×
近期发现有不法分子冒充我刊与作者联系,借此进行欺诈等不法行为,请广大作者加以鉴别,如遇诈骗行为,请第一时间与我刊编辑部联系确认(《中国物理C》(英文)编辑部电话:010-88235947,010-88236950),并作报警处理。
本刊再次郑重声明:
(1)本刊官方网址为cpc.ihep.ac.cn和https://iopscience.iop.org/journal/1674-1137
(2)本刊采编系统作者中心是投稿的唯一路径,该系统为ScholarOne远程稿件采编系统,仅在本刊投稿网网址(https://mc03.manuscriptcentral.com/cpc)设有登录入口。本刊不接受其他方式的投稿,如打印稿投稿、E-mail信箱投稿等,若以此种方式接收投稿均为假冒。
(3)所有投稿均需经过严格的同行评议、编辑加工后方可发表,本刊不存在所谓的“编辑部内部征稿”。如果有人以“编辑部内部人员”名义帮助作者发稿,并收取发表费用,均为假冒。
                  
《中国物理C》(英文)编辑部
2024年10月30日

Giant dipole resonance parameters from photoabsorption cross-sections

  • The structural effect is believed to have no influence on the decay properties of medium and heavy-mass nuclei at excitation energies above the pairing gap. These properties can be described by statistical properties using so-called photon strength functions for different multipolarities, and directly related to the photoabsorption cross-section ($\sigma_{\rm abs}$). $\sigma_{\rm abs}$ is dominated by the electric giant dipole resonance at $\gamma$ energy $\epsilon_\gamma \leqslant 40$ MeV. In this study, we construct two kinds of systematic giant dipole resonance parameters by fitting the experimental photoabsorption cross-sections. One is based on the microscopic relativistic quasiparticle random phase approximation approach, whereas the other is estimated by the phenomenological models within the Lorentzian representation. Both of them are demonstrated ot efficiently describe the experimental photoabsorption cross-sections available for medium to heavy-mass nuclei, and they can obtain more reliable predictions for the unknown nuclear system.
  • 加载中
  • [1] T. Belgya, O. Bersillon, R. Capote et al, Handbook for Calculations of Nuclear Reaction Data (IAEA-TECDOC, 2006)
    [2] R. Capote, M. Herman, P. Obloinsky et al, Nuclear Data Sheets, 110: 3107 (2009) doi: 10.1016/j.nds.2009.10.004
    [3] V. A. Plujko, I. M. Kadenko, E. V. Kulich et al, in Proc. Workshop on Photon Strength Functions Rel. Topics, Prague, Czech Republic, 17-20 June 2007 (2007)
    [4] P. Dimitriou, R. B. Firestone, S. Siem et al, in European Physical Journal Web of Conferences (2015), vol. 93, p. 06004
    [5] S. Goriely and P. Dimitriou, in Summary Report from the First Research Coordination Meeting, 4-8 April 2016, Vienna, Austria (2016)
    [6] S. Goriely, M. Wiedeking, and P. Dimitriou, in Summary Report from the Second Research Coordination Meeting, 16-20 October 2017, Vienna, Austria (2018)
    [7] M. Wiedeking, D. Filipescu, and P. Dimitriou, in Summary Report from the Third Research Coordination Meeting, 17-21 December 2018, Vienna, Austria (2019)
    [8] S. Goriely and E. Khan, Nuclear Physics A, 706: 217 (2002) doi: 10.1016/S0375-9474(02)00860-6
    [9] IAEA, Handbook on photonuclear data for applications cross sections and spectra (International Atomic Energy Agency, 2000)
    [10] S. G. Kadmenskij, V. P. Markushev, and V. I. Furman, Sov. J. Nucl. Phys. 37 (1983)
    [11] V. A. Plujko, S. N. Ezhov, M. O. Kavatsyuk et al, J. Nucl. Sci. Technol., 2: 811 (2002)
    [12] F. Catara, E. Lanza, M. Nagarajan et al, Nuclear Physics A, 624: 449 (1997) doi: 10.1016/S0375-9474(97)00485-5
    [13] D. Vretenar, N. Paar, P. Ring et al, Nucl. Phys. A, 692: 496 (2001) doi: 10.1016/S0375-9474(01)00653-4
    [14] P. Ring, Z. yu Ma, N. V. Giai et al, Nucl. Phys. A, 694: 249 (2001) doi: 10.1016/S0375-9474(01)00986-1
    [15] N. Paar, P. Ring, T. Nikšić et al, Phys. Rev. C, 67: 034312 (2003) doi: 10.1103/PhysRevC.67.034312
    [16] D. Vretenar, A. Afanasjev, G. Lalazissis et al, Physics Reports, 409: 101 (2005) doi: 10.1016/j.physrep.2004.10.001
    [17] S. Goriely, E. Khan, and M. Samyn, Nuclear Physics A, 739: 331 (2004) doi: 10.1016/j.nuclphysa.2004.04.105
    [18] M. Martini, S. Péru, S. Hilaire et al, Phys. Rev. C, 94: 014304 (2016)
    [19] D. M. Brink, Ph.D. thesis, Oxford University (1955)
    [20] P. Axel, Phys. Rev., 126: 671 (1962) doi: 10.1103/PhysRev.126.671
    [21] J. Kopecky and M. Uhl, Phys. Rev. C, 41: 1941 (1990) doi: 10.1103/PhysRevC.41.1941
    [22] J. Kopecky, M. Uhl, and R. E. Chrien, Phys. Rev. C, 47: 312 (1993) doi: 10.1103/PhysRevC.47.312
    [23] S. Mughabghab and C. Dunford, Physics Letters B, 487: 155 (2000) doi: 10.1016/S0370-2693(00)00792-9
