ,Tp~,τ)−µτ)+1 τ exp(ǫ(ρ,T,δ,Tp~,τ)−µτ)+1 From Eq. (7), we can see that, at finite temperature, Finally,thefreeenergypernucleonF(ρ,T,δ)ofthether- to obtain the chemical potential µ requires knowing τ mal equilibrium asymmetric nuclear matter can be ob- ǫ ρ,T,δ,~p,τ) (and thus R (ρ,~p)) for all p~, while ( τ1,τ2 tained from the thermodynamic relation from Eq. (6) knowing R (ρ,~p) needs further to know τ1,τ2 f (~r,p~) which again depends on the chemical potential τ µτ from Eq. (4). Therefore. Eqs. (4), (5), (6), and (7) F(ρ,T,δ)=E(ρ,T,δ)−T Sτ(ρ,T,δ). (12) constitute closedsets of equations whose solutioncanbe τ X obtained by a self-consistency iteration, just as in the Hartree-Fock theory. Following the recipe used in Ref. [25], the self- consistency problem of Eqs. (4), (5), (6), and (7) can 20 20 be solved by the following iterative scheme. Firstly, we Symmetric Nuclear Matter make an initial guess for Rτ1,τ2(ρ,~p) from the zero tem- 10 MDI interaction 10 perature condition, i.e., Rτ01,τ2(ρ,p~)= 2Cρτ01,τ2 Z d3p′h123+Θ((p~pf−(τp~2′))2−/Λp′2) (8) MeV) -100 -010 F (M wherepf(τ)=h¯(3π2ρτ)1/3istheFermimomentum. The E ( eV right hand side of Eq. (8) is not related to the chemical ) -20 T (MeV) -20 potential µτ and thus the initial form of the single nu- 0 cleon energy ǫ0(ρ,T,δ,~p,τ) can be obtained. Secondly, 5 -30 10 -30 substituteǫ0(ρ,T,δ,~p,τ)intoEq.(7)toobtaintheinitial 15 chemical potential µ0 for protons and neutrons. Then, τ -40 -40 useǫ0(ρ,T,δ,~p,τ)andµ0τ toobtainnewRτ1,τ2(ρ,p~)func- 0 1 2 0 1 2 3 tion, namely, Rτ11,τ2(ρ,p~) from Eq. (4) and (6). This in / 0 turn gives the new single nucleon energy ǫ1(ρ,T,δ,~p,τ) FIG. 1: (Color online) Density dependenceof theenergy per fromEq. (5)andthenthenewchemicalpotentialµ1τ can nucleon E (left panel) and free energy per nucleon F (right be obtained from Eq. (7). The cycle is repeated and a panel) for symmetric nuclear matter at T =0 MeV, 5 MeV, fewiterationsaresufficienttoachieveconvergenceforthe 10 MeV and 15 MeV with the MDI interaction. chemicalpotentialµ withenoughaccuracy. Itshouldbe τ mentioned that the neutron and proton chemical poten- Using the MDI interaction, we can now calculate the tials are coupled with each other in asymmetric nuclear energypernucleonE(ρ,T,δ)andfreeenergypernucleon matter and thus the convergence condition must be sat- F(ρ,T,δ) of nuclear matter at finite temperature from isfied simultaneously for neutrons and protons. Eq. (9) and (12). Shown in Fig. 1 is the density depen- With the self-consistency iteration, we can finally ob- dence of E(ρ,T,δ) and F(ρ,T,δ) for symmetric nuclear tain the chemical potential µ and the single nucleon matteratT =0MeV,5MeV,10MeVand15MeVusing τ energy ǫ(ρ,T,δ,~p,τ) for an asymmetric nuclear matter the MDI interaction with x =0 and −1. For symmetric atthermalequilibrium with a finite temperatureT. The nuclear matter (δ = 0), the parameter x = 0 would give potentialenergydensityV(ρ,T,δ)ofthethermalequilib- the same results as the parameter x = −1 as we have rium asymmetric nuclear matter then can be calculated discussedabove,andthusthe curvesshowninFig. 1are fromEq.