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2024年10月30日

Multiplicity dependence of the freezeout parameters in high energy hadron-hadron collisions

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Muhammad Ajaz, Majid Shehzad, Muhammad Waqas, Haifa I. Alrebdi, Momhammad Ayaz Ahmad, Antalov Jagnandan, Shawn Jagnandan, Murad Badshah, Jalal Hasan Baker and Abdul Mosawir Quraishi. Multiplicity dependence of the freezeout parameters in high energy hadron-hadron collisions[J]. Chinese Physics C. doi: 10.1088/1674-1137/ad2a4c
Muhammad Ajaz, Majid Shehzad, Muhammad Waqas, Haifa I. Alrebdi, Momhammad Ayaz Ahmad, Antalov Jagnandan, Shawn Jagnandan, Murad Badshah, Jalal Hasan Baker and Abdul Mosawir Quraishi. Multiplicity dependence of the freezeout parameters in high energy hadron-hadron collisions[J]. Chinese Physics C.  doi: 10.1088/1674-1137/ad2a4c shu
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Multiplicity dependence of the freezeout parameters in high energy hadron-hadron collisions

  • 1. Department of Physics, Abdul Wali Khan University Mardan, Mardan 23200, Pakistan
  • 2. School of Mathematics, Physics and Optoelectronic Engineering, Hubei University of Automotive Technology, Shiyan 442002, China
  • 3. Department of Physics, College of Science, Princess Nourah bint Abdulrahman University, P.O. Box 84428, Riyadh 11671, Saudi Arabia
  • 4. Department of Mathematics, Physics and Statistics, Faculty of Natural Sciences, University of Guyana, 101110 Georgetown, Guyanan, South America
  • 5. Department of Physics, Faculty of Science, University of Tabuk, Tabuk, Kingdom of Saudi Arabia
  • 6. Department of Electrical Engineering, College of Engineering, Qassim University, Unaizah, Saudi Arabia

Abstract: We examined the transverse momentum ($ p_T $) spectra of various identified particles, encompassing both light-flavored and strange hadrons ($ \pi^+ + \pi^- $, $ K^+ + K^- $, $ p + \bar{p} $, ϕ, $ K_s^0 $, $ \Lambda + \bar{\Lambda} $, $ \Xi^- + {\bar{\Xi}}^+ $, and $ \Omega^- + {\bar{\Omega}}^+ $), across different multiplicity classes in proton-proton collisions (p-p) at a center-of-mass energy of $ \sqrt{s}= 7 $ TeV. Utilizing the Tsallis and Hagedorn models, parameters relevant to the bulk properties of nuclear matter were extracted. Both models exhibit good agreement with experimental data. In our analyses, we observed a consistent decrease in the effective temperature (T) for the Tsallis model and the kinetic or thermal freeze-out temperature ($ T_0 $) for the Hagedorn model, as we transitioned from higher multiplicity (class-I) to lower multiplicity (class-X). This trend is attributed to the diminished energy transfer in higher multiplicity classes. Additionally, we observed that the transverse flow velocity ($ \beta_T $) experiences a decline from class-I to class-X. The normalization constant, which represents the multiplicity of produced particles, was observed to decrease as we moved toward higher multiplicity classes. While the effective and kinetic freeze-out temperatures, as well as the transverse flow velocity, show a mild dependency on multiplicity for lighter particles, this dependency becomes more pronounced for heavier particles. The multiplicity parameter for heavier particles was observed to be smaller than that of lighter particles, indicating a greater abundance of lighter hadrons compared to heavier ones. Various particle species were observed to undergo decoupling from the fireball at distinct temperatures: lighter particles exhibit lower temperatures, while heavier ones show higher temperatures, thereby supporting the concept of multiple freeze-out scenarios. Moreover, we identified a positive correlation between the kinetic freeze-out temperature and transverse flow velocity, a scenario where particles experience stronger collective motion at a higher freeze-out temperature. The reason for this positive correlation is that, as the multiplicity increases, more energy is transferred into the system. This increased energy causes greater excitation and pressure within the system, leading to a quick expansion.

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    I.   INTRODUCTION
    • The collision of relativistic heavy nuclei results in a highly unstable, transient state of matter known as Quark Gluon Plasma (QGP), which exists for a short time. Specifically, QGP refers to a strongly interactive state of matter [14] where quarks and gluons are asymptotically free, which is a peculiar behavior. The temperature and energy density of QGP is as high as those of the early universe; owing to this resemblance, QGP constitutes a prominent research topic in high-energy physics, and many collaborations around the globe are working on QGP to explore the conditions of the early universe. The existence of QGP has been confirmed through collisions of heavy nuclei such as Pb-Pb and Au-Au. In addition, many signatures of QGP have been observed in p-p collisions. These collisions mainly provide baselines for heavy-ion collisions. These signatures of QGP may include strangeness enhancement, $ J/\psi $ melting or suppression, and jet quenching. [58].