    [24] S. Goriely, Physics Letters B, 436: 10 (1998) doi: 10.1016/S0370-2693(98)00907-1
    [25] M. B. Chadwick, P. Obloinský, P. E. Hodgson et al, Phys. Rev. C, 44: 814 (1991)
    [26] Y. Tian, Z.-y. Ma, and P. Ring, Phys. Rev. C, 79: 064301 (2009)
    [27] B. L. Berman and S. C. Fultz, Rev. Mod. Phys., 47: 713 (1975) doi: 10.1103/RevModPhys.47.713
    [28] S. S. Dietrich and B. L. Berman, Atomic Data and Nuclear Data Tables, 38: 199 (1988) doi: 10.1016/0092-640X(88)90033-2
    [29] Y. P. Popov (Proc. Europhys. Topical Conf., Smolenice, 1982), vol. 10
    [30] S. G. Kadmenskij, V. P. Markushev, and V. I. Furman, Yad. Fiz. 37 (1983)
    [31] N. Otuka, E. Dupont, V. Semkova et al, Nuclear Data Sheets, 120: 272 (2014) doi: 10.1016/j.nds.2014.07.065
    [32] Y. Assafiri and M. Thompson, Nuclear Physics A, 460: 455 (1986) doi: 10.1016/0375-9474(86)90424-0
    [33] B. S. ishkhanov, I. M. kapitonov, E. I. lileeva et al, Moscow State Univ. Inst. of Nucl. Phys. Reports, 27: 711 (2002)
    [34] B. S. Dolbilkin, V. A. Zapevalov, V. I. Korin et al, Ser. Fiz., 30: 349 (1966)
    [35] V. A. Erokhova, M. A. Yolkin, A. V. Izotova et al, Bull. Rus. Acad. Sci. Phys., 67: 1636 (2003)
    [36] V. V. Varlamov, M. E. Stepanov, and V. V. Chesnokov, Bull. Rus. Acad. Sci. Phys., 67: 724 (2003)
    [37] V. V. Varlamov, N. N. Peskov, D. V. Rudenko et al, Tech. Rep. INDC (CCP)-440, P37 (2004)
    [38] V. V. Varlamov, M. A. Makarov, N. N. Peskov et al, Physics of Atomic Nuclei, 78: 634 (2015) doi: 10.1134/S106377881505018X
    [39] B. L. Berman, J. T. Caldwell, R. R. Harvey et al, Phys. Rev., 162: 1098 (1967) doi: 10.1103/PhysRev.162.1098
    [40] V. V. Varlamov, B. S. Ishkhanov, V. N. Orlin et al, Bulletin of the Russian Academy of Sciences: Physics, 74: 833 (2010) doi: 10.3103/S1062873810060225
    [41] V. V. Varlamov, B. S. Ishkhanov, V. N. Orlin et al, Physics of Atomic Nuclei, 79: 501 (2016) doi: 10.1134/S1063778816040219
    [42] A. Veyssiere, H. Beil, R. Bergere et al, Nucl.Phys. A, 159: 561 (1970)
    [43] B. S. Ishkhanov, I. M. Kapitonov, V. I. Shvedunov et al, Yadernaya Fizika, 33: 581 (1981)
    [44] V. V. Varlamov, A. I. Davydov, M. A. Makarov et al, Bull. Rus. Acad. Sci. Phys., 80: 317 (2016) doi: 10.3103/S1062873816030333
    [45] V. V. VARLAMOV, B. S. ISHKHANOV, I. V.MAKARENKO, Rept: Moscow State Univ.Inst.of Nucl.Phys.Reports 9 (2006)
    [46] V. V. Varlamov, B. S. Ishkhanov, and V. N. Orlin, Physics of Atomic Nuclei, 75: 1339 (2012) doi: 10.1134/S1063778812110191
    [47] V. V. Varlamov, B. S. Ishkhanov, V. N. Orlin et al, Physics of Atomic Nuclei, 76: 1403 (2013) doi: 10.1134/S1063778813110148
    [48] A. M. Goryachev, G. N. Zalesnyy, Jour: Izvestiya Akademii Nauk KazSSSR, Ser. Fiz.-Mat., 6: 8 (1978)
    [49] V. V. Varlamov, M. A. Makarov, N. N. Peskov et al, Physics of Atomic Nuclei, 78: 746 (2015) doi: 10.1134/S1063778815060150
    [50] J. T. Caldwell, E. J. Dowdy, B. L. Berman et al, Phys. Rev. C, 21: 1215 (1980) doi: 10.1103/PhysRevC.21.1215
    [51] C. M. McCullagh, M. L. Stelts, and R. E. Chrien, Phys. Rev. C, 23: 1394 (1981) doi: 10.1103/PhysRevC.23.1394
    [52] A. van der Woude, Electric and Magnetic Giant Resonances in Nuclei (WORLD SCIENTIFIC, 1991), chap. II, pp. 99-232
    [53] P. Moller, J. Nix, W. Myers et al, Atomic Data and Nuclear Data Tables, 59: 185 (1995) doi: 10.1006/adnd.1995.1002
  • 加载中

Figures(4) / Tables(4)

Get Citation
Yuan Tian, Xi Tao, Jimin Wang, Xianbo Ke, Ruirui Xu and Zhigang Ge. Giant dipole resonance parameters from photoabsorption cross-sections[J]. Chinese Physics C. doi: 10.1088/1674-1137/43/11/114102
Yuan Tian, Xi Tao, Jimin Wang, Xianbo Ke, Ruirui Xu and Zhigang Ge. Giant dipole resonance parameters from photoabsorption cross-sections[J]. Chinese Physics C.  doi: 10.1088/1674-1137/43/11/114102 shu
Milestone
Received: 2019-07-02
Article Metric

Article Views(2507)
PDF Downloads(56)
Cited by(0)
Policy on re-use
To reuse of subscription content published by CPC, the users need to request permission from CPC, unless the content was published under an Open Access license which automatically permits that type of reuse.
通讯作者: 陈斌, bchen63@163.com
  • 1. 

