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核反应率数据库是天体核合成与恒星演化建模的关键输入量, 直接影响各类核天体物理过程的计算精度与物理可信度. 近年来, 高分辨4π探测器阵列、新型气体探测器、γ-带电粒子符合测量等先进实验技术在关键核天体物理反应研究中得到广泛应用; 同时, 锦屏深地核天体物理实验平台等地下低本底设施也取得了一系列重要进展. 这些新的低能区实验测量结果, 相较于传统数据库依赖的经验外推或者理论计算, 为关键核反应天体环境温度区间的热核反应率评估提供了更直接的约束, 也为未来数据库的持续优化提供了新的实验支撑. 本文系统回顾了当前主流核反应率数据库—REACLIB、STARLIB、BRUSLIB等的建库目标、数据结构与典型应用, 梳理了它们在数据库覆盖、拟合方式与误差评价等方面的特征. 这些数据库在推动核反应网络计算标准化进程中发挥了重要作用. 在此基础上, 结合当前核反应率数据库特点, 在元数据存储结构、数据库更新以及人员组织形式等方面提出若干方法, 并强调了前沿实验进展对先进数据库构建的重要性.Nuclear reaction rate databases serve as essential inputs for nucleosynthesis and stellar evolution modeling, directly influencing the accuracy and physical reliability of calculations in various nuclear astrophysics processes. This work provides a comprehensive review of the major reaction rate databases—REACLIB, STARLIB, and BRUSLIB—highlighting their objectives, data structures, and representative applications, and discussing their coverage, fitting methods, and uncertainty evaluation. These databases have been instrumental in advancing the standardization of nuclear reaction network calculations. However, although these databases have significantly lowered the barrier to performing network modeling, there remains substantial room for improvement in aspects such as database unit structures, update mechanisms, and organizational frameworks. For example, detailed information on the underlying nuclear physics experiments or data analyses is often not included in REACLIB. Therefore, enhancing the stored metadata warrants careful consideration, since it can significantly improve the reliability of astrophysical modeling. At the same time, the advancement of nuclear astrophysics reaction rate databases depends heavily on continuous progress at the experimental frontier. In recent years, innovative experimental techniques—such as novel 4π high-resolution detector arrays and γ–charged particle coincidence measurements—have been widely applied to studies of key nuclear astrophysics reactions, significantly expanding research capabilities. To meet the demands of cutting-edge astrophysical studies for accurate reaction rates, the real-time updating and systematic evaluation of experimental data for key reactions represent both an important opportunity and an urgent challenge for the development of modern databases. several important achievements of the JUNA Collaboration at the Jinping underground nuclear astrophysics facility, where low-background experiments have been conducted, are also presented in this paper. These new low-energy measurements, when compared with traditional extrapolations used in databases, are found to provide more direct constraints on key reactions in nuclear astrophysics and to offer crucial experimental support for the continuous optimization of future databases.
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Keywords:
- nuclear astrophysics /
- nuclear reaction rate database /
- stellar nucleosynthesis /
- underground experiment
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图 1 核天体物理与其他主要物理学领域之间可能联系的示意图展示
Fig. 1. Diagrammatic presentation of possible connections of nuclear astrophysics with other major fields of physics.
图 4 12C+12C熔合反应天体物理$ S^* $因子. TTIK实验[61]、数据库编评数据[22]、特洛伊木马方法(THM)实验数据[63], 反对称分子动力学模型计算结果分别用红色实线, 深蓝色点划线, 黑色虚线, 淡蓝色点划线表示
Fig. 4. Astrophysical S-factor of the $ ^{12}\mathrm{C}+{}^{12}\mathrm{C} $ fusion reaction. The results from TTIK experiments[61], evaluated database data[22], Trojan Horse Method (THM) experimental data[63], and antisymmetrized molecular dynamics (AMD) calculations are represented by the red solid line, dark blue dash-dotted line, black dashed line, and light blue dash-dotted line, respectively.