      We used p-p collisions as references to study the collision mechanism of heavy nuclei at colliders. Recent results obtained from p-p and proton-lead (p-Pb) collisions have shown similar trends to that of Pb-Pb collisions. For instance, spectra of $ p_T $ as a function of transverse mass $ m_T $ have shown the same excitation function with charged hadron multiplicity as that exhibited by larger colliding systems. The analyses of the $ p_T $ distribution in p-p collisions show a clear hardening of the $ p_T $ spectra from multiplicity class-X to class-I, where the average charged particle densities in class-X are lowest while the charged particle densities in class-I are highest, which is the same trend observed in collisions of larger systems [9]. Additionally, it has been found that, in contrast to pions, the event charged-particle multiplicity increases with the integrated yields of strange and multi-strange hadrons [10]. This strangeness enhancement has already been reported for Pb-Pb collisions.

      QGP behaves like a hot fluid that expands and cools down; during its evolution, it passes through many stages, and each stage has its corresponding temperature. The chemical freeze-out temperature corresponds to the chemical freeze-out stage where inelastic collisions among the constituents of the fireball vanish, which results in the stoppage of production of new particles. The underlying reason is that when the fireball expands owing to a pressure gradient, the inter-particle distances at a certain point become so large that the constituents of the fireball cannot interact inelastically [1113]. The thermal freeze-out stage corresponds to the kinetic or thermal freeze-out temperature, where elastic collisions between the generated particles also come to an end [1416]. After the thermal freeze-out stage, the particles move outward, where they may be detected by the detectors, and the particles at the detectors have the same energy and momentum spectra or distribution as they have at the thermal freeze-out stage. This implies that very accurate information about the thermal or kinetic freeze-out stage can be obtained by studying the $ p_T $ spectra of the outgoing particles. The information about the freeze-out stage may include the thermal freeze-out temperature, radial or transverse flow velocity of the outgoing particles, volume of the created system (V) after the collision, and number of particles created or the multiplicity parameter ($ N_0 $).

      The detectors cannot measure the aforementioned freeze-out parameters; therefore, many hydrodynamical and statistical models are used to extract the values of these valuable parameters, which help understand the true nature of QGP. Even after the interactions between particles stop during the evolution of the fireball, the particles still occupy space according to a statistical distribution [17]. The models used for the analysis in the present study and those commonly used are briefly discussed in this paper. The use of non-extensive statistical distributions to analyze the $ p_T $ spectra in high-energy collisions is popular and convenient. In previous studies, a variety of Tsallis distributions have been used to effectively explain the $ p_T $ spectra of produced particles in p-p interactions at RHIC and LHC energies [1823]. The most relevant aspect about using the Tsallis distribution is that it only depends on three parameters, which help fit the experimental data: the first parameter is the effective temperature (T), which includes both thermal and flow effects of the fireball; the second parameter is the non-extensive variable (q), which measures the deviation from the extensive Boltzmann-Gibbs statistics; and the third parameter is the fitting or normalization constant ($ N_0 $). These three parameters can be incorporated to calculate the volume and initial conditions of the system, for example, the initial temperature [24]. To analyze the $ p_T $ distributions of the outgoing particles in high energy nuclei collisions at the LHC and RHIC, various flow models are incorporated into Tsallis statistics. To extract the radial flow velocity and kinetic freeze-out temperature, the Hagedorn formula with embedded transverse flow [2528], Blast-Wave model with Tsallis statistics (TBW model) [29, 30], Blast-Wave model with Boltzmann Gibbs statistics (BGBW model) [31, 32] and Tsallis distribution with flow effect or improved Tsallis distribution [3335] have mainly been used in previous studies.

      The rest of the paper is structured as follows. The "Methodology" section elucidates the statistical models utilized in our analyses. Subsequently, the "Results and Discussion" section presents our findings in detail and provides suitable explanations. Finally, the "Conclusion" section encapsulates the outcomes and deductions drawn from our research.