    沈阳化工大学材料科学与工程学院 沈阳 110142

  1. 本站搜索
  2. 百度学术搜索
  3. 万方数据库搜索
  4. CNKI搜索

Email This Article

Title:
Email:

Giant dipole resonance parameters from photoabsorption cross-sections

    Corresponding author: Yuan Tian, tiany@ciae.ac.cn
    Corresponding author: Ruirui Xu, xuruirui@ciae.ac.cn
  • 1. China Nuclear Data Center, China Institute of Atomic Energy, P.O. Box 275(41), Beijing 102413, China
  • 2. Guangxi Normal University, Guilin, Guangxi Province, 541004, China

Abstract: The structural effect is believed to have no influence on the decay properties of medium and heavy-mass nuclei at excitation energies above the pairing gap. These properties can be described by statistical properties using so-called photon strength functions for different multipolarities, and directly related to the photoabsorption cross-section ($\sigma_{\rm abs}$). $\sigma_{\rm abs}$ is dominated by the electric giant dipole resonance at $\gamma$ energy $\epsilon_\gamma \leqslant 40$ MeV. In this study, we construct two kinds of systematic giant dipole resonance parameters by fitting the experimental photoabsorption cross-sections. One is based on the microscopic relativistic quasiparticle random phase approximation approach, whereas the other is estimated by the phenomenological models within the Lorentzian representation. Both of them are demonstrated ot efficiently describe the experimental photoabsorption cross-sections available for medium to heavy-mass nuclei, and they can obtain more reliable predictions for the unknown nuclear system.

    HTML

    1.   Introduction
    • Photonuclear cross-sections are necessary for energy, safety, and medical applications, as well as for nuclear physics and astrophysics [1, 2]. The total photoabsorption is the fundamental parameter that determines various competitive photonuclear reactions, which can be described using photon strength functions (PSF) [3]. In recent years, to systematically improve the quality of current photonuclear cross-sections and remove unreliable and discrepant data, a new international coordinated research project (CRP) is held by International Atomic Energy Agency (IAEA) to update the IAEA photonuclear data and generate a reference database for PSF in 2016–2020 [47]. Meanwhile, an international measurement collaboration under this CRP, photoexcitation, and neutron emission cross-sections (Phoenix), is also carried out to measure photonuclear data, and a series of new measurements for the $ \gamma $-ray data have been obtained in NewSUBARU, Oslo et al. to support the improvement.

      Among all electric and magnetic transitions with different multipolarities, dipole electric $ \gamma $-transitions (E1) are usually dominant. The total photoabsorption cross-sections above the neutron separation energy are usually described by E1 strength functions [8, 9]. Both microscopic and phenomenological approaches were investigated with generated E1 strength functions in the past.

      In microscopic approaches, the E1 strength function can be derived from many models, such as the finite Fermi systems [10], semi-classical thermodynamic pole approach [11], and random phase approximation (RPA) based the ground description with Hartree-Fock calculations [12] or relativistic mean field calculations [1316]. Recently, the E1 strength function based on the Hartree-Fock-Bogoliubov (HFB) and Quasi-particle RPA (QRPA) model with a realistic Skyrme interaction [8, 17] and Gogny interaction [18] by Goriely et al., is constructed for the entire nuclear chart. Ring et al. used time-dependent relativistic mean field theory to derive the fully self-consistent relativistic quasiparticle random phase approximation (RQRPA) [14, 15].

      In the phenomenological approaches, the photoabsorption cross-section is normally estimated within the Lorentzian representation of the giant dipole resonance (GDR). In spherical nuclei, this depends on the GDR parameters: the peak energy $ E_r $, the width $ \Gamma_r $ and the value $ \sigma_r $ of the photoabsorption cross-section around the GDR energy. In the axially deformed nuclei, it is taken as a sum of two components with two sets of GDR parameters. There are several most frequently used phenomenological models of the photoabsorption cross-sections description: the standard Lorentzian (SLO) model [19, 20], the enhanced generalized Lorentzian (EGLO) model [21, 22], the generalized Fermi-liquid (GFL) model [23], the Hybrid model (GH) [24], the modified Lorentzian (MLO) approach [11], and its simplified version SMLO [3]. The main difference in various phenomenological models is the width $ \Gamma(\epsilon_\gamma) $. The width $ \Gamma(\epsilon_\gamma) $ reflects the description of the collective state damping, and also depends on the temperature.

      In this work, we wish to determine the systematic GDR parameters for nuclei with medium to heavy-mass. In Section 2, details of the theoretical models are described, which are used to calculate the GDR component of the photoabsorption cross-section. Section 3 presents our calculation and the obtained results of the systematic GDR parameters for the entire nuclear chart. Related discussions are also contained in the section. Finally, the work is summarized in Section 4.