表 1 三种主要核反应率数据库的表达方式与特点
Table 1. XXXXXXXXXXX
数据库 数据格式 数据库特点 REACLIB 七参数解析表达式 解析形式统一, 适用于大规模恒星演化与核合成网络(如XNet[33]、
MESA[34]、Kepler[35]); 通常不直接提供反应率不确定度信息.BRUSLIB 表格化(温度vs核反应率) 包含基于实验的汇编(如NACRE/NACREII)与大规模Hauser-Feshbach(HF)预测
两部分; 在质量数>40, 且位于接近稳定核素带区域的复合核研究中更为可靠[15].STARLIB 表格化(温度vs核反应率
vs反应不确定度)提供特定温度下每个反应率的概率密度函数, 严格定义反应率
不确定度[29], 便于开展核反应的蒙特卡洛全局敏感度分析[16].
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表 3 近年来若干核天体物理关键核反应实验测量及数据库收录
Table 3. XXXXXXXXX
核反应 实验技术 核反应率数据库收录 参考文献 25Mg(p, γ)26Al 地下实验直接测量 REACLIB未更新 [79] 13C(α, n)16O 地下实验直接测量 REACLIB未更新 [76,80] 19F(p, γ)20Ne 地下实验直接测量 REACLIB未更新 [81] 19F(p, α)16O 地下实验直接测量 REACLIB未更新 [82] 18O(α, γ)22Ne 地下实验直接测量 REACLIB未更新 [77,83] 2H(p, γ)3He 地下实验直接测量 REACLIB未更新 [71] 12, 13C(p, γ)13, 14N 地下实验直接测量 REACLIB未更新 [73] 59Fe(n, γ)60Fe β-Oslo方法 REACLIB未更新 [52] 22Mg(α, p)25Al MUSIC, AT-TPC REACLIB未更新 [56,85] 14C(n, γ)15C 超导螺线管 REACLIB未更新 [59] 12C+12C THM, TTIK REACLIB未更新 [61,63] 12C(α, γ)16O ANC REACLIB未更新 [86,87] 22Ne(α, n)25Mg, 22Ne(α, γ)26Mg 转移反应, 直接测量 REACLIB未更新 [88] 39K(p, γ)40Ca 转移反应 STARLIB, REACLIB [89] 18Ne(α, p)21Na 镜像核, 转移反应 STARLIB [90] 9Be(n, γ)10Be 活化法+AMS REACLIB [91] 30Si(p, γ)31P 直接测量 REACLIB [92]
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-
[1] Pagel B 1980 Nature 286 744
Google Scholar
[2] Burbidge E M, Burbidge G R, Fowler W A, Hoyle F 1957 Rev. Mod. Phys. 29 547
Google Scholar
[3] Angulo C, Arnould M, Rayet M, Descouvemount P, Baye D, Willain C L, Coc A, Barhoumi S, Aguer P, Rolfs C, Kunz R, Hammer J W, Mayer A, Paradellis T, Kossionides S, Chronidou C, Spyrou K, Innocenti S D, Fiorentini G, Ricci B, Zavatarelli S, Providencia C, Wolters H, Soares J, Grama C, Rahighi J, Shotter A, Rachti M L 1999 Nucl. Phys. A 656 3
Google Scholar
[4] Werrison A W, Wiblin E R 1951 Nature 167 346
Google Scholar
[5] Fowler W A 1969 Eng. Sci. 32 8
[6] Cease R P 2001 Hist. Stud. Phys. Biol. Sci. 32 41
Google Scholar
[7] Catherall R, Andreazza W, Breitenfeldt M, Dorsival A, Focker G J, Gharsa T P, Giles T J, Grenard J L, Locci F, Martins P, Marzari S, Schipper J, Shornikov A, Stora T 2017 J. Phys. G: Nucl. Part. Phys. 44 094002
Google Scholar
[8] Burkard K H, Dumanski W, Kirchner R, Klepper O, Roeckl E 1976 Nucl. Instrum. Methods 139 275
Google Scholar
[9] Macklin R L, Gibbons J H, Inada T 1963 Phys. Rev. 129 2695
Google Scholar
[10] Macklin R L, Gibbons J H, Inada T 1963 Nature 197 369
[11] Lovell A C B, Wilson A, Wiblin D V M 1951 Nature 167 476
[12] Zerkin V V, Pritychenko B 2018 Nucl. Instrum. Methods Phys. Res. A 888 31