    II.   METHODOLOGY
    • Experimental $ p_T $ distributions for identified light and strange particles in $ \sqrt{s} $ = 7 TeV p-p collisions were reported in [9] and [10], respectively. The $ p_T $ distributions of particles have a lot of information about the freeze-out stage of QGP. Therefore, these distributions are significant for the extraction of these pieces of information (parameters). Various statistical and hydrodynamical models are used to extract these parameters from $ p_T $ distributions, as described in the "Introduction" section. In the present study, two models, namely the Tsallis and Hagedorn models, were used. The classical exponential function called Boltzmann Gibbs function, given in Eq. (1), is only suitable for low $ p_T $ regions. For high $ p_T $ regions, a power law distribution is more appropriate. The Tsallis function, given in Eq. (2), is one of such power law distribution functions that covers a wide range of $ p_T $.

      $ f(E) \propto {\rm exp} \left(-\frac{E-\mu}{T}\right), $

      (1)

      $ \frac{{\rm d}^2N}{\ N_{\rm evt}\ {\rm d}p_T\ {\rm d}y}=2\ \pi\ C\ p_T \bigg[1+\frac{(q-1)}{T}m_T\bigg]^{-\frac{1}{(q-1)}}, $

      (2)

      In Eq. (2), N, $N_{\rm evt}$, and $ p_T $ represent the number of particles produced in the collision, number of participating particles taking part in the collision, and transverse momentum, respectively [36]; T denotes the effective temperature, encompassing both the thermal and flow effects within the evolving system. The non-extensivity parameter is denoted as q, and C represents the fitting constant, which is directly related to the size or volume of the created system according to the equation $ C=\dfrac{g V}{(2 \pi)^3} $, where V denotes the volume of the system, and g is the degeneracy factor with varying values for different particles [3739]. The transverse mass of the outgoing particle is represented by $ m_T $, calculated using the formula $ m_T= \sqrt{{p_T}^2- {m_0}^2} $, where $ m_0 $ corresponds to the rest mass of the produced particle. The Tsallis distribution function was employed in previous studies in various manners; the most consistent form in thermodynamic terms is as follows:

      $ \frac{{\rm d}^2N}{\ N_{\rm evt}\ {\rm d}p_T\ {\rm d}y}=2\ \pi\ C\ p_T\ m_T \bigg[1+\frac{(q-1)}{T}m_T\bigg]^{-\frac{q}{(q-1)}}. $

      (3)

      It is important to note that the Tsallis model presented in Eq. (2) and Eq. (3) provides insights into the parameter T. However, it does not offer information about $ T_0 $ and $ \beta_T $. In order to extract these two parameters, we employed the Hagedorn model, which incorporates $ \beta_T $. The functional expression for this model is expressed in a simplified form as follows:

      $ \frac{{\rm d}^2N}{\ N_{\rm evt}\ {\rm d}p_T\ {\rm d}y}=2\ \pi\ C \ p_T \bigg[1+\frac{m_T}{nT_0}\bigg]^{-n}, $

      (4)

      where $ T_0 $ is the thermal freeze-out temperature, and n is the entropy parameter. To have a contribution from the transverse flow velocity ($ \beta_T $), we must replace $ m_T $ by $ <\gamma_T> (m_T - P_T <\beta_T>) $ in Eq. (4) [40], where $ <\gamma_T> $is a Lorentz factor. Eq. (5) is the simplest form of the Hagedorn model with embedded $ \beta_T $:

      $ \frac{{\rm d}^2N}{\ N_{\rm evt}\ {\rm d}p_T\ {\rm d}y}=2\ \pi\ C \ p_T \bigg[1+\frac{<\gamma_T> (m_T - P_T <\beta_T>)}{nT_0}\bigg]^{-n}. $

      (5)

      It is important to mention that, in this analysis, we used the minimum $ \chi^2 $ method to fit the theoretical model functions on the experimental transverse momentum spectra of particles. The minimum $ \chi^2 $ method considers combined statistical and systematic errors added in quadrature.

    III.   RESULTS AND DISCUSSION
    • Figures 1(a)−1(h) show the transverse momentum distribution, ${{\rm d}2N}/({\ N_{\rm evt}\ {\rm d}p_T\ {\rm d}y})$, for various light-flavored identified and strange hadrons in 7 TeV p-p collisions categorized into various multiplicity classes. Each plot represents the $ p_T $ distribution for a specific particle type, including $ \pi^++\pi^- $, $ K^++K^- $, $ K_s^0 $, $ p+\bar p $, ϕ, $ \Lambda+\bar\Lambda $, $ \Xi^-+\bar\Xi^+ $, and $ \Omega^-+\bar\Omega^+ $. Within each plot, different colors correspond to different multiplicity classes in the experimental data, while distinct symbols across Figs. 1(a)−1(h) are used for different particle species. Overlaid on these data points, solid and dotted curves depict the fit outcomes derived using the Tsallis distribution (Eq. (3)) and the Modified Hagedorn model with incorporated flow (Eq. (5)), respectively. In some cases, scaling factors are applied to certain spectra to prevent curve and data point overlap within a single plot. These scaling factors are specified alongside each multiplicity class at the upper portion of each plot. During the fitting process, efforts were made to minimize the $ \chi^2 $value for each fit, aiming to achieve high-quality fitting and hence accurate parameter extraction. The parameters extracted by the Tsallis and Hagedorn models are listed in Tables 1 and 2, respectively. The constant "C" in Eqs. (2) to (5) serves as a normalization constant that ensures that the integral of the functions in these equations evaluates to unity; "$ N_0 $" is another normalization constant in Tables 1 and 2, used for comparing the function or model against experimental data. Despite the possibility of absorbing C into $ N_0 $, both constants retain distinct purposes. The presence of both C and $ N_0 $ allows for precise descriptions within the context of the study.