    2.   Theoretical formalism
    • The theoretical photoabsorption cross-section $ \sigma_{\rm abs}(\epsilon_\gamma) $ as a function of $ \gamma $-ray energy $ \epsilon_\gamma $ is taken as a sum of the terms

      $ \sigma_{\rm abs}(\epsilon_\gamma) = \sigma_{\rm GDR}(\epsilon_\gamma)+\sigma_{\rm QD}(\epsilon_\gamma), $

      (1)

      where the component $ \sigma_{\rm GDR}(\epsilon_\gamma) $ corresponds to GDR excitation, and $ \sigma_{\rm QD}(\epsilon_\gamma) $ is a quasideuteron contribution (a photoabsorption by a neutron–proton pair), which is taken in accordance with the model proposed by Chadwick et al. [25].

      The GDR component $ \sigma_{\rm GDR}(\epsilon_\gamma) $ of the total photoabsorption cross-section is equal to the photoabsorption cross-section of electric dipole $ \gamma $ rays $ \sigma_{\rm E1}(\epsilon_\gamma) $, which is proportional to the strength function $ S_{\rm E1}(\epsilon_\gamma) $

      $ \sigma_{\rm E1}(\epsilon_\gamma) = \frac{16\pi^3}{9}\frac{e^2}{\hbar c}\epsilon_\gamma S_{\rm E1}(\epsilon_\gamma), $

      (2)

      where the isovector dipole strength function $ S_{\rm E1}(E_\gamma) $ can be calculated by a microscopic model, such as: RQRPA equations [1315, 26]. In standard notation, these equations can be written in matrix form as

      $ \left(\begin{array}{cc} A^J&B^J\\-B^{*J}&-A^{*J} \end{array}\right)\left(\begin{array}{c} X^{\nu J}\\Y^{\nu J} \end{array}\right) = \omega^\nu\left( \begin{array}{c} X^{\nu J}\\Y^{\nu J} \end{array}\right). $

      (3)

      Then, the reduced electric transition probability from the ground to an excited state with angular momentum J and excitation energy $ \omega_\nu $ for a multipole operator $ \hat{Q}^J $ is given by

      $ \begin{split} B(J,\omega_\nu) =& \bigg|\sum\limits_{kk'}(\langle k||\hat{Q}^J||k'\rangle X_{kk'}^{\nu J}+(-1)^{j_k-j_{k'}+J}\langle k'||\hat{Q}^J||k\rangle Y_{kk'}^{\nu J})\\&\times(u_kv_{k'}+(-1)^Jv_ku_{k'})\bigg|^2 . \end{split} $

      (4)

      The isovector dipole strength function $ S_{\rm E1}(E_\gamma) $ can be calculated by

      $ S_{\rm E1}(\epsilon_\gamma) = \sum\limits_\nu\frac{B(1,\omega_\nu)}{\pi}\frac{\Gamma(\epsilon_\gamma)/2}{(\epsilon_\gamma-\omega_\nu)^2+(\Gamma(\epsilon_\gamma)/2)^2}, $

      (5)

      where $ \Gamma(\epsilon_\gamma) $ is the width of the Lorentzian distribution.

      Phenomenological models assume that the total photoabsorption cross-section has a Lorentzian shape with various expressions for the "width" $ \Gamma_r(\epsilon_\gamma) $. The standard Lorentzian (SLO) model [19, 20] is based on the Brink hypothesis. In the SLO model, the width $ \Gamma_r(\epsilon_\gamma) $ is taken as the constant $ \Gamma_r $:

      $ \sigma_{\rm{{GDR,SLO}}}(\epsilon_\gamma) = \sigma_r\Gamma_r \frac{\epsilon_\gamma^2\Gamma_r}{(\epsilon_\gamma^2-E_r^2)^2+[\Gamma_r\cdot \epsilon_\gamma]^2}, $

      (6)

      where $ E_r $ and $ \sigma_r $ are the GDR energy (in $ {\rm MeV} $) and the peak cross-section (in $ {\rm mb} $), respectively. The SLO approach can be used to describe the photon absorption data for medium and heavy-mass nuclei [27, 28]. However, for $ \gamma $-emission, the SLO model underestimates the $ \gamma $-decay spectra at low energies [29].

      In the low energy range, the generalized Fermi liquid (GFL) [23] and the enhanced generalized Lorentzian (EGLO) [21, 22] models are based on Kadmenskij-Markushev-Furman (KMF) model [10, 30] and give a better description of the $ {\rm E1} $ strengths at the energies $ \epsilon_\gamma $ close to zero. The photoaborption cross-section of the EGLO is given by the following expression:

      $ \begin{split} \sigma_{\rm{{GDR,EGLO}}}(\epsilon_\gamma)=& \sigma_r\Gamma_r\epsilon_\gamma\\&\times\left[\frac{\epsilon_\gamma\Gamma_K(\epsilon_\gamma)}{(\epsilon_\gamma^2-E_r^2)^2+\epsilon_\gamma^2\Gamma_K^2(\epsilon_\gamma)}\right.+\left.\frac{0.7\Gamma_K(\epsilon_\gamma = 0)}{E_r^3}\right]\end{split}$

      (7)

      with a width equal to

      $ \begin{split} \;\;\Gamma_K(\epsilon_\gamma)=& C_{\rm coll}(\epsilon_\gamma)(\epsilon_\gamma^2+4\pi T_f^2),\\ C_{\rm coll}(\epsilon_\gamma) =& \frac{\Gamma_\gamma}{\epsilon_\gamma^2}\chi(\epsilon_\gamma) = C_{\rm KMF}\chi(\epsilon_\gamma)\equiv C_k(\epsilon_\gamma) \end{split}, $