(1)andtheenergypernucleonE(ρ,T,δ)isthen the same for x = 0 and −1. From Fig. 1, one can see obtained as that the energy per nucleon E(ρ,T,δ) increases with in- creasingtemperatureT whilethefreeenergypernucleon F(ρ,T,δ) decreases with increment of T. The increment 1 p2 E(ρ,T,δ)= V(ρ,T,δ)+ d3p f (~r,p~) . oftheenergypernucleonE(ρ,T,δ)withthetemperature τ ρ" τ Z 2mτ # reflects the thermal excitation of the nuclear matter due X (9) to the change of the phase-space distribution function 4 f (~r,p~). With the increment of the temperature, more τ nucleonsmovetohighermomentumstatesandthus lead 60 tolargerinternalenergypernucleon. Ontheotherhand, 50 (a) T=0 MeV (b) T=5 MeV the decrement of the free energy per nucleon F(ρ,T,δ) ) =0.5 V40 with T is mainly due to the increment of the entropy e =1.5 per nucleon with increasing temperature. This feature (M 30 =2.5 also implies that the increment of TS(ρ,T) with T is 0) =20 larger than the increment of E(ρ,T) with T. Further- more, the temperature effects are seen to be stronger at T,10 , lowerdensitieswhiletheybecomemuchweakerathigher E( 0 idsesnmsiatilelesr. aAntdlotwhuersdteemnspiteireast,utrheeeFffeercmtsiomnotmheenetnuemrgpyfp(τer) ) 50 (c) T=10 MeV (d) T=15 MeV nucleon E(ρ,T,δ) are expected to be stronger. Mean- T,40 , while, the entropy per nucleon becomes larger at lower E(30 densities where the particles become more free in phase spaceandthusleadstoasmallerfreeenergypernucleon. 20 10 0 0.0 0.2 0.4 0.6 0.8 0.0 0.2 0.4 0.6 0.8 1.0 2 60 60 Pure Neutron Matter MDI interaction FIG.3: (Coloronline)E(ρ,T,δ)−E(ρ,T,δ=0)asafunction x= 0 ofδ2 at temperatureT =0MeV (a),5MeV (b),10 MeV(c) 40 40 x= 1 and 15 MeV (d) for three different baryon number densities ρ = 0.5ρ0,1.5ρ0 and 2.5ρ0 using the MDI interaction with V) F x=0. e 20 20 ( M M ( e E V 0 T15 (MeV) T (MeV) 0 ) equation of state of hot neutron-rich matter at density 10 0 ρ, temperature T, and an isospin asymmetry δ can also 5 5 be written as a parabolic function of δ, i.e., 0 10 -20 15 -20 E(ρ,T,δ)=E(ρ,T,δ =0)+E (ρ,T)δ2+O(δ4). (13) sym 0.0 0.5 1.0 1.5 0.0 0.5 1.0 1.5 2.0 / 0 The temperature and density dependent symmetry en- ergy E (ρ,T) for hot neutron-rich matter can thus be sym FIG. 2: (Color online) Same as Fig. 1 but for pure neutron extractedfromE (ρ,T)≈E(ρ,T,δ =1)−E(ρ,T,δ = sym matterusingtheMDIinteractionwithx=0(solidlines)and 0). The symmetry energy E (ρ,T) is the energy cost −1 (dashed lines). sym to convert all protons in symmetry matter to neutrons at the fixed temperature T and density ρ. In order to Similarly, shown in Fig. 2 are the density dependence check the empirical parabolic law Eq. (13) for the MDI of the E(ρ,T,δ) and F(ρ,T,δ) for pure neutron matter interaction, we show in Fig. 3 E(ρ,T,δ)−E(ρ,T,δ =0) at T = 0 MeV, 5 MeV, 10 MeV and 15 MeV using the as a function of δ2 at temperature T = 0 MeV, 5 MeV, MDI interaction with x = 0 and −1. The temperature 10 MeV and 15 MeV for three different baryon number dependence of the E(ρ,T,δ) andF(ρ,T,δ) for pure neu- densities ρ = 0.5ρ ,1.5ρ and 2.5ρ using the MDI in- 0 0 0 tronmatterisseentobesimilartothatofthesymmetric teraction with x = 0. The clear linear relation between nuclear matter as shown in Fig. 1. However,the param- E(ρ,T,δ)−E(ρ,T,δ = 0) and δ2 shown in Fig. 3 indi- eters x=0 and −1 display different density dependence catesthe validity ofthe empiricalparaboliclawEq. (13) for the energyper nucleon E(ρ,T,δ)and free energyper for the hot neutron-rich matter. We note that the em- nucleon F(ρ,T,δ), which just reflects that the parame- piricalparaboliclawEq. (13)isalsowellsatisfiedforthe