      Figure 1.  (color online) $ p_T $ spectra of the double differential yield of various light-flavored and strange hadrons at a center-of-mass energy of 7 TeV. These spectra were analyzed using both the Tsallis and Hagedorn models, with the results depicted using solid and dotted lines, respectively. The experimental data points are illustrated using diverse colors and shapes. These analyses were conducted across various multiplicity classes.

      EnergyParticleMultiplicity ClassT/MeVq$ N_0 $$ \chi^2 $NDF
      I97.900 ± 2.9371.159 ± 0.035295.400 ± 8.8623.48546
      II93.200 ± 2.7961.159 ± 0.035232.400 ± 6.9723.55346
      III93.200 ± 2.7961.156 ± 0.035189.000 ± 5.673.40146
      IV90.100 ± 2.7031.156 ± 0.035163.000 ± 4.892.94346
      7 TeV$ \pi^+ + \pi^- $V88.500 ± 2.6551.155 ± 0.035144.500 ± 4.3352.68246
      VI86.600 ± 2.5981.154 ± 0.035123.600 ± 3.7082.30446
      VII83.600 ± 2.5081.153 ± 0.03598.800 ± 2.9641.72746
      VIII80.400 ± 2.4121.152 ± 0.03581.400 ± 2.4421.13546
      IX77.700 ± 2.3311.149 ± 0.03458.900 ± 1.7670.59746
      X68.870 ± 2.0661.142 ± 0.03437.600 ± 1.1280.42546
      I144.380 ± 4.3311.145 ± 0.03443.410 ± 1.30218.5241
      II133.500 ± 4.0051.146 ± 0.03433.600 ± 1.00813.51741
      III123.550 ± 3.7071.149 ± 0.03427.200 ± 0.81612.96541
      IV116.520 ± 3.4961.15 ± 0.03523.160 ± 0.69510.17941
      7 TeV$ K^+ + K^- $V111.940 ± 3.3581.151 ± 0.03520.260 ± 0.6087.34441
      VI105.920 ± 3.1781.151 ± 0.03516.950 ± 0.5097.03641
      VII97.570 ± 2.9271.152 ± 0.03513.420 ± 0.4036.40841
      VIII90.280 ± 2.7081.153 ± 0.03510.760 ± 0.3233.45541
      IX78.540 ± 2.3561.153 ± 0.0357.740 ± 0.2322.98841
      X54.520 ± 1.6361.153 ± 0.0354.590 ± 0.13811.35341
      I151.180 ± 4.5351.141 ± 0.03421.310 ± 0.6399.62735
      II136.390 ± 4.0921.145 ± 0.03416.600 ± 0.49815.06235
      III130.120 ± 3.9041.145 ± 0.03413.380 ± 0.4018.39135
      IV129.260 ± 3.8781.142 ± 0.03411.410 ± 0.34215.11535
      7 TeV$ K_S^0 $V125.460 ± 3.7641.142 ± 0.0349.940 ± 0.29817.69835
      VI117.220 ± 3.5171.144 ± 0.0348.360 ± 0.25117.01535
      VII106.880 ± 3.2061.146 ± 0.0346.650 ± 0.2000.19835
      VIII99.920 ± 2.9981.147 ± 0.0345.280 ± 0.1580.17935
      IX90.940 ± 2.7281.146 ± 0.0343.760 ± 0.1130.16535
      X75.180 ± 2.2551.143 ± 0.0341.190 ± 0.03622.74135
      I176.160 ± 5.2851.114 ± 0.03317.430 ± 0.52323.57539
      II155.470 ± 4.6641.117 ± 0.03413.890 ± 0.41738.49939
      III140.000 ± 4.2001.118 ± 0.03411.440 ± 0.34331.56439
      IV128.250 ± 3.8481.119 ± 0.0349.890 ± 0.29718.78939
      7 TeV$ p+\bar{p} $V120.630 ± 3.6191.12 ± 0.0348.720 ± 0.26228.60239
      VI110.990 ± 3.3301.122 ± 0.0347.320 ± 0.2242.15239
      VII106.900 ± 3.2071.117 ± 0.0345.830 ± 0.17539.76539
      VIII100.060 ± 3.0021.115 ± 0.0334.620 ± 0.13950.80439
      IX51.190 ± 1.5361.136 ± 0.0343.440 ± 0.10341.29439
      X29.420 ± 0.8831.131 ± 0.0341.780 ± 0.05329.89339
      Continued on next page

