constraints on symmetry energy and n/p effective mass splitting with hics
DESCRIPTION
HIRFL-RIBLL 合作体第 2 次会议,上海. Constraints on symmetry energy and n/p effective mass splitting with HICs. Yingxun Zhang ( 张英逊 ). China Institute of Atomic Energy. Outline. 1, Symmetry energy and n/p effective mass splitting. - PowerPoint PPT PresentationTRANSCRIPT
Constraints on symmetry energy and n/p effective mass splitting with HICs
Yingxun Zhang (张英逊 )
China Institute of Atomic Energy
HIRFL-RIBLL 合作体第 2 次会议,上海
Outline
1, Symmetry energy and n/p effective mass splitting
2, Probing symmetry energy and n/p effective mass splitting with new version of ImQMD
A, new version of ImQMD (ImQMD-Sky)B, Ri and Ri(y) C, DR(n/p)D, DR(n/p) at higher beam energy
3, Conclusions
Isospin asymmetric Equation of State
S(r) is the density dependence of symmetry energy, it is a key ingredient of the isospin asymmetric EOS. However, S(r) uncertainty
)(0,, 42 OSEE
It is a fundamental properties of nuclear matter, and is very important for understanding • properties of nuclear structure • properties of neutron star• properties of heavy ion reaction mechanism
S(r)
(MeV
)
1, Symmetry energy and n/p effective mass splitting
Constraining Symmetry energy with heavy ion collisions
Heavy Ion Collisions large regions of r, T, d ,
• measure isospin sensitive observables, such as: the N/Z ratios of the emitted particles (n/p ratios, isospin diffusion, t/He3, N/Z ratios of IMFs, flow, pi-/pi+, ……)
1. the symmetry energy information can be extracted. Indirectly! (depends on models)
• compare with the prediction from the transport model,
Recent progress: constraints on symmetry energy at subsaturation density
• Ri: M.B. Tsang, Yingxun Zhang, LWChen, BALi, M.Colonna, Coupland et al• DR(n/p): Famiano, BALi, Yingxun Zhang, S.Kumar, YGMa, ZQFeng , ……
• IAS: Danielewicz, et.al.,• PDR(Pb): A. Klimkiewicz, ….• N-Star, A.Steiner, ….• FRDM: P. Moller, .. ; Mass: M. Liu, FSZhang, et.al. ,• M_12, F.Amorini, …….• alpha-decay, JM Dong, WZuo, …
ImQMD (DR, Ri, R7) 50MeV/A, 35MeV/A,
Challenges in the constraints on symmetry energy: Different in detail !
M.B.Tsang, Yingxun Zhang, et.al., PRL2009
• different NN interactions or EDF (Skyrme, Gogny, …..) or cross sections are adopted among these models
Momentum dependence of symmetry potential is the most important one among these factors
……momentum dependence of symmetry potential, which would lead to very different magnitude and density …, effective mass of nucleons…, is expected to significantly affect the n/p ratios, …..
Y.X.Zhang, et.al., PLB664, 145(2008); from BALi, et.al., PRL and PLB
Example,
However, Momentum dependence of symmetry potential (n/p effective mass splitting)is Uncertainty! We need to constrain it as well as density dependence of symmetry energy.
Besides depending on the nuclear density, the symmetry energy also depends on the momentum or energy of a nucleon.
S()=K+Sloc()+Snlc(,k)
For cold nuclear matter
m_n*<m_p*
m_n*>m_p*
• Several works has been done for proposing the HIC observables which are sensitive to the momentum dependence of symmetry potential(or n/p effective mass splitting).
• J.Rizzo, et.al., Phys.Rev.C (2005), n/p (p_t)• H.H.Wolter, et.al.,; t/He3 (p_t) ;• Z.Q Feng, et.al. PLB2012, DR(n/p) (pt), DR(t/He3) (pt),• …….
Here, we would like to constrain the symmetry energy and n/p effective mass splitting simultaneously by comparing HIC data with the transport model calculations.
• Constraints on the n/p effective mass splitting (mn*>mp*) has been obtained by analyzing nucleon-nuclei optical potential data. (B.A.Li, C. Xu, et.al., PRC2006,2010).
CXu,BALi,LWChen, PRC82,054607
1. The Skyrme parameter sets have been adjusted for fitting the properties of nuclear matter, binding energy, actinide fission barrier, masses, …… Thus, E0, K0, S0, L, Ksym, m*_s, m*_v, ……. are correlated.
2. In Skyrme EDF, one can easily choose different values S0, L, Ksym, m*_s, m*_v for similar K_0.
3. If one use the Skyrme interaction in transport models, one could get the constraints on Skyrme parameters, also on symmetry energy and n/p effective mass splitting from reaction data simultaneously.