[13] Otuka N, Dupont E, Semkova V, Pritychenko B, Blokhin A I, Aikawa M, Babykina S, Bossant M, Chen G, Dunaeva S, Forrest R A, Fukahori T, Furutachi N, Ganesan S, Ge Z, Gritzay O O, Herman M, Hlavac S, Kato K, Lalremruata B, Zhuang Y 2014 Nucl. Data Sheets 120 272
[14] Cyburt R H, Amthor A M, Ferguson R, Meisel Z, Smith K, Warren S, Heger A, Hoffman R D, Rauscher T, Sakharuk A, Schatz H, Thielemann F K, Wiescher M 2010 Astrophys. J. Suppl. Ser. 189 240
[15] Aikawa M, Arnould M, Goriely S, Jorissen A, Takahashi K 2005 A & A 441 1195
[16] Sallaska A L, Iliadis C, Champange A E, Goriely S, Starrfield S, Timmes F X 2013 Astrophys. J. Suppl. Ser. 207 18
[17] Fowler W A, Caughlan G E, Zimmerman B A 1967 Ann. Rev. Astr. Astro. 5 525
[18] Xu Y, Goriely S, Jorissen A, Chen G L, Arnould M 2013 A & A 549 106
[19] Fowler W A, Caughlan G R, Zimmerman B A 1975 Ann. Rev. Astr. Astro. 13 69
[20] Harris M J, Fowler W A, Caughlan G R, Zimmerman B A 1983 Ann. Rev. Astr. Astro. 21 165
[21] Caughlan G R, Fowler W A, Harris M J, Zimmerman B A 1985 At. Data Nucl. Data Tables 32 197
[22] Caughlan G R, Fowler W A, 1988 At. Data Nucl. Data Tables 40 283
[23] Rauscher T, Thielemann F -K 2000 At. Data Nucl. Data Tables 75 1
[24] Xu Y, Takahashi K, Goriely S, Arnould M, Ohta M, Utsunomiya H 2013 Nucl. Phys. A 918 61
[25] Iliadis C, D'Auria J M, Starrfield S, Thompson W J, Wiescher M 2001 Astrophys. J. 134 151
Google Scholar
[26] Bao Z Y, Beer H, Käppeler F, VOSS F, WISSHAK K 2000 At. Data Nucl. Data Tables 76 70
Google Scholar
[27] Koning A J, Delaroche J-P 2003 Nucl. Phys. A 713 231
Google Scholar
[28] Demetriou P, Grama C, Goriely S 2002 Nucl. Phys. A 707 253
Google Scholar
[29] Longland R, Iliadis C, Champange A E, Newton J R, Ugalde C, Coc A, Fitzgerald R 2010 Nucl. Phys. A 841 1
[30] Iliadis C, Longland R, Champange A E, Coc A, Fitzgerald R 2010 Nucl. Phys. A 841 31
Google Scholar
[31] Iliadis C, Longland R, Champange A E, Coc A 2010 Nucl. Phys. A 841 323
Google Scholar
[32] Iliadis C, Longland R, Champange A E, Coc A 2010 Nucl. Phys. A 841 251
Google Scholar
[33] Hix W R, Thielmann F K 1999 Astrophys. J. 511 862
Google Scholar
[34] Paxton B, Smolec R, Schwab J 2019 Astrophys. J. Suppl. Ser. 243 10
Google Scholar
[35] Woosley S E, Heger A 2007 Phys. Rep. 442 269
Google Scholar
[36] Wagoner R V 1969 Astrophys. J. Suppl. Ser. 162 247
[37] Woosley S E, Fowler W A, Holmes J A, Zimmerman B A 1978 At. Data Nucl. Data Tables 22 371
Google Scholar
[38] Dillmann I, Heil M, Käppeler F, Plag R, Rauscher T, Thielemann F-K 2006 Proceedings of the International Conference on Capture Gamma-Ray Spectroscopy and Related Topics Notre Dame, IN, USA, September 4–9, 2005 p123