      Table 1.  Values of the free parameters for various identified particles including light-flavored and strange hadrons, derived from the Tsallis model in hadronic collisions at a center-of-mass energy of 7 TeV.

      Table 1-continued from previous page
      EnergyParticleMultiplicity ClassT/MeVq$ N_0 $$ \chi^2 $NDF
      I206.420 ± 6.1931.131 ± 0.0342.650 ± 0.08023.37413
      II191.520 ± 5.7461.131 ± 0.0342.090 ± 0.0639.71713
      III180.210 ± 5.4061.131 ± 0.0341.730 ± 0.05210.11113
      7 TeVϕIV & V167.220 ± 5.0171.132 ± 0.0341.380 ± 0.0414.07413
      VI140.000 ± 4.2001.137 ± 0.0341.050 ± 0.0329.93813
      VII114.090 ± 3.4231.146 ± 0.0340.820 ± 0.0253.60813
      VIII103.150 ± 3.0951.145 ± 0.0340.630 ± 0.0195.4513
      IX76.530 ± 2.2961.151 ± 0.0350.450 ± 0.0146.2813
      X33.230 ± 0.9971.152 ± 0.0350.260 ± 0.0083.0713
      I233.120 ± 6.9941.091 ± 0.03312.280 ± 0.3688.10713
      II205.870 ± 6.1761.095 ± 0.0339.570 ± 0.2875.73813
      III195.170 ± 5.8551.094 ± 0.0337.670 ± 0.2305.82213
      IV166.970 ± 5.0091.102 ± 0.0336.550 ± 0.1974.74613
      7 TeV$ \Lambda + \bar{\Lambda} $V154.150 ± 4.6251.104 ± 0.0335.710 ± 0.1714.15213
      VI141.830 ± 4.2551.105 ± 0.0334.710 ± 0.1416.03413
      VII115.630 ± 3.4691.112 ± 0.0333.700 ± 0.1114.75313
      VIII105.300 ± 3.1591.112 ± 0.0332.850 ± 0.0866.54113
      IX79.380 ± 2.3811.117 ± 0.0341.920 ± 0.0589.90813
      X40.920 ± 1.2281.124 ± 0.0340.850 ± 0.02612.07213
      I281.770 ± 8.4531.081 ± 0.0321.550 ± 0.0476.86710
      II271.550 ± 8.1471.077 ± 0.0321.130 ± 0.0344.94510
      III260.930 ± 7.8281.072 ± 0.0320.900 ± 0.0277.46510
      IV255.860 ± 7.6761.072 ± 0.0320.730 ± 0.0226.73810
      7 TeV$ \Xi^- + \bar{\Xi}^+ $V226.900 ± 6.8071.079 ± 0.0320.620 ± 0.0196.2110
      VI202.860 ± 6.0861.084 ± 0.0330.510 ± 0.0157.54410
      VII181.730 ± 5.4521.087 ± 0.0330.380 ± 0.0116.45110
      VIII152.780 ± 4.5831.094 ± 0.0330.290 ± 0.0098.32710
      IX105.560 ± 3.1671.108 ± 0.0330.180 ± 0.0055.910
      X91.010 ± 2.7301.102 ± 0.0330.070 ± 0.00211.78110
      I + II292.630 ± 8.7791.079 ± 0.0320.140 ± 0.0042.633
      III + IV275.340 ± 8.2601.079 ± 0.0320.080 ± 0.0021.5833
      7 TeV$ \Omega^- + \bar{\Omega}^+ $V + VI234.160 ± 7.0251.079 ± 0.0320.080 ± 0.0021.5253
      VII + VIII188.450 ± 5.6541.080 ± 0.0320.030 ± 0.0013.4113
      IX + X106.850 ± 3.2061.090 ± 0.0330.010 ± 0.0009.7233
      EnergyParticleMultiplicity class$ T_0 $/MeV$ \beta_T $ /cn$ N_0 $$ \chi^2 $NDF
      I80.500 ± 2.4150.413 ± 0.0126.350 ± 0.191303.030 ± 9.0912.94346
      II76.220 ± 2.2870.410 ± 0.0126.340 ± 0.190237.600 ± 7.1282.63946
      III72.720 ± 2.1820.409 ± 0.0126.340 ± 0.190195.600 ± 5.8682.41746
      IV70.560 ± 2.1170.407 ± 0.0126.340 ± 0.190169.100 ± 5.0732.08746
      7 Tev$ \pi^+ + \pi^- $V68.760 ± 2.0630.403 ± 0.0126.350 ± 0.191150.300 ± 4.5091.91146