      (8)

      where the empirical factor $ \chi(\epsilon_\gamma) $ is obtained from fitting to experimental data,

      $ \chi(\epsilon_\gamma) = k+(1-k)(\epsilon_\gamma-\epsilon_0)/(E_r-\epsilon_0), $

      (9)

      and the parameter k reproduces the experimental $ {\rm E1} $ strength around a reference energy $ \epsilon_0 $; $ \chi(E-\gamma = E_r) = 1 $ and $ C_K(E_r) = C_{\rm KMF} $. The value of the factor k depends on the model adopted to describe the nuclear state density, and was obtained from the average resonance capture data, where $ \epsilon_0 = 4.5 $ MeV. If the Fermi gas model is used, k is given by

      $ k = \left\{ {\begin{array}{*{20}{l}} {1,}&{A<148}\\ {1+0.09(A-148)^2{\rm exp}{-0.18(A-148)}}&{A\geqslant 148}. \end{array}} \right. $

      The expression for the GFL model photoabsorption cross-section has the following form

      $ \begin{aligned} \sigma_{\rm{{GDR,GFL}}}(\epsilon_\gamma) = \sigma_r\Gamma_r\epsilon_\gamma \times \frac{K\cdot E_r\cdot\Gamma_m(\epsilon_\gamma)}{(\epsilon_\gamma^2-E_r^2)^2+K[\Gamma_m(\epsilon_\gamma)\epsilon_\gamma]^2}, \end{aligned} $

      (10)

      where the quantity K depicts the Landau parameters of the quasi-particle interaction in the isovector channel of Fermi system, and the energy-dependent width $ \Gamma_m(\epsilon_\gamma) $ is written as:

      $ \Gamma_m(\epsilon_\gamma) = \Gamma_{\rm coll}(\epsilon_\gamma)+\Gamma_{dq}(\epsilon_\gamma), $

      (11)

      the collisional component is taken as

      $ \Gamma_{\rm coll}(\epsilon_\gamma)\equiv C_{\rm coll}(\epsilon_\gamma^2+4\pi^2T_f^2), $

      (12)

      with $ C_{\rm coll} $ determined by normalizing the total width $ \Gamma_m(\epsilon_\gamma) $ at $ \epsilon_\gamma = E_r $ and $ T_f = 0 $ to the GDR width of a cold nucleus, i.e. $ \Gamma_m(\epsilon_\gamma = E_r) = \Gamma_r $. The component $ \Gamma_{dq} $ is assumed in the following form:

      $ \Gamma_{dq}(\epsilon_\gamma) = C_{dq}\sqrt{\epsilon_\gamma^2\bar{\beta}_2^2+\epsilon_\gamma s_2}, $

      (13)

      where $ C_{dq} = \sqrt{5\ln2/\pi} = 1.05 $; $ s_2 = E_2+\bar{\beta}_2^2\approx217.16/A^2 $ with $ E_{2+} $ as the energy of the first vibrational quadrupole state, and $ \bar{\beta}_2 $ being the effective deformation parameter.

      It can be noted that the SLO, EGLO, and GFL expressions are not consistent with the general relations between the imaginary part of the response function and photoabsorption cross-section. To avoid this shortcoming, the Modified Lorentzian approach (MLO) was proposed [11]. The photoabsorption cross-section within the MLO model has the following form:

      $\begin{split} \sigma_{\rm{{GDR,MLO}}}(\epsilon_\gamma)=& \sigma_r\Gamma_r\epsilon_\gamma\frac{\epsilon_\gamma}{1-\exp(\epsilon_\gamma/T_f)}\\ & \times\frac{\Gamma_\gamma(\epsilon_\gamma)}{(\epsilon_\gamma^2-E_r^2)^2+[\Gamma_\gamma(\epsilon_\gamma)\cdot \epsilon_\gamma]^2}, \end{split} $

      (14)

      where at zero excitation energy $ \Gamma_r = \Gamma_\gamma(\epsilon_\gamma = E_r) $.

      In the case where the excitation energy is not too high and $ \epsilon_\gamma $ ranges from zero up to the GDR energy, the MLO1 width $ \Gamma(\epsilon_\gamma) $ can be expressed as

      $ \Gamma(\epsilon_\gamma) = \left\{ {\begin{array}{*{20}{l}} {a(\epsilon_\gamma+U_f) = aU,}&{\rm{for}} \ \gamma-{\rm{decay}}\\ {a\epsilon_\gamma,}&{\rm{for\ photoabsorption}} \end{array}} \right. $

      (15)

      where $ a = \Gamma_r/E_r = C_{\rm KMF}\cdot \epsilon_\gamma $ if the normalization condition $ \Gamma_r = \Gamma_\gamma(\epsilon_\gamma = E_r) $ is adopted for cold nuclei. This model is denoted as the simplified modified Lorentzian (SMLO) model [3]. The values of the parameter a are obtained by fitting the SMLO shape to the experimental photoabsorption cross-sections in spherical nuclei.