[39] Bao Z Y, Käppeler F 1987 At. Data Nucl. Data Tables 36 411
Google Scholar
[40] Beer H, Voss F, Winters R R 1992 Astrophys. J. Suppl. Ser. 80 403
Google Scholar
[41] Vescovi D, Reifarth R, Lorenz E, Elbe A 2023 EPJ Web Conf. 279 11011
Google Scholar
[42] Dillmann I, Plag R, Käppeler F, Rauscher T 2010 Proceedings of the Scientific Workshop on Neutron Measurements, Theory and Applications-Nuclear Data for Sustainable Nuclear Energy Geel, Belgium, April 28–30, 2009 p55
[43] Reifarth R, Erbacher P, Fiebiger S, Göbel K, Heftrich T, Heil M, Käppeler F, Klapper N, Kurtulgil D, Langer C 2018 Eur. Phys. J. Plus 133 424
Google Scholar
[44] Rochman D, Koning A, Goriely S, Hilaire S 2025 Nucl. Phys. A 1053 122951
Google Scholar
[45] Rauscher T, Thielemann F K 2000 At. Data Nucl. Data Tables 75 1
Google Scholar
[46] Okumura S, Schnabel G, Koning A 2024 EPJ Web Conf. 292 12003
Google Scholar
[47] 许金艳, 阳黎升, 李奇特, 叶沿林, 韩家兴, 白世伟, 高见 2020 原子能科学技术 54 6
Xu J Y, Yang L S, Li Q T, Ye Y L, Han J X, Bai S W, Gao J 2020 Atom. Energy Sci. Technol. 54 6
[48] 卢奋华, 唐述文, 傅圣威, 闫铎, 马朋, 杨海波, 余玉洪, 章学恒, 王世陶, 张永杰, 方芳, 刘拓琦, 徐颖锋, 李治, 刘相满, 魏啸宝, 孙志宇 2024 原子核物理评论 32 3
Lu F H, Tang S W, Fu S W, Yan D, Ma P, Yang H B, Yu Y H, Zhang X H, Wang S T, Zhang Y J, Fang F, Liu T Q, Xu Y F, Li Z, Liu X M, Wei X B, Sun Z Y 2024 Nucl. Phys. Rev. 32 3
[49] 范胜男, 王波, 祁辉荣, 刘梅, 张余炼, 张建, 刘荣光, 伊福廷, 欧阳群, 陈元柏 2013 62 122901
Fan S N, Wang B, Qi H R, Liu M, Zhang Y L, Zhang J, Liu R G, Yi F T, Ouyang Q, Chen Y B 2013 Acta Phys. Sin. 62 122901
[50] 吴怡娇, 孟天鸣, 张献文, 谭旭, 马蒲芳, 殷浩, 任百惠, 屠秉晟, 张瑞天, 肖君, 马新文, 邹亚明, 魏宝仁 2024 73 240701
Google Scholar
Wu Y J, Meng T M, Zhang X W, Tan X, Ma P F, Yin H, Ren B H, Tu B S. Zhang R T, Xiao J, Ma X W, Zou Y M, Wei B R 2024 Acta Phys. Sin. 73 240701
Google Scholar
[51] Yang G C, Hua L M, Lu F, Su J, Li Z H, Jin S L, Shen Y P, Guo B 2022 Nucl. Sci. Tech. 33 68
[52] Spyrou A, Richman D, Couture A, Fields C E, Liddick S N, Childers K, Crider B P, DeYoung P A, Dombos A C, Gastis P, Guttormsen M, Hermansen K, Larsen A C, Lewis R, Lyons S, Midtbø J E, Mosby S, Muecher D, Naqvi F, PalmisanoKyle A, Perdikakis G, Prokop C, Schatz H, Smith M K, Sumithrarachchi C, Sweet A 2024 Nat. Commun. 15 9608
Google Scholar
[53] Song L Y, Wang L, Su J, Zhang L Y, He J J, Jin S L, Lu F, Shen Y P, Chen J F, Sheng Y D, Chen X, Lin S, Qin Z W, Li Z M, Zhang H, Wang L H, Chen Y J, Jiang X Z, Shen Z L, Li X Y, Liu F C, Huang Y T, Chen S Z, Guo B, Liu W P 2025 Nucl. Sci. Tech. 36 213