ters x = 0 and −1 give different density dependence of parameter x=−1. the nuclear symmetry energy and symmetry free energy Similarly, we can define the symmetry free energy as will be discussed in the following. F (ρ,T) by the following parabolic approximation to sym the free energy per nucleon III. NUCLEAR SYMMETRY ENERGY AND F(ρ,T,δ)=F(ρ,T,δ =0)+F (ρ,T)δ2+O(δ4). (14) sym SYMMETRY FREE ENERGY The temperature and density dependent symmetry free As in the case of zero temperature, phenomenologi- energy F (ρ,T) for hot neutron-rich matter can thus sym cal and microscopic studies [13, 14] indicate that the be extracted from F (ρ,T) ≈ F(ρ,T,δ = 1) − sym 5 60 50 (a) T=0 MeV (b) T=5 MeV 50 50 MDI interaction =0.5 ) x= 0 eV 40 =1.5 40 x= 1 T (MeV) 40 =0) (M 2300 =2.5 (MeV) 30 11 5050 30 sym F( ,T, 10 (,T) 20 20 ,T) (M ) F( 500 (c) T=10 M eV (d) T=15 MeV Esym 10 T05 (MeV) 10 eV) T, 40 10 , 15 F( 30 0 0 0.0 0.5 1.0 0.0 0.5 1.0 1.5 20 / 0 10 FIG. 5: (Color online) Density dependence of the symmetry 0 energy Esym(ρ,T) (left panel) and thesymmetry free energy 0.0 0.2 0.4 0.6 0.8 0.20 0.2 0.4 0.6 0.8 1.0 Fsym(ρ,T) (right panel) at T =0MeV, 5MeV, 10 MeV and 15 MeV using theMDI interaction with x=0 and −1. FIG.4: (Color online)SameasFig. 3butforthefreeenergy per nucleon F(ρ,T,δ). namely, with increasing temperature T, E (ρ,T) de- sym creaseswhile F (ρ,T)increases. This also means that sym F (ρ,T) always has larger values than E (ρ,T) at sym sym F(ρ,T,δ = 0) which is just the free energy cost to fixeddensity andtemperature since they are identicalat convert all protons in symmetry matter to neutrons at zero temperature. At higher temperatures, one expects the fixed temperature T and density ρ. In order to thesymmetryenergyE (ρ,T)todecreaseasthePauli sym check if the empirical parabolic law is also valid for the blocking(apurequantumeffect)becomeslessimportant free energy per nucleon of hot neutron-rich matter, we when the nucleon Fermi surfaces become more diffused show in Fig. 4 F(ρ,T,δ) − F(ρ,T,δ = 0) as a func- at increasingly higher temperatures [13, 14, 15]. On the tion of δ2 at temperature T = 0 MeV, 5 MeV, 10 MeV other hand, the symmetry free energy F (ρ,T) is re- sym and 15 MeV for three different baryon number densities lated to the entropy per nucleon of the asymmetric nu- ρ = 0.5ρ ,1.5ρ and 2.5ρ using the MDI interaction 0 0 0 clear matter, which is not a pure quantum effect, and with x = 0. One can see from Fig. 4 that the parabolic its increment with increasingtemperature can be under- law Eq. (14) is also approximately satisfied though at stood by the following expression low densities and high temperatures, the linear relation between F(ρ,T,δ) − F(ρ,T,δ = 0) and δ2 is violated F (ρ,T) = E (ρ,T) sym sym slightly. Forthe parameterx=−1,wealsoobtainedthe +T [S (ρ,T,δ =0)+S (ρ,T,δ =0)] n p similar conclusion. −TS (ρ,T,δ =1). (15) n InFig. 