One of best choices in transport models is to use full Skyrme EDF
New version of ImQMD
YX Zhang, ZXLi, HLiu, Tsang(2012)
Changes:
2, Probing the symmetry energy and n/p effective mass splitting
Para. Rho_0 E0 K0 Q0 J L Ksym m*_s m*_n/m*_p
SLy4 0.16 -15.97 229.91 363.11 32 46 -120 0.69 <1
SkI2 0.158 -15.78 240.93 339.70 33 104 71 0.68 <1SkM* 0.16 -15.77 216.61 386.09 30 46 -156 0.79 >1
Gs 0.158 -15.59 237.29 348.79 31 93 14 0.78 >1
Small L Large L
m_n*<m_p* SLy4 (L=46MeV) SkI2 (L=104MeV)
m_n*>m_p* SkM* (L=46MeV) Gs (L=93MeV)
Select four parameter sets
K0 = 230 ± 20MeV, S0 = 32 ± 2MeV, different L and n/p effective mass splitting.
Density dependence of symmetry energy , and the symmetry potential as a function of nucleon energy
• The Larger the L is, the smaller the symmetry energy at <rho0 is.• The larger the Usym is, the larger the n/p ratio is
Zhang, Li, Liu, Tsang (2012)
Isospin diffusion and isospin transport ratios as a function of rapidity
For m*n<m*p, the isospin diffusion process is accelerated due to larger Lane potential at subsaturation density.
Ri=(2X-XAA-XBB)/(XAA-XBB)In absence of isospin diffusion R=1 or R=-1, R~0 for isospin equilibrium
Isospin diffusion occurs only in asymmetric systems A+B, and diffusion ability depends on the symmetry energy and n/p effective mass splitting.
Ri(SLy4, L=46MeV, m*_n<m*_p)<Ri(SkM*, L=46MeV, m*_n>m*_p) < Ri(SkI2, L=104MeV, m*_n<m*_p)<Ri(Gs, L=93MeV, m*_n>m*_p)
Ri is more sensitive to L than n/p effective mass splitting.
A=124Sn, B=112Sn
Chi-square analysis on Ri(y)Chi-Square
SLy4 9.41SkM* 1.62SkI2 22.64Gs 22.52
The Ri(y) data fit the results from SkM* among four parameter sets.
SkM*:S0=30MeV, L=46Mev, Ksym=-156MeV, m*=0.79 and m*n>m*p
The calculated results of Ri from SLy4 and SkM* can fall in the data range.
For SLy4 and SkM*, they have S0=30-32MeV, L=46MeV
n/p and DR(n/p) ratios as a function of kinetic energy
Ebeam=50AMeV, 124Sn+124Sn, 112Sn+112Sn
kp
knpn dEdM
dEdMpYnYR//)(/)(/ DR(n/p)=Rn/p(124)/Rn/p(112)
• The Larger the L is, the smaller the n/p ratio is.
• m*n<m*p enhance the Y(n)/Y(p) ratios at higher kinetic energy region.
• DR(n/p) ratios are sensitive to the n/p effective mass splitting.
Y(n)/Y(p) and DR(n/p) are more sensitive to n/p effective mass splitting than L
n/p and DR(n/p) at different beam energy
• For higher beam energy, the Y(n)/Y(p) obtained with m*n>m*p
are greater than that with m*n<m*p cases at lower beam energy.
Cross overSLy4 (S0=32MeV, L=46MeV, m*n<m*p)SkM*(S0=30MeV, L=46MeV, m*n>m*p)
3, Conclusion1, Developed a new version of ImQMD which can accommodate the Standard Skyrme interaction in parameters. It can bridge the reaction and structure study by using same EDF.
2, The Ri and Ri(y) support the SLy4 and SkM* interactions, they have L=46MeV.
3, Isospin diffusion data Ri(y) prefer to SkM*, the neutron effective mass is greater than proton effective mass (mn*>mp*), but it is not a strong constraint with deep chi-2 minimum.
4, neutron proton effective mass splitting (isospin dependent MDI) plays an important role on the Y (n)/Y (p) ratios of transverse emitted nucleons at high kinetic energy.
5, The n/p effective nucleon masses should be further studied at intermediate energy per nucleon and more calculations are needed.
Thanks for your attention!
合作者: Zhuxia Li (李祝霞) China Institute of Atomic Energy, Hang Liu (刘航) Texas Advanced Computer center, University of Texas, M.B.Tsang (曾敏儿) NSCL/Michigan State University
Charge distribution
Weak dependence on the parameters we selected
Ebeam=50AMeV