2.1 The AMPT model

The AMPT model [22, 23] is a transport model consisting of four main components: initial conditions, partonic interactions, conversion from partonic to hadronic matter, and hadronic interactions. The initial conditions, with spatial and momentum distributions of minijet partons and soft string excitations included, are obtained from the heavy ion jet interaction generator (HIJING) model [24], which is an extension of the PYTHIA model [25]. A Woods–Saxon radial shape is used for the colliding gold nuclei and a parametrized nuclear shadowing function that depends on the impact parameter of the collision [24] is introduced. Scatterings among partons are modeled by Zhang’s parton cascade (ZPC) [26], which at present, includes only two-body elastic scatterings with cross sections obtained from pQCD with screening mass. In the default version of the AMPT model, after the partons stop interacting, they recombine with their parent strings, which are produced from initial soft nucleon–nucleon interactions. The resulting strings are converted to hadrons using the Lund string fragmentation model. However, in the case of the string melting version of AMPT model, the hadrons produced from string fragmentation are converted to their valence quarks and antiquarks. The subsequent partonic interactions are modeled by ZPC. Following the freeze-out of the partons, they are recombined into hadrons by a quark coalescence process. The dynamic evolution of the hadronic phase is subsequently described by an extended relativistic transport (ART) model [27] including baryon–baryon, baryon–meson, and meson–meson elastic and inelastic scatterings. Details of the AMPT model can be found in Ref. [22].

2.2 Quark phase space and charm hadron p_T distributions in the AMPT model

As we focus on the parton scattering effect on charm hadron azimuthal angular correlation study, in the following, the string melting version of the AMPT model (v2.26t5) is employed [23]. In this version of ZPC, two partons undergo scattering every time when they approach each other with a distance smaller than $\sqrt{\sigma /\pi }$ and with a total parton elastic scattering cross section of $\sigma \approx 9\pi {\alpha }_s^2/(2{\mu }^2)$. This transport process in AMPT simulates the parton energy loss in hot QGP medium [22]. We set the strong coupling constant as αs = 0.33 and screening mass as μ = 2.265/fm or 1.241/fm for σ = 3 mb or 10 mb, respectively [22]. Fig. 1 shows the momentum space density of charm quarks together with light quarks and the corresponding charm hadrons in 0–80% Au + Au collisions at $\sqrt{s_{\text{NN}}}$ = 200 GeV from AMPT model. Fig. 1(a) shows the quark rapidity density distributions while Fig. 1(b) shows their transverse momentum spectrum distributions. The charm quarks density dN/dy at mid-rapidity is approximately 0.4 and the rapidity density of light quarks is close to 500.

Fig. 1.Full-screen View

(Color online) (a) Rapidity density of charm quarks $(c+\overline{c})$ and strange quarks $(s+\overline{s})$ as well as light quarks $(u+\overline{u}+d+\overline{d})$ at parton freeze-out in Au + Au collisions at $\sqrt{s_{\text{NN}}}$ = 200 GeV. (b) and (c) shows p_T distributions, for quarks (b) and for the corresponding charm hadrons (c) compared with experimental data [18, 28].

We found that this charm quark density is significantly lower than the result at RHIC energies [18, 28]. To improve the prediction power, we enabled the $\text{c}\overline{\text{c}}$ trigger in HIJING [24], to enhance the total rate of $\text{c}\overline{\text{c}}$ in our study. The physical process of charm quark evolution is identical to that of other charm quarks in the model. The trigger rate is determined by the experimentally measured cross section. For example, to match the rate at RHIC, we randomly triggered half of the full event sample, and the mid-rapidity density of charm quark reached ∼3.6 in the 0–80% central Au + Au collisions at $\sqrt{s_{\text{NN}}}$ = 200 GeV. The AMPT model with similar direction is currently under development [29].

As the inelastic scatterings among partons are not included in the current version of the AMPT model, the quarks produced from the melting of strings scatter uninterruptedly and then freeze out. Those freeze-out charm quarks coalescence with the nearby partons to form hadrons, which continue their evolution in the hadronic medium modeled by ART, and then freeze out, as shown in Fig. 1(c). With the enhanced production of $\text{c}\overline{c}$ in the early stage of the AMPT process, the result of the D meson p_T spectrum from the AMPT model can reasonably reproduce the experimental data. However, the results from the J/ψ p_T spectrum are lower than the data. This can be attributed to the fact, that there is no initial production and dissociation of J/ψ particles in the medium. A prediction for Λc is also presented, which can be found between Ds and J/ψs [cf. Fig. 1(c)].