      VI66.580 ± 1.9970.401 ± 0.0126.370 ± 0.191128.200 ± 3.8461.57546
      VII63.030 ± 1.8910.400 ± 0.0126.380 ± 0.191104.120 ± 3.1241.23446
      VIII60.190 ± 1.8060.400 ± 0.0126.400 ± 0.19284.980 ± 2.5490.86846
      IX55.340 ± 1.6600.399 ± 0.0126.470 ± 0.19465.310 ± 1.9590.71146
      X45.410 ± 1.3620.396 ± 0.0126.660 ± 0.20042.040 ± 1.2611.54646
      I112.800 ± 3.3840.298 ± 0.0096.660 ± 0.20043.170 ± 1.2955.87341
      II104.000 ± 3.1200.290 ± 0.0096.600 ± 0.19833.340 ± 1.00013.82841
      III96.680 ± 2.9000.281 ± 0.0086.530 ± 0.19627.000 ± 0.81014.79941
      IV91.020 ± 2.7310.270 ± 0.0086.450 ± 0.19422.970 ± 0.68913.01341
      7 Tev$ K^+ + K^- $V86.780 ± 2.6030.264 ± 0.0086.420 ± 0.19320.060 ± 0.60211.95841
      VI81.890 ± 2.4570.258 ± 0.0086.400 ± 0.19216.780 ± 0.50312.2141
      VII74.720 ± 2.2420.251 ± 0.0086.360 ± 0.19113.290 ± 0.39910.83341
      VIII67.450 ± 2.0240.248 ± 0.0076.320 ± 0.19010.600 ± 0.3188.6141
      IX56.990 ± 1.7100.245 ± 0.0076.330 ± 0.1907.580 ± 0.2279.83841
      X46.430 ± 1.3930.163 ± 0.0056.420 ± 0.1934.390 ± 0.1325.42141
      I137.120 ± 4.1140.223 ± 0.0076.960 ± 0.20921.420 ± 0.64320.38935
      II128.670 ± 3.8600.212 ± 0.0066.890 ± 0.20716.570 ± 0.4970.31235
      III121.200 ± 3.6360.209 ± 0.0066.870 ± 0.20613.430 ± 0.4030.23335
      IV116.810 ± 3.5040.188 ± 0.0066.810 ± 0.20411.470 ± 0.3440.24635
      7 TeV$ K_S^0 $V109.010 ± 3.2700.187 ± 0.0066.710 ± 0.20110.050 ± 0.3020.24835
      VI104.030 ± 3.1210.175 ± 0.0056.660 ± 0.2008.390 ± 0.2520.24935
      VII95.960 ± 2.8790.168 ± 0.0056.630 ± 0.1996.690 ± 0.2010.35935
      VIII87.330 ± 2.6200.160 ± 0.0056.520 ± 0.1965.320 ± 0.1600.29235
      IX70.090 ± 2.1030.155 ± 0.0056.360 ± 0.1913.850 ± 0.1160.32835
      X54.970 ± 1.6490.154 ± 0.0056.550 ± 0.1972.080 ± 0.06223.98535
      I154.160 ± 4.6250.171 ± 0.0058.440 ± 0.25317.280 ± 0.51819.25939
      II137.260 ± 4.1180.169 ± 0.0058.370 ± 0.25113.670 ± 0.41033.51539
      III122.490 ± 3.6750.147 ± 0.0048.160 ± 0.24511.290 ± 0.33926.9539
      IV118.490 ± 3.5550.118 ± 0.0048.160 ± 0.2459.750 ± 0.29316.76339
      7 TeV$ p + \bar{p} $V110.590 ± 3.3180.116 ± 0.0038.100 ± 0.2438.600 ± 0.25825.73939
      VI105.590 ± 3.1680.097 ± 0.0038.050 ± 0.2427.190 ± 0.21639.37739
      VII96.090 ± 2.8830.051 ± 0.0027.920 ± 0.2385.880 ± 0.17621.05539
      VIII90.290 ± 2.7090.031 ± 0.0017.920 ± 0.2384.730 ± 0.14216.88739
      IX32.090 ± 0.9630.031 ± 0.0016.900 ± 0.2073.330 ± 0.10043.80339
      X19.520 ± 0.5860.025 ± 0.0017.420 ± 0.2231.810 ± 0.05418.8739
      Continued on next page

      Table 2.  Values of the free parameters for distinct identified particles including light-flavored and strange hadrons, obtained through the application of the Hagedorn model at a center-of-mass energy of 7 TeV.

      Table 2-continued from previous page
      EnergyParticleMultiplicity class$ T_0 $/MeV$ \beta_T $/cn$ N_0 $$ \chi^2 $NDF
      I185.940 ± 5.5780.188 ± 0.0067.550 ± 0.2272.63 ± 0.07921.65713
      II165.530 ± 4.9660.214 ± 0.0067.620 ± 0.2292.05 ± 0.0626.60913
      III150.430 ± 4.5130.228 ± 0.0077.580 ± 0.2271.680 ± 0.0509.05613
      IV & V135.000 ± 4.0500.232 ± 0.0077.540 ± 0.2261.330 ± 0.0404.30913
      7 TeVϕVI118.400 ± 3.5520.237 ± 0.0077.510 ± 0.2251.000 ± 0.0307.03813
      VII92.070 ± 2.7620.203 ± 0.0066.880 ± 0.2060.780 ± 0.0234.74913
      VIII68.940 ± 2.0680.196 ± 0.0066.670 ± 0.2000.610 ± 0.0185.413
      IX46.620 ± 1.3990.151 ± 0.0056.340 ± 0.1900.430 ± 0.0137.8513
      X5.690 ± 0.1710.159 ± 0.0056.340 ± 0.1900.240 ± 0.0076.31613

      To begin with the discussion of parameter trends, we introduce the plots in Fig. 2. As observed in Fig. 2 (i) and 2 (ii), a noticeable decrease in both T and $ T_0 $ is apparent when transitioning from multiplicity class I to class X. This trend can be attributed to the fact that, in multiplicity class I, a substantial portion of the colliding systems significantly overlaps, leading to a reduction in overlap as one progresses toward higher multiplicity classes. Consequently, this decrease in overlap results in a diminished energy transfer among the nucleons within the colliding systems. Note that T and $ T_0 $ in Fig. 2 (i) and 2 (ii) are consistent with a mass differential scenario compatible with [41] and our previous results [4244]. A higher temperature causes heavier particles to decouple from the system earlier than lighter particles. The reason behind the early freeze-out of the massive particles is that they have lower production rates due to higher energy requirements. Therefore, they become less abundant and more susceptible to freeze-out at higher temperatures compared to lighter particles. Besides, we observed that the temperature (effective and kinetic freeze-out temperatures) of the lighter particles is weakly dependent on multiplicity while this dependence becomes more significant as the particle mass increases, which is consistent with the results reported by Khuntia et al. [41]. A possible explanation for this phenomenon could be as follows. Light particles have a lower kinetic freeze-out temperature, indicating weaker interactions with the surrounding medium. As a result, they are less responsive to variations in multiplicity. Conversely, heavier particles interact more strongly with the medium, rendering them more susceptible to changes in multiplicity. In addition, the values of transverse flow velocity in Fig. 2 (iii) were observed to be minimum at higher multiplicity classes and maximum at lower classes of multiplicity. In scenarios with lower multiplicity classes, more energy is transferred into the system, leading to a stronger pressure gradient in the collision zone and the creation of a highly compressed system. This compressed system holds considerable collision energy in potential form. Consequently, as the system begins to expand, it does so with a notably high transverse flow velocity. Conversely, higher multiplicity classes involve lesser energy transfer into the system, resulting in a less pronounced pressure gradient within the collision zone. This leads to a lower level of compression in the system, ultimately causing the expanding system to have a lower transverse flow velocity. Similar to $ T_0 $, $ \beta_T $ also has a strong dependence on multiplicity for heavier particles and weak dependence on multiplicity for lighter particles. The correlation between $ T_0 $ and $ \beta_T $ is revealed to be positive in Fig. 3. The positive correlation is related to the high temperature and quick expansion of the system. The lower multiplicity class refers to the central collisions, whereas the higher multiplicity class refers to the peripheral collisions. Hence, the above results show that the lower multiplicity class reaches a very high temperature and expands quickly. In previous studies [14], the correlation between $ T_0 $ and $ \beta_T $ is negative. Both positive and negative correlations are correct and have their own explanations. The negative correlation is associated to the longer-lived fireball in lower multiplicity classes. The positive correlation between kinetic freeze-out temperature and transverse flow velocity indicates that, in high-energy collisions, particles with higher thermal energies also exhibit stronger collective motion. The higher multiplicity is associated with the higher energy transfer into the system, owing to which the excitation function of the system increases, resulting in the hadronization of highly thermalized particles. By contrast, owing to the fact that the same higher energy is transferred into the system at higher multiplicity, the system squeezes and then expands rapidly with greater $ \beta_T $. Therefore, greater $ \beta_T $ will always be accompanied by greater $ T_0 $ , and vice versa. Finally, the multiplicity parameter ($ N_0 $) exhibits a decline as the masses of produced particles increase, indicating a more prominent production of lighter particles in contrast to heavier ones. Additionally, $ N_0 $ demonstrates a diminishing trend as one progresses toward higher multiplicity classes. The connection between higher multiplicity classes and lower collision energies or centrality of particle collisions might explain the smaller values of $ N_0 $ in these scenarios.