[54] Ayyad Y, Olaizola B, Mittig W, Potel G, Zelevinsky V, Horoi M, Beceiro-Novo S, Alcorta M, Andreoiu C, Ahn T, Anholm M, Atar L, Babu A, Bazin D, Bernier N, Bhattacharjee S S, Bowry M, Caballero-Folch R, Cortesi M, Dalitz C, Dunling E, Garnsworthy A B, Holl M, Kootte B, Leach K G, Randhawa J S, Saito Y, Santamaria C, Šiuryt˙e P, Svensson C E, Umashankar R, Watwood N, Yates D 2019 Phys. Rev. Lett. 123 082501
Google Scholar
[55] Sieverding A, Randhawa J S, Zetterberg D, deBoer R J, Ahn T, Mancino R, Martínez-Pinedo G, Hix W R 2022 Phys. Rev. C 106 015803
[56] Hu J, Yamaguchi H, Lam Y H, Heger A, Kahl D, Jacobs A M, Johnston Z, Xu S W, Zhang N T, Ma S B, Ru L H, Liu E Q, Liu T, Hayakawa S, Yang L, Shimizu H, Hamill C B, Murphy A St J, Su J, Fang X, Chae K Y, Kwag M S, Cha S M, Duy N N, Uyen N K, Kim D H, Pizzone R G, La Cognata M, Cherubini S, Romano S, Tumino A, Liang J, Psaltis A, Sferrazza M, Kim D H, Li Y Y, Kubono S 2021 Phys. Rev. Lett. 127 172701
[57] Gai M 2022 EPJ Web Conf. 260 01005
[58] Ayyad Y, Bazin D, Bonaiti F, Chen J, Li X, Anthony A, Avila M, Beceiro-Novo S, Bhatt K, Cabo C, Furuno T, Guimarães V, Hall-Smith A, Hunt C, Jayatissa H, Kawabata T, Kumi H, López-González J M, Lois-Fuentes J, Macchiavelli A, McCann G, Müller-Gatermann C, Muñoz-Ramos A, Mittig W, Olaizola B, Rahman Z, Regueira D, Rufino J, Sakajo S, Santamaria C, Serikow M Z, Tang T, Tolstukhin I, Turi N, Watwood N, Zamora J 2025 Front. Phys. 13 1539148
Google Scholar
[59] Jiang Y, He Z, Luo Y, Xin W, Chen J, Li X, Shen Y, Guo B, Li G, Pang D, Ma T, Nan W, Kajino T, Liu W 2025 Astrophys. J. 989 231
[60] Nan W K, Wang Y B, Sheng Y D, Su J, Zhang Y Q, Song L Y, Shen Y P, Cao F Q, Chen C, Dong C, Li Y J, Li Z H, Lian G, Nan W, Wang Q, Song N, Yan S Q, Zeng S, Fan Q W, Zhang H, Zhu M H, Guo B, Liu W P 2024 Nucl. Sci. Tech. 35 208
[61] Nan W K, Wang Y B, Su J, Sheng Y D, deBoer R J, Zhang Y Q, Song L Y, Cao F Q, Chen C, Dong C, Li Y J, Li Z H, Lian G, Nan W, Shen Y P, Song N, Yan S Q, Zeng S, Guo B, Liu W P 2025 Phys. Lett. B 862 139341
Google Scholar
[62] 南威克, 王友宝, 谌阳平, 李云居, 郭冰, 柳卫平 2025 原子核物理评论 42 199
Nan W K, Wang Y B, Shen Y P, Li Y J, Guo B, Liu W P 2025 Nucl. Phys. Rev. 42 199
[63] Tumino A, Spitaleri C, La Cognata M, Cherubini S, Guardo G L, Gulino M, Hayakawa S, Indelicato I, Lamia L, Petrascu H, Pizzone R G, Puglia S M R, Rapisarda G G, Romano S, Sergi M L, Spartá R, Trache L 2018 Nature 557 687
Google Scholar
[64] deBoer R J, Görres J, Wiescher M, Azuma R E, Best A, Brune C R, Fields C E, Jones S, Pignatari M, Sayre D, Smith K, Timmes F X, Uberseder E 2017 Rev. Mod. Phys. 89 035007