Then, the history of charm quark interactions was analyzed in AMPT, by tracing the dynamics of parton cascading by the number of collisions (N_scattering) of one charm quark with other partons. The procedure described in Ref. [30] was strictly followed, but with a focus on the charm quarks. Fig. 2(a) shows the probability distributions of the charm quarks freeze-out after N_scattering collisions. In average, partons are subjected to 〈N_scattering〉 = 4-5 Au + Au collisions at $\sqrt{s_{\text{NN}}}$ = 200 GeV with σ = 3 mb and impact parameter b = 8 fm, while the number becomes 8–9 for σ = 10 mb. As can be seen in Fig. 2(b), the average elastic energy loss of a charm quark with p_T is close to 2 GeV/c. The charm quarks continuously lose energy due to the two-body elastic scattering in ZPC. The 〈ΔE〉 is the largest in the first collision, it drops gradually as more collisions occur, and apparently, it stabilizes with larger 〈N_scattering〉. It is understood that the 〈ΔE〉 is smaller in the 10-mb scenario because it typically experiences a larger number of scatterings. Fig. 2(c) shows the average energy loss of charm quarks as a function of their momentum. These values are expected to be similar in the range of σ = 3–10 mb, and their difference is due to the probability distribution of N_scattering. The 〈ΔE〉 increases as the momentum of the charm quark increases, and its value is close to that of the calculation based on a linearized Boltzmann transport model [20].

Fig. 2.Full-screen View

(a) Normalized probability distributions of charm quark freezing-out after N_scattering collisions in AMPT with cross sections of 3 mb and 10 mb, respectively. (b) Corresponding average energy loss of charm quarks with initial transverse momentum of 1.6 lt; p_T lt; 2.0 GeV/c as a function of their number of collisions in ZPC. (c) Average energy loss of charm quarks in different momentum windows.

2.3 Two-particle angular correlation

To study the azimuthal angle dependence of the charm evolution in hot dense medium simulated in AMPT, two-particle angular correlations are used, which is a powerful tool to determine the interaction of the lower energy jet (or parton) with the surrounding medium. The analysis process is described in detail in Refs. [31-34], and we briefly introduce the method in this section. Selected particles from each event are paired for correlations as

while they are combined with particles from different events to build the background distribution

where Δϕ is the relative azimuthal angle and Δ≤ta is the relative pseudorapidity between the particle pair. <>In our analysis, each event is mixed with 10 other events to improve the statistical power of the background estimation, while the direction of the impact parameter of the collisions in the AMPT events is rotated randomly in the transverse plane to calculate B(Δ≤ta,Δϕ). %We also carry out another check by mixing event with similar event plane direction, and the difference between different background reconstructions is found to be negligible. Then, the two-particle correlation function can be obtained as

A one-dimensional Δϕ correlation function can be constructed from the C(Δη,Δϕ) by integrating over Δ≤ta as

where the normalization constant A is given by $N_{\text{pairs}}^{\text{mixed}}/N_{\text{pairs}}^{\text{signal}}$. The distribution of pairs in Δϕ can be expanded to a Fourier series,

The coefficients v_n,n can be directly calculated by

where n = 2,3,4 and N = 200 is the number of Δϕ bins. The harmonic flow coefficients vn (n = 2,3,4) can be calculated as $v_n=v_{n\mathrm{,}n}/\sqrt{\left|v_{n\mathrm{,}n}\right|}$.

2.4 Azimuthal correlation of charm quarks and charm hadrons

The azimuthal anisotropy of charm and light hadrons can be obtained from the two-particle angular correlations as described above. Fig. 3 shows the elliptic flow v₂ of mid-rapidity hadrons as a function of p_T in 0–80% Au + Au collisions at $\sqrt{s_{\text{NN}}}$ = 200 GeV, for πs (Fig. 3(a)), $K_S^0$s (Fig. 3(b)), protons (Fig. 3(c)), and charm hadrons (Fig. 3(d)). Systematically, the AMPT model calculations with a parton cross section of 3 mb generate a smaller elliptic flow than those from 10 mb, and they describe the low p_T data better than results from 10 mb, as shown in Fig. 3. When p_T increases to 1.5 GeV/c and above, results from the AMPT model with a parton cross section of 3 mb underestimate the data. From this p_T range, results from the AMPT model with a parton cross section of 10 mb are closer to the data. As shown in Fig. 2, results in the range of 3––10 mb represent the different number of parton collisions and they are responsible for the difference in the v₂ values. This is also the case for charm hadrons [cf. Fig. 2(d)]. For the D hadron result, as data is only available from p_T gt; 1.0 GeV/c, the AMPT result with a cross section of 10 mb gives better description of the D₀ data. Calculations on Λc and Ds are also available. They follow a similar p_T and parton cross section dependence behavior as those other particles presented in panels (a-d) of Fig. 3. Further measurements of the elliptic flow of Λc and Ds at RHIC energies can help to distinguish the parton cross section dependence of v₂(p_T) behavior.