      Figure 2.  (color online) Correlation plots showing diverse parameters obtained through the fitting of $ p_T $ spectra for various light-flavored and strange hadrons generated in proton-proton collisions at a center-of-mass energy of $ \sqrt{s} $ = 7 TeV across different multiplicity classes. The fitting process involves the utilization of both the Tsallis and Hagedorn models. These correlation plots offer insights into the relationships between the extracted parameters.

      Figure 3.  (color online) Correlation plot depicting the relationship between the kinetic freeze-out temperature ($ T_0 $) and transverse flow velocity ($ \beta_T $). These parameters were extracted through a fitting procedure applied to the $ p_T $ spectra of light-flavored and strange hadrons produced in proton-proton collisions at a center-of-mass energy of $ \sqrt{s} $ = 7 TeV. This fitting procedure was carried out by employing the Hagedorn model. The resulting correlation plot provides insights into the interplay between $ T_0 $ and $ \beta_T $.

    IV.   CONCLUSIONS
    • The analysis of transverse momentum spectra for identified particles, encompassing both light-flavored and strange hadrons, was based on the Tsallis and Hagedorn models. It was found that both models satisfactorily fit experimental data. We extracted the effective temperature (T), kinetic freeze-out temperature ($ T_0 $), and transverse flow velocity ($ \beta_T $). These parameters exhibited an increase as we moved toward lower multiplicity classes, driven by the higher energy transfer in such cases. It is important to highlight that both $ T_{\rm eff} $ and $ T_0 $ exhibited an upward trend with the rising masses of particle species, thereby confirming the existence of a multi-freeze-out scenario. In this scenario, lighter particles experience freeze-out later than heavier particles.

      The normalization constant, or multiplicity parameter, exhibits a direct correlation with collision event multiplicity, underscoring reduced particle production in higher multiplicity classes. In contrast, this constant exhibits an inverse relationship with the masses of the generated particles, indicating diminished production of heavier hadrons compared to lighter ones. A weak dependence of temperature (effective and kinetic freeze-out) on multiplicity was observed for lighter particles, while heavier particles exhibited a strong temperature dependence. One possible explanation for this trend is as follows. Light particles tend to possess a lower kinetic freeze-out temperature, indicating less interaction with the surrounding medium. Consequently, they exhibit reduced sensitivity to shifts in multiplicity. Conversely, heavier particles engage in stronger interactions with the medium, rendering them more responsive to changes in multiplicity.

      Moreover, our study reveals a positive correlation between transverse flow velocity and kinetic freeze-out temperature. This positive correlation suggests that there is a higher degree of excitation in the lower multiplicity classes (higher multiplicity events), which corresponds to higher temperatures and quick expansion.

    Credit authorship contribution statement
    • M. Ajaz: Conceptualization, Methodology, Writing original draft. M. Shehzad: Formal analysis, Visualization. M. Waqas: Formal analysis, Visualization. H. I. Alrebdi: Methodology, Writing review & editing, Funding acquisition, Visualization. A. Jagnandan: Software, Methodology. M. A. Ahmad: Software, Methodology. S. Jagnandan: Software, Formal analysis. M. Badshah: Methodology, Writing original draft. J. H. Baker: Methodology, Investigation, Writing review & editing. A. M. Quraishi: Supervision, Methodology.

    Declaration of competing interest
    • The authors declare that there are no known financial interests or personal relationships that could have potentially influenced the findings presented in this paper.

    Data Availability
    • The data utilized in this study are either provided within the manuscript itself or appropriately referenced at relevant points.

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