    3.   Calculations and discussion
    • In this section, we construct two kinds of systematic GDR parameters for medium to heavy nuclei. One is based on the microscopic RQRPA calculation. The other is achieved by phenomenological models. The shape of parameters is obtained by fitting the theoretical calculation to the experiment photoabsorption cross-sections from the EXFOR library [31]. In Table 1 and 2 we have listed 47 nuclei, which we use to fit the systematic GDR parameters. Therein are 25 spherical nuclei and 22 axially deformed nuclei.

      nucleuspointsenergy range /MeVRef.def. $ \beta_2 $
      34S2912.0 - 26.0[32]0.00
      40Ar6110.0 - 40.0[33]0.00
      40Ca7011.25 - 28.1[34]0.00
      42Ca15110.0 - 40.0[35]0.00
      44Ca5811.5 - 40.0[35]0.00
      48Ca6010.5 - 40.0[35]0.00
      48Ti5811.5 - 40.0[35]0.00
      51V4110.47 - 32.69[36]0.00
      52Cr11511.5 - 40.0[33]0.00
      90Zr4612.2 - 25.7[37]0.035
      91Zr10110.8 - 30.0[38]0.053
      92Zr10515.8 - 27.8[39]0.053
      94Zr927.85 - 31.0[38]0.063
      112Sn16710.9 - 27.5[40]0.018
      114Sn16810.4 - 27.1[40]0.00
      116Sn2009.70 - 29.6[40]0.00
      117Sn2327.40 - 30.9[40]−0.044
      118Sn2119.40 - 30.7[40]0.00
      119Sn2337.40 - 31.1[40]0.00
      120Sn2079.20 - 29.8[40]0.00
      122Sn1848.90 - 27.2[40]0.00
      124Sn2208.60 - 30.9[40]0.00
      138Ba618.48 - 27.1[41]0.00
      208Pb1017.50 - 37.5[42]0.00
      209Bi1098.01 - 26.4[41]−0.008

      Table 1.  Experimental values of spherical nuclei used to fit systematic GDR parameters.

      nucleuspointsenergy range /MeVRef.def. $ \beta_2 $
      23Na11012.8 - 40.0[43]0.390
      24Mg8211.0 - 29.75[34]0.356
      25Mg1549.4 - 40.0[33]0.323
      27Al15010.2 - 40.0[33]−0.541
      28Si15110.0 - 40.0[33]−0.583
      29Si1588.6 - 40.0[33]−0.334
      63Cu6010.5 - 40.0[33]0.161
      65Cu6010.5 - 40.0[33]−0.155
      80Se689.92 - 28.1[44]0.150
      127I868.78 - 29.5[45]−0.128
      133Cs669.05 - 29.5[41]−0.103
      159Tb1987.70 - 27.4[46]0.288
      181Ta597.50 - 36.5[47]0.248
      182W658.02 - 20.8[48]0.240
      184W658.02 - 20.8[48]0.221
      186W658.02 - 20.8[48]0.210
      186Os451.11 - 19.7[49]0.205
      188Os847.44 - 30.4[49]0.179
      189Os777.44 - 29.9[49]0.170
      190Os847.44 - 30.4[49]0.153
      192Os827.44 - 29.9[49]0.145
      235U385.22 - 18.3[50]0.241

      Table 2.  Experimental values of axially deformed nuclei used to fit systematic GDR parameters.

    • 3.1.   Microscopic GDR parameters

    • In this section, we construct the microscopic GDR parameters within the relativistic quasiparticle random phase approximation (RQRPA) calculation, which is obtained with the NL3 interaction [26]. RQRPA has been proved to be able to provide a reliable description of the GDR centroid and fraction of the energy-weighted sum rule exhausted by the E1 mode. However, this can only be used to solve the spherical nuclei, and if we want to reproduce the photoabsorption cross-section of the experimental data, it is necessary to find a good width of the Lorentzian distribution. In previous RQRPA calculations, the width of the Lorentzian distribution is usually treated as a constant [15, 16]. Here, we follow the method in Ref. [51] and define an energy-dependent width parameter as $ \Gamma(\epsilon_\gamma) = \Gamma\sqrt{\epsilon_\gamma/E_{\rm E1}} $ in Eq.(5), where $ E_{\rm E1} $ is the peak energy of the giant dipole resonance, and $ \Gamma $ is one of the parameters we use to fit the experimental data. To reproduce the photoabsorption cross-section of the experimental data, we add another parameter G in Eq.(2) to adjust the height of the curve of the photoaborption cross-section

      $ \sigma_{\rm E1}(\epsilon_\gamma) = \frac{16\pi^3}{9}\frac{e^2}{\hbar c}G\epsilon_\gamma S_{\rm E1}(\epsilon_\gamma). $

      (16)

      With the help of the MINUIT package, we adjust G and $ \Gamma $ to improve the RQRPA calculation of the photoabsorption cross-section in Table 1. As shown in Table 3, the total $ \chi^2_{\rm tot} $ of the RQRPA with experimental photoabsorption cross-section has been improved more than 10 times.

      $\Gamma$G$\chi_{\rm tot}^2$
      RQRPA2.0 (C)1.0270.0
      RQRPA(fitted)1.59 (ED)0.6521.0

      Table 3.  Parameters and $\chi_{\rm tot}^2$ of microscopic GDR parameters within RQRPA. C depicts constant width of Lorentzian distribution., $ED$ denotes energy-dependent width.

      In Fig. 1, we present the comparison of our microscopic GDR parameters (RQRPA) calculations with the experimental photoabsorption cross-sections and other GDR calculations such as: QRPA, MLO1, and SMLO for 52Cr, 90Zr, 120Sn, and 208Pb. The QRPA calculations are based on the Sly4 Skyrme force [8], and the results of MLO1* are based on the parameters from RIPL-3 [2]. The curves of the SMLO are calculated by phenomenological GDR parameters, which we discuss in the next section. Fig. 1shows that the centroid energy of RQRPA is closer to the experimental GDR energy. By adjusting G and $ \Gamma $ parameters, we can reproduce the experimental photoabsorption cross-section as well as the MLO1*. Our microscopic GDR parameter calculations can be used to estimate the spherical nuclei, and the cross-section for heavy-mass nuclei are lower than the ones obtained by experimental data.