Fig. 3.Full-screen View

(Color online) Elliptic flow v₂ of mid-rapidity hadrons as a function of p_T in 0–80% Au + Au collisions at $\sqrt{s_{\text{NN}}}$ = 200 GeV. The calculations were performed with total parton cross sections of 3 and 10 mb. The experimental data were obtained from Refs.[4, 35].

Then the charm–charm azimuthal correlations were studied in Au + Au collisions at $\sqrt{s_{\text{NN}}}$ = 200 GeV. Fig. 4 shows the quarks azimuthal correlations, which was performed at the stage of parton freeze-out in ZPC, prior to the hadronization in AMPT. Partons with p_T lt; 2.5 GeV/c were chosen to cover the majority of quarks in the collisions, which required a η gap of (0.8,2.4) between quarks. It should be noted that the kinematic window needs to be adjusted with different acceptance in different experiments. In the case of the total parton cross section of 3 mb (Fig. 4(a)), the charm–charm correlation is suppressed at the near side and enhanced at the far side, which is different from the distributions of light quark azimuthal correlations. This is possibly due to a stronger effect of the initial production on the massive charm quarks, as indicated by the open triangles in Fig. 4 and discussed in Ref. [36]. The increase in the total parton cross section enhances the collision probability among quarks [cf. Fig. 2]; thus, it reduces the difference from the effect of initial production between the charm and light quarks. This can also be seen in Fig. 4(b), with a larger total parton cross section calculation, where the correlations between the charm quarks are nearly the same as light quarks.

Fig. 4.Full-screen View

(Color online) Two-particle azimuthal correlations between charm quarks (open symbols), charm quarks and light quarks (blue stars), and light quarks (red squares) in 0–80% Au + Au collisions at $\sqrt{s_{\text{NN}}}$ = 200 GeV from AMPT: the total parton cross section of 3 mb (a) and 10 mb (b). A scenario of charm–charm azimuthal correlations without parton interaction is also shown in (a).

These charm quarks coalesce into a charm hadron with the nearby quarks and undergo hadronic interaction in the AMPT. Fig. 5 shows the corresponding charm hadron azimuthal correlations together with light hadrons. In the case of the total parton cross section of 3 mb, the correlations between D–π are nearly identical to those of π–π, suggesting hadronization and hadronic scattering effect on the evolution of charm hadrons, while the correlations between D–D are slightly different from those of light hadrons. They have a slightly higher distribution on the far side and a lower distribution on the near side. According to the study with the larger total parton cascade cross section of 10 mb (panel Fig. 4(b)), the correlations between charm hadrons and between light hadrons are the same. Fig. 5(a) shows a calculation of D–D correlations without parton interaction (the 0-mb cross section scenario), which gives a flat distribution along Δϕ. This is a scenario with hadronization and hadronic interaction only, which is similar to the default version of the AMPT model. The comparison of D–D azimuthal correlations among different parton cross section parameters applied in AMPT suggests that the number of parton collisions affects the evolution of charm quarks in QGP medium.

Fig. 5.Full-screen View

(Color online) Two-particle azimuthal correlations of D–D, D–π, and π-π in 0–80% Au + Au collisions at $\sqrt{s_{\text{NN}}}$ = 200 GeV from AMPT: total parton cross section of 3 mb (a) and 10 mb (b). A scenario of D–D correlations without parton interaction is plotted for reference in panel (a).

We also studied the high p_T charm hadron azimuthal correlations in QGP medium. Figure 6 shows the two-particle azimuthal correlations with a trigger particle p_T gt; 5 GeV/c and its associated particle at p_T 2 GeV/c. The correlations are normalized with respect to the number of triggers. The results of charge hadron azimuthal correlations from AMPT partially describe the experimental data, which are slightly different in parton cross sections of 3 and 10 mb, because only elastic scattering is included in the current calculations. For the D–D correlations with small parton cross section, similar to the low p_T azimuthal correlation results, shown in of Fig. 5(a), the high p_T D–D correlations exhibit different behavior than the light flavor charge hadrons, in this case with lower yield on both the near and far sides. For the case of 10-mb parton cross section, correlations between D–D are similar to light charge hadrons on the far side, and lower on the near side, as shown in Fig. 5(b).

Fig. 6.Full-screen View

(Color online) The two-particle azimuthal correlations of D-D, D-h^±, and h^±-h^± in 0–80% Au + Au collisions at $\sqrt{s_{\text{NN}}}$ = 200 GeV, with a trigger particle of p_T gt; 5 GeV/c and associated particle of p_T 2 GeV/c. Experimental data on charge hadron azimuthal correlation is obtained from Ref. [37].