5,weshowthedensity dependence ofthe sym- metry energy Esym(ρ,T) and the symmetry free energy The first term of the right hand side in Eq. (15) is the Fsym(ρ,T) at T =0 MeV, 5 MeV, 10 MeV and 15 MeV symmetry energy Esym(ρ,T), which decreases with in- using the MDI interaction with x = 0 and −1. For dif- creasing temperature as discussed above. However, the ferentchoice of the parameterx=0 and−1,Esym(ρ,T) total entropy per nucleon of the symmetric nuclear mat- andFsym(ρ,T)displaydifferentdensitydependencewith ter is larger than that of the pure neutron matter and x = 0 (−1) giving larger (smaller) values for the sym- their difference becomes larger with increasing tempera- metry energy and the symmetry free energy at lower ture, which leads to a positive value for the difference densities while smaller (larger) ones at higher densities between the last two terms of the right hand side in for a fixed temperature. Similar to the E(ρ,T,δ) and Eq. (15). Therefore, F (ρ,T) has larger values than sym F(ρ,T,δ) as shown in Figs. 1 and 2, the temperature E (ρ,T) at fixed density and temperature. Further- sym effects onthe symmetryenergyEsym(ρ,T)andthe sym- more, the increment of TS(ρ,T)with T is stronger than metry freeenergyFsym(ρ,T)arefoundto be strongerat theincrementofE(ρ,T)withT asmentionedabove,and lowerdensitieswhiletheybecomemuchweakerathigher the combinational effects thus cause the symmetry free densities. energy F (ρ,T) increase with increasing temperature. sym Interestingly, we can see from Fig. 5 that the sym- Within the present self-consistent thermal model, be- metry energy E (ρ,T) and the symmetry free energy cause the single particle potential is momentum depen- sym F (ρ,T) exhibit opposite temperature dependence, dent with the MDI interaction, the potential part of the sym 6 symmetry energy is expected to be temperature depen- dent. Itisthusinterestingtostudyhowthepotentialand kinetic parts of the symmetry energy Esym(ρ,T) may 30 MDI interaction with x = 0 vary respectively with temperature. However, for the (a) = 0 symmetry free energy F (ρ,T), one cannot separate 25 Total sym Potential its potential and kinetic parts since F (ρ,T) depends sym 20 Kinetic on the entropy that is determined by the phase space distribution function. Fig. 6 displays the temperature 15 dependence of the symmetry energy Esym(ρ,T) as well V) 10 as its potential and kinetic energy parts using the MDI e M tinhteerpaacrtaiomnetweirthxx==−01,atthρe=samρ0e, 0co.5nρc0l,usainodn0is.1oρb0t.aWineitdh. T) ( 18 (b) =0.5 0 , 15 ItisseenthatboththesymmetryenergyE (ρ,T)and sym ( itspotentialenergypartdecreasewithincreasingtemper- m12 y s ature at all three densities considered. While the kinetic E 9 energy part of the E (ρ,T) increases slightly with in- sym creasing temperature for ρ=ρ and 0.5ρ and decreases for ρ = 0.1ρ . These features0are uniqu0ely determined 5 (c) = 0 0 by the momentum dependence in the MDI interaction 4 within the present self-consistent thermal model. The 3 decrementofthekineticenergypartofthesymmetryen- 2 ergywith temperature atvery low densities is consistent with predictions of the Fermi gas model at high temper- 1 atures and/orvery lowdensities [15, 26]. In the study of 0 5 10 15 T (MeV) Ref.[15]usingthesimplifieddegenerateFermigasmodel FIG. 6: (Color online) Temperature dependence of the sym- the potential part of the symmetry energy was assumed to be temperature independent for simplicity. The de- metry energy Esym(ρ,T) as well as its potential energy part and kinetic energy part using MDI interaction with x=0 at crease of the symmetry energy observed there is thus ρ=ρ0 (a), 0.5ρ0 (b), and 0.1ρ0 (c). completely due to the decrease in the kinetic contribu- tion. However,wenotethatthetemperaturedependence of the total symmetry energy Esym(ρ,T) is consistent where△[(Z/A)2]≡(Z /A )2−(Z /A )2 isthedifference with each other for the two models. This is due to the 1 1 2 2 betweenthe(Z/A)2valuesofthetwofragmentingsources fact that the phase space distribution function will vary created in the two reactions. self-consistently accordingto if the singleparticle poten- AsmentionedinRef. [15],however,becauseofthedif- tial is or not momentum dependent. From the present ferent assumptions used in the various derivations, the self-consistentthermalmodelwithmomentumdependent validity of Eq. (16) is still disputable as to whether MDI interaction,ourresults indicate thatthe decreasing and when the C is actually the symmetry energy or symmetry energy with increasing temperature is essen- sym the symmetry free energy. Moreover, the physical inter- tially due to the decrement of its potential contribution. pretation of the C (ρ,T) is also not clear, sometimes sym even contradictory, in the literature. The main issue is whether the C measures the symmetry energy of the sym fragmenting source or that of the fragments formed at IV. ISOTOPIC SCALING IN HEAVY-ION freeze-out. This ambiguity is also due to the fact that COLLISIONS the derivation of Eq. (16) is not unique. In particular, within the grand canonical statistical model for multi- It has been observed experimentally and theoretically fragmentation [34, 35] the Csym refers to the symmetry in many types of reactions that the ratio R (N,Z) of energy of primary fragments. While within the sequen- 21 yields of a fragment with proton number Z and neu- tial Weisskopf model in the grand canonical limit [34] tron number N from two reactions reaching about the it refers to the symmetry energy of the emission source. sametemperatureT satisfiesanexponentialrelationship Following the arguments in Ref. [15], we assume in the R21(N,Z)∝ exp(αN) [27, 28, 29, 30, 31, 32, 33, 34, 35, presentworkthattheCsym reflectsthesymmetryenergy 36, 37, 38]. Particularly, in several statistical and dy- of bulk nuclear matter for the emission source. namical models under some assumptions [34, 35, 36], it In Fig. 7, we show the symmetry energy Esym(ρ,T) has been shown that the scaling coefficient α is related and symmetry free energy Fsym(ρ,T) as a function of to the symmetry energy C (ρ,T) via temperature using MDI interaction with x = 0 and −1 sym at different densities from 0.1ρ to ρ . The temperature 0 0 α= 4Csym(ρ,T) △[(Z/A)2], (16) dbeepveenrdyesnicmeiolafrthtoetshyamtminetRryefe.n[1er5g]ywEhesyrme(aρs,iTm)pilsifiseedendteo- T 7 squares) [31, 32]. From Fig. 7, it is seen clearly that the experimentally observed evolution of the symmetry 35 V) MDI interaction with x = 0 MDI interaction with x = 1 energyismainlyduetothechangeindensityratherthan Me 30 / 0=1 / 0=1 temperature, as shown in Ref. [15]. Meanwhile, we can T) ( 25 00..89 INDRA@GSI 0.9 INDRA@GSI efrsatgimmaetnetfermomissFioign.s7outrhceeafvroermagtehefrmeeezaes-uouretddteenmsiptyeroaftuthree , 0.7 0.8 (m 0.6 dependentsymmetryenergybasedontheisotopicscaling and Fsy1250 00..45 TAMU 000...567 TAMU wasynimtahlmyxseits=riyn0,ehnweeearvgfiyyn-diEontsyhmceo(alρlvi,seTiroa)ngsfe.rofIrmneepzthea-erotuMictuDdlaIerni,nsuittesyirnaogcftttiohhnee ) 0.3 T 0.4 fragmentemissionsourceρ isbetweenabout0.41ρ and , 10 f 0 (m 0.2 0.3 0.52ρ0 for TAMU data while about 0.42ρ0 and 0.75ρ0 Esy 5 0.1 0.2 for INDRA-ALADIN collaboration data. On the other Esym Fsym 0.1 hand, using the symmetry energy Esym(ρ,T) from the 0 MDI interaction with x = −1, the ρf is found to be 0 2 4 6 8 0 2 4 6 8 10 between about 0.57ρ0 and 0.68ρ0 for TAMU data while T (MeV) about0.58ρ0 and0.84ρ0 forINDRA-ALADIN collabora- tiondata. Itisinterestingtoseethattheextractedvalues FIG. 7: (Color online) Temperature dependence of the sym- ofρ fromtheMDIinteractionwithx=0isverysimilar metry energy (solid lines) and symmetry free energy (dashed f lines) using MDI interaction with x = 0 (left panel) and to those extracted in Ref. [30] using different models. −1 (right panel) at different densities from 0.1ρ0 to ρ0. Furthermore, if the symmetry free energy Fsym(ρ,T) The experimental data from Texas A&M University (solid from the MDI interactionwith x=0 is used to estimate squares) and the INDRA-ALADIN collaboration at GSI theρ ,wefindtheρ isbetweenabout0.36ρ and0.49ρ f f 0 0 (open squares) are included for comparison. forTAMUdataandabout0.33ρ and0.72ρ forINDRA- 0 0 ALADINcollaborationdata. While ifthe symmetryfree energyF (ρ,T)fromtheMDIinteractionwithx=−1 sym is used, the ρ is between about 0.52ρ and 0.66ρ for generateFermigasmodelatfinitetemperatureshasbeen f 0 0 TAMU data and about 0.51ρ and 0.83ρ for INDRA- used. The symmetry energy does not change much with 0 0 ALADINcollaborationdata. Therefore,theextractedρ thetemperatureatagivendensity,especiallyaroundthe f values are not sensitive to if the measured C (ρ,T) is saturation density ρ . Furthermore, it is seen that while sym 0 thesymmetryenergyorthesymmetryfreeenergy. How- the symmetry energy E (ρ,T) deceases slightly with sym ever, the extracted ρ values are indeed sensitive to the the increasing temperature at a given density, the sym- f x parameter used in the MDI interaction, namely, the metry free energy F (ρ,T) increases instead. Around sym density dependence of the symmetry energy. We note the saturation density ρ , it is found that the difference 0 thatthe zero-temperaturesymmetryenergyforthe MDI between the symmetry energy E (ρ,T) and the sym- sym interaction with x = 0 and −1 can be parameterized, metryfreeenergyF (ρ,T)isquitesmall,i.e.,onlysev- sym respectively, as 31.6(ρ/ρ )0.69 MeV and 31.6(ρ/ρ )1.05 eral percents, though at higher temperature, compared 0 0 MeV [11]. Therefore, the isotopic scaling in heavy-ion withtheirvaluesatT =0MeV.Thisfeatureconfirmsthe collisionsprovidesapotentialgoodprobe forthe density assumption on identifying C (ρ,T) to E (ρ,T) at sym sym dependence ofthe nuclear matter symmetry energyonce lower temperatures and not so low densities [28, 29, 30]. the average density of the emission source has been de- At low densities, on the other hand, the symmetry free terminedintheisotopicscalingmeasurement,aspointed energy F (ρ,T) exhibits a stronger temperature de- sym out in Ref. [15]. pendenceanditissignificantlylargerthanthesymmetry energy E (ρ,T) at moderate and high temperatures. sym This is due to the fact that the entropy contribution to the symmetry free energy F (ρ,T) becomes stronger V. SUMMARY sym at low densities as mentioned in Sec. II and Sec. III. It shouldbenotedthat,atlowdensitiestheentropymaybe Within a self-consistent thermal model using the affected strongly by the clustering effects [33, 39] which isospin and momentum dependent MDI interaction with are not included in the present work. x = 0 and −1 constrained by the isospin diffusion data Experimentally, the temperature T and scaling coeffi- in heavy-ioncollisions, we have investigated the temper- cient α (thus the C ) of the fragment emission source ature dependence of the nuclear matter symmetry en- sym can be directly measured while the determination of the ergy E (ρ,T) and symmetry free energy F (ρ,T). sym sym density of emission source usually depends on the model It is shown that the nuclear matter symmetry energy used. AlsoincludedinFig.7aretheexperimentaldataof E (ρ,T) generally decreases with increasing tempera- sym the measured temperature dependent symmetry energy ture while the symmetry free energy F (ρ,T) exhibits sym fromTexasA&MUniversity(TAMU)(solidsquares)[30] oppositetemperaturedependence. Thedecrementofthe and the INDRA-ALADIN collaboration at GSI (open symmetry energy with temperature is essentially due to 8 thedecrementofthepotentialenergypartofthesymme- ergy F (ρ,T) in the temperature and density ranges sym tryenergywithtemperature. Thetemperatureeffectson reached in the TAMU and INDRA/GSI experiments. the nuclear matter symmetry energy and symmetry free They are, however, sensitive to the x parameter used energy are found to be stronger at lower densities while in the MDI interaction, namely, the density dependence become much weaker at higher densities. Furthermore, of the symmetry energy. Therefore the isotopic scaling the difference between the nuclear matter symmetry en- in heavy-ioncollisions provides a potentially good probe ergy E (ρ,T)and symmetry free energy F (ρ,T) is forthedensitydependenceofthenuclearmattersymme- sym sym found to be quite small around nuclear saturation den- try energy provided the average density of the emission sity, although significantly large at very low densities. source can be determined simultaneously in the isotopic Comparing the theoretical density and tempera- scaling measurements. ture dependent symmetry energy E (ρ,T) with the sym C (ρ,T) parameter extracted from the isotopic scal- sym ing data from TAMU and the INDRA-ALADIN collab- Acknowledgments oration at GSI, we found that the experimentally ob- served evolution of the symmetry energy is mainly due to the change in density rather than temperature, as This work was supported in part by the National shown in the previous work [15]. Meanwhile, we have Natural Science Foundation of China under Grant Nos. estimated the averagefreeze-out density of the fragment 10334020, 10575071, and 10675082, MOE of China un- emission source formed in these reactions by comparing der project NCET-05-0392, Shanghai Rising-Star Pro- the calculated E (ρ,T) or F (ρ,T) with the mea- gram under Grant No. 06QA14024,the SRF for ROCS, sym sym suredC (ρ,T). Ourresultsindicatethattheextracted SEM of China, the US National Science Foundation un- sym average freeze-out densities are not sensitive to whether der Grant Nos. PHY-0652548 and PHY-0456890, and theexperimentallymeasuredC (ρ,T)parameteristhe the NASA-Arkansas Space Grants Consortium Award sym symmetry energy E (ρ,T) or the symmetry free en- ASU15154. sym [1] B.A. Li, C.M. Ko, and W. Bauer, topical review, Int. Rev. C 67, 034611 (2003). Jour. Mod. Phys.E 7, 147 (1998). [19] B.A. Li, C. B. Das, S. Das Gupta, and C. Gale, Phys. 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