      Figure 1.  (color online) Comparison of SMLO (black solid line) and RQRPA (red dashed line) calculations with experimental photoabsorption cross-sections and other systematic GDR parameters calculations QRPA [8] (blue dash-dot line) and MLO1* from RIPL-3 [2] (magenta dash-dot-dot line) for 52Cr, 90Zr, 120Sn and 208Pb.

    • 3.2.   Phenomenological GDR parameters

    • In this section, systematic GDR parameters, based on phenomenological models, are systematically constructed. As introduced in Section 2, the phenomenological models assume that the total photoabsorption cross-section has a Lorentzian shape. In spherical nuclei, this depends on GDR parameters: the energy $ E_r $, the value $ \sigma_r $ of the photoabsorption cross-section, and width $ \Gamma_r $ at GDR energy. In axially deformed nuclei, this is taken as a sum of two components with two sets of the GDR parameters.

      There are several different models of the photoabsorption cross-section description. The major difference of various models is the expressions for the width of the curve. In the standard Lorentzian model (SLO) [19, 20], the width is adopted as a constant that is equal to the GDR width $ \Gamma_r $. In other models, such as the enhanced generalized Lorentzian model (EGLO) [21, 22], generalized Fermi liquid model (GFL) [23], hybrid model (GH) [24], and modified Lorentzian model (MLO) [11], the width is taken as dependent on the $ \gamma $-ray energy $ \Gamma(\epsilon_\gamma) $. Although in the different models, $ \Gamma(\epsilon_\gamma) $ has various formulas, $ \Gamma_r $ is the only parameter of the $ \gamma $-ray energy dependent width.

      Hence, in our phenomenological GDR parameters, first we have to define three basic values for the photoabsorption cross-section. They are assumed in the form of the mass number A and deformation $ \beta_2 $:

      $ \begin{split}E_r =& a_1(1+a_6I^2)/A^{1/3}+a_2(1+a_7I^2)/A^{1/6},\\ \Gamma_r =& a_3E_r^{a_4}-a_8E_r\beta_2,\\ \sigma_r =& \frac{2}{\pi}a_5\cdot\sigma_{TRK}/\Gamma_r.\end{split}$

      (17)

      where $ a_i(i = 1,\cdots,8) $ are adjustable parameters, $ I = (N-Z)/A $, and $ \sigma_{\rm{{TRK}}} = 60NZ/A $ is the classical dipole Thomas-Reiche-Kuhn sum rule [52]. Comparing with the Eq.(137) in RIPL-3 Ref. [2], we added three extra parts with three more parameters, which correspond to the neutron-proton asymmetry I and deformation $ \beta_2 $ of the nuclei. Our phenomenological GDR parameters are not only for the spherical nuclei, but also can be used to calculate axially deformed nuclei. We adopt the following formula:

      $\begin{split} E_{r,2} =& E_r\frac{1}{b_0}[1-1.51\cdot10^{-2}(a_0^2-b_0^2)],\\ E_{r,1} =& E_{r,2}/\left[0.911\frac{a_0}{b_0}+0.089\right],\\ \Gamma_{r,2} =& b_2E_{r,2}^{b_3}-E_{r,2}b_6\beta_2,\; \; \; \; \Gamma_{r,1} = b_4E_{r,1}^{b_5}-E_{r,1}b_7\beta_2,\\ \sigma_{r,2} =& \sigma_r|1-b_8+b_1\beta_2|,\; \; \; \; \sigma_{r,1} = \sigma_r|b_8-b_1\beta_2|.\end{split}$

      (18)

      where indexes $ 1 $ and $ 2 $ correspond to the collective motion along and perpendicular to the axis of symmetry, respectively, with the relative semi-axes of a spheroid. We added eight parameters $ b_i (i = 1,\cdots,8) $ to change the value of width $ \Gamma_{r} $ and photoabsorption cross-section $ \sigma_r $ with deformation $ \beta_2 $.

      $\begin{split} a_0 =& (1+\alpha_2)/\lambda,\\ b_0 =& (1-0.5\alpha_2)/\lambda,\\ \lambda^3 =& 1+\frac{3}{5}\alpha_2^2+\frac{2}{35}\alpha_2^3. \end{split} $

      (19)

      Effective quadrupole deformation parameters $ \alpha_2 $ or $ \beta_2 $ were determined from ground state deformation parameters $ \beta_n\equiv\alpha_n/\sqrt{(2n+1)/4\pi} $, with the nuclear radius expansion expressed in spherical harmonics. $ \beta_n $ parameters were provided by Ref. [53].

      In Table 4, we display all the phenomenological GDR parameters and total $ \chi^2 $-values of MLO1, MLO2, MLO3, EGLO, GFL, SLO, GH, and SMLO models. Symbols SLO* and MLO1* denote the parameters in RIPL-3 [2]. In Fig. 2, we display the $ \chi^2 $ of each nucleus with different models. The red and blue points are $ \chi^2 $ values for the spherical and deformed nuclei, respectively. Comparing with the global GDR parameters of RIPL-3, our systematic approach, Eq. (17) and (18), represents a significantly better fit of the experimental photoabsorption cross-section, especially for the deformed nuclei, since the total $ \chi^2 $ value of the SMLO model is the smallest, and the formula of the SMLO is very simple. Therefore, the SMLO model performs better than others.

      MLO1MLO2MLO3EGLOGFLSLOGHSMLOSLO*MLO1*
      $ a_1 $42.72241.50442.56343.176939.202539.778338.442342.015227.4728.69
      $ a_2 $16.086516.720416.159316.083418.884917.633618.694716.403222.06321.731
      $ a_3 $0.01110.01240.01220.00480.01040.0120.010.00620.02770.0285
      $ a_4 $1.03751.01571.00711.19631.01861.00951.01141.16821.91.9
      $ a_5 $0.04520.04770.04570.03090.03950.04590.03840.03641.2221.267
      $ a_6 $-9.0294-10.4079-10.3748-5.00-6.6123-11.7035-10.4802-10.571300
      $ a_7 $8.88119.603910.34574.18094.41969.76937.659410.344400
      $ a_8 $0.00390.00490.00430.00170.00230.00510.00390.001400
      $ b_1 $−0.8837−0.903−0.8877−0.7608−0.8142−0.8966−0.8669−0.796200
      $ b_2 $0.27530.50830.3950.00860.28090.58380.50520.06290.0260.026
      $ b_3 $1.07890.86660.94952.24251.18680.78840.92471.58361.911.91
      $ b_4 $0.08550.05030.07580.19450.47450.07570.15510.18210.0260.026
      $ b_5 $1.46291.59031.48091.42220.99071.48191.32781.27031.911.91
      $ b_6 $−0.184−0.1789−0.1604−0.1539−0.3373−0.1666−0.2366−0.188200
      $ b_7 $0.0815−0.02210.0361.02760.31790.11940.24260.262300
      $ b_8 $0.24480.23070.24740.29140.24750.2290.23030.3040.3330.333
      $ \chi^2 $9.876912.852610.72469.74210.127515.921415.69919.516125.804819.0095

      Table 4.  Parameters and $ \chi^2 $-values of systematics within MLO1, MLO2, MLO3, EGLO, GFL, SLO, GH, and SMLO models.

      Figure 2.  (color online) The $\chi^2$ of each nuclei with different models, red and blue points depict $\chi^2$ values for spherical and deformed nuclei, respectively.

      In Figs. 1 and 3, we displayed the comparison of the results of SMLO with the experimental photoabsorption cross-sections and other systematic calculations such as: QRPA and MLO1*. In Fig. 1, we compare cross-sections of the spherical nuclei, and in Fig. 3 the deformed nuclei including: 28Si, 80Se, 127I and 186W are taken into account. The QRPA calculations are based on the Sly4 Skyrme force [8] and MLO1* is the result of the GDR parameters in RIPL-3 [2]. As observed in Figs. 1 and 3, the SMLO model can provide a good description of the GDR peak energy for both spherical and deformed nuclei. Around the GDR region, the agreement of the phtotoabsorption cross-sections between SMLO and experimental data are rather satisfactory.

      Figure 3.  (color online) Comparison of SMLO (solid line) calculations with experimental photoabsorption cross-sections for 28Si, 80Se, 127I, and 186W. The QRPA (dash dot line) calculations are based on the Sly4 Skyrme force [8], and MLO1* (dash dot dot line) are the results of GDR parameters recommended by RIPL-3 [2].

    4.   Summary
    • In this work, we constructed two kinds of systematic GDR parameters to describe the photoabsorption cross-section of medium to heavy-mass nuclei. The microscopic GDR parameters are based on RQRPA calculations, which can be used to describe the photoabsorption cross-section of the spherical nuclei with only two parameters. At the same time, we systematically explore phenomenological GDR parameters in various Lorentzian models with 16 parameters, and the SMLO model is recommended at last, considering its brief formula expression and the smallest $ \chi^2 $.

      To further test the predictive ability of the two methods, we produce the GDR peak energies in the broad mass range 20$ \leqslant $A$ \leqslant$209, and compare them with the measurements in Fig. 4, where the black squares represent the experimental data [3], the blue triangles are the calculations of RQRPA with NL3 interaction for 58 even-even spherical nuclei from 30Si to 208Pb, and the red circles are the results of 266 nuclei from 20Ne to 209Bi using the systematic SMLO parameters in Table 4. Both methods yield reliable productions of the measured points. The GDR peak energies in the RQRPA scheme keep good consistency with the experimental data for A$ \geqslant $ 40 spherical nuclei. The GDR parameters from SMLO cover not only the spherical nuclei, but also the deformed medium to heavy-mass nuclei, and better performance is demonstrated around the mass A$ \geqslant $120.

      Figure 4.  (color online) Comparison of experimental GDR energy [3] with RQRPA calculation obtained with NL3 interaction and SMLO calculations. RQRPA energies are displayed for 58 spherical nuclei only.

      We would like to thank C.H. Cai (Nankai University), J.S. Zhang, Q.B.Shen, Y.L. Han (CNDC), and T. Kawano (LANL) for their kind discussions on the photon-nuclear reaction calculation; B.S. Yu (CNDC), H.W. Wang(SINAP), W. Luo (Nanhua University) and V.Varlamov (MSU) for their help on the experimental data evaluation of W isotopes; P. Dimitriou (IAEA) and A. Koning (IAEA) for their help on the evaluation.

Reference (53)

目录

/

DownLoad:  Full-Size Img  PowerPoint
Return
Return