Google Scholar
[65] Wang Y B, Qin X, Wang B X, Liu W P, Li Z H, Bai X X, Lian G, Guo B, Zeng S, Su J, Li Y J, Jiang C 2009 Chin. Phys. C 33 181
Google Scholar
[66] Qin X, Wang Y B, Bai X X, Guo B, Jiang C, Li Y J, Li Z H, Lian G, Su J, Wang B X, Zeng S, Liu W P 2008 Chin. Phys. C 32 957
Google Scholar
[67] Broggini C, Bemmerer D, Caciolli A, Trezzi D 2018 Prog. Part. Nucl. Phys. 98 55
Google Scholar
[68] Robertson D, Couder M, Greife U, Strieder F, Wiescher M 2016 EPJ Web Conf. 109 09002
Google Scholar
[69] Liu W P, Li Z H, He J J, Tang X D, Lian G, An Z, Chang J J, Chen H, Chen Q H, Chen X J, Chen Z J, Cui B Q, Du X C, Fu C B, Gan L, Guo B, He G Z, Heger A, Hou S Q, Huang H X, Huang N, Jia B L, Jiang L Y, Kubono S, Li J M, Li K A, Li T, Li Y J, Lugaro M, Luo X B, Ma H Y, Ma S B, Mei D M, Qian Y Z, Qin J C, Ren J, Shen Y P, Su J, Sun L T, Tan W P, Tanihata I, Wang S, Wang P, Wang Y B, Wu Q, Xu S W, Yan S Q, Yang L T, Yang Y, Yu X Q, Yue Q, Zeng S, Zhang H Y, Zhang H, Zhang L Y, Zhang N T, Zhang Q W, Zhang T, Zhang X P, Zhang X Z, Zhang Z M, Zhao W, Zhao Z, Zhou C 2016 Sci. China Phys. Mech. Astron. 59 642001
Google Scholar
[70] Liu W P 2023 Chin. Phys. Lett. 40 060401
Google Scholar
[71] Mossa V, Stöckel K, Cavanna F, Ferraro F, Aliotta M, Barile F, Bemmerer D, Best A, Boeltzig A, Broggini C, Bruno C G, Caciolli A, Chillery T, Ciani G F, Corvisiero P, Csedreki L, Davinson T, Depalo R, Di Leva A, Elekes Z, Fiore E M, Formicola A, Fülöp Zs, Gervino G, Guglielmetti A, Gustavino C, Gyürky G, Imbriani G, Junker M, Kievsky A, Kochanek I, Lugaro M, Marcucci L E, Mangano G, Marigo P, Masha E, Menegazzo R, Pantaleo F R, Paticchio V, Perrino R, Piatti D, Pisanti O, Prati P, Schiavulli L, Straniero O, Szücs T, Takács M P, Trezzi D, Viviani M, Zavatarelli S 2020 Nature 587 210
Google Scholar
[72] Piatti D, Chillery T, Depalo R, Aliotta M, Bemmerer D, Best A, Boeltzig A, Broggini C, Bruno C G, Caciolli A, Cavanna F, Ciani G F, Corvisiero P, Csedreki L, Davinson T, Di Leva A, Elekes Z, Ferraro F, Fiore E M, Formicola A, Fülöp Zs, Gervino G, Gnech A, Guglielmetti A, Gustavino C, Gyürky Gy, Imbriani G, Junker M, Kochanek I, Lugaro M, Marcucci L E, Marigo P, Masha E, Menegazzo R, Mossa V, Pantaleo F R, Paticchio V, Perrino R, Prati P, Schiavulli L, Stöckel K, Straniero O, Szücs T, Takács M P, Zavatarelli S 2020 Phys. Rev. C 102 052802(R
[73] Skowronski J, Boeltzig A, Ciani G F, Csedreki L, Piatti D, Aliotta M, Ananna C, Barile F, Bemmerer D, Best A, Broggini C, Bruno C G, Caciolli A, Campostrini M, Cavanna F, Colombetti P, Compagnucci A, Corvisiero P, Davinson T, Depalo R, Di Leva A, Elekes Z, Ferraro F, Formicola A, Fülöp Zs, Gervino G, Gesuè R M, Guglielmetti A, Gustavino C, Gyürky Gy, Imbriani G, Junker M, Lugaro M, Marigo P, Masha E, Menegazzo R, Paticchio V, Perrino R, Prati P, Rapagnani D, Rigato V, Schiavulli L, Sidhu R S, Straniero O, Szücs T, Zavatarelli S 2023 Phys. Rev. Lett. 131 162701
Google Scholar
[74] Pantaleo F R, Boeltzig A, Best A, Perrino R, Aliotta M, Balibrea-Correa J, Barile F, Bemmerer D, Broggini C, Bruno C G, Buompane R, Caciolli A, Cavanna F, Chillery T, Ciani G F, Corvisiero P, Csedreki L, Davinson T, deBoer R J, Depalo R, D'Erasmo G, Di Leva A, Elekes Z, Ferraro F, Fiore E M, Formicola A, Fülöp Zs, Gervino G, Guglielmetti A, Gustavino C, Gyürky Gy, Imbriani G, Junker M, Kochanek I, Lugaro M, Masha E, Menegazzo R, Mossa V, Paticchio V, Piatti D, Prati P, Rapagnani D, Schiavulli L, Stöckel K, Straniero O, Szücs T, Takács M P, Trezzi D, Wiescher M, Zavatarelli S 2021 Phys. Rev. C 104 025802
Google Scholar
[75] Piatti D, Masha E, Aliotta M, Balibrea-Correa J, Barile F, Bemmerer D, Best A, Boeltzig A, Broggini C, Bruno C G, Caciolli A, Cavanna F, Chillery T, Ciani G F, Compagnucci A, Corvisiero P, Csedreki L, Davinson T, Depalo R, Di Leva A, Elekes Z, Ferraro F, Fiore E M, Formicola A, Fülöp Zs, Gervino G, Guglielmetti A, Gustavino C, Gyürky Gy, Imbriani G, Junker M, Lugaro M, Marigo P, Menegazzo R, Mossa V, Pantaleo F R, Paticchio V, Perrino R, Prati P, Rapagnani D, Schiavulli L, Skowronski J, Stöckel K, Straniero O, Szücs T, Takács M P, Zavatarelli S 2022 Eur. Phys. J. A 58 194
Google Scholar
[76] Ciani G F, Csedreki L, Rapagnani D, Aliotta M, Balibrea-Correa J, Barile F, Bemmerer D, Best A, Boeltzig A, Broggini C, Bruno C G, Caciolli A, Cavanna F, Chillery T, Colombetti P, Corvisiero P, Cristallo S, Davinson T, Depalo R, Di Leva A, Elekes Z, Ferraro F, Fiore E, Formicola A, Fülöp Zs, Gervino G, Guglielmetti A, Gustavino C, Gyürky Gy, Imbriani G, Junker M, Lugaro M, Marigo P, Masha E, Menegazzo R, Mossa V, Pantaleo F R, Paticchio V, Perrino R, Piatti D, Prati P, Schiavulli L, Stöckel K, Straniero O, Szücs T, Takács M P, Terrasi F, Vescovi D, Zavatarelli S 2021 Phys. Rev. Lett. 127 152701
Google Scholar
[77] Dombos A C, Robertson D, Simon A, Kadlecek T, Hanhardt M, Görres J, Couder M, Kelmar R, Olivas-Gomez O, Stech E, Strieder F, Wiescher M 2022 Phys. Rev. Lett. 128 162701
Google Scholar
[78] Straniero O, Imbriani G, Strieder F, Bemmerer D, Broggini C, Caciolli A, Corvisiero P, Costantini H, Cristallo S, Di Leva A, Formicola A, Elekes Z, Fülöp Zs, Gervino G, Guglielmetti A, Gustavino C, Gyürky Gy, Junker M, Lemut A, Limata B, Marta M, Mazzocchi C, Menegazzo R, Piersanti L, Prati P, Roca V, Rolfs C, Rossi Alvarez C, Somorjai E, Terrasi F, Trautvetter H-P 2013 Astrophys. J. 763 100
Google Scholar
[79] Su J, Zhang H, Li Z H, Ventura P, Li Y J, Li E, Chen C, Shen Y P, Lian G, Guo B, Li X Y, Zhang L Y, He J J, Shen Y D, Chen Y J, Wang L H, Zhang L, Cao F Q, Nan W, Nan W K, Li G X, Song N, Cui B Q, Chen L H, Ma R G, Zhang Z C, Jiao T Y, Gao B S, Tang X D, Wu Q, Li J Q, Sun L T, Wang S, Yan S Q, Liao J H, Wang Y B, Zeng S, Nan D, Fan Q W, Qi N C, Sun W L, Guo X Y, Zhang P, Chen Y H, Zhou Y, Zhou J F, He J R, Shang C S, Li M C, Cheng J P, Liu W P 2022 Sci. Bull. 67 125
Google Scholar
[80] Gao B, Jiao T Y, Li Y T, Chen H, Lin W P, An Z, Ru L H, Zhang Z C, Tang X D, Wang X Y, Zhang N T, Fang X, Xie D H, Fan Y H, Ma L, Zhang X, Bai F, Wang P, Fan Y X, Liu G, Huang H X, Wu Q, Zhu Y B, Chai J L, Li J Q, Sun L T, Wang S, Cai J W, Li Y Z, Su J, Zhang H, Li Z H, Li Y J, Li E T, Chen C, Shen Y P, Lian G, Guo B, Li X Y, Zhang L Y, He J J, Sheng Y D, Chen Y J, Wang L H, Zhang L, Cao F Q, Nan W, Nan W K, Li G X, Song N, Cui B Q, Chen L H, Ma R G, Zhang Z C, Yan S Q, Liao J H, Wang Y B, Zeng S, Nan D, Fan Q W, Qi N C, Sun W L, Guo X Y, Zhang P, Chen Y H, Zhou Y, Zhou J F, He J R, Shang C S, Li M C, Kubono S, Liu W P, deBoer R J, Wiescher M, Pignatari M 2022 Phys. Rev. Lett. 129 132701
Google Scholar
[81] Zhang L Y, He J J, deBoer R J, Wiescher M, Heger A, Kahl D, Su J, Odell D, Chen Y J, Li X Y, Wang J G, Zhang L, Cao F Q, Zhang H, Zhang Z C, Jiang X Z, Wang L H, Li Z M, Song L Y, Zhao H W, Sun L T, Wu Q, Li J Q, Cui B Q, Chen L H, Ma R G, Li E T, Lian G, Sheng Y D, Li Z H, Guo B, Zhou X H, Zhang Y H, Xu H S, Cheng J P, Liu W P 2022 Nature 610 656
Google Scholar
[82] Zhang L Y, Su J, He J J, Wiescher M, deBoer R J, Kahl D, Chen Y J, Li X Y, Wang J G, Zhang L, Cao F Q, Zhang H, Zhang Z C, Jiao T Y, Sheng Y D, Wang L H, Song L Y, Jiang X Z, Li Z M, Li E T, Wang S, Lian G, Li Z H, Tang X D, Zhao H W, Sun L T, Wu Q, Li J Q, Cui B Q, Chen L H, Ma R G, Guo B, Xu S W, Li J Y, Qi N C, Sun W L, Guo X Y, Zhang P, Chen Y H, Zhou Y, Zhou J F, He J R, Shang C S, Li M C, Zhou X H, Zhang Y H, Zhang F S, Hu Z G, Xu H S, Chen J P, Liu W P 2022 Phys. Rev. Lett. 127 152702
[83] Wang L H, Su J, Shen Y P, He J J, Lugaro M, Szányi B, Karakas A I, Zhang L Y, Li X Y, Guo B, Lian G, Li Z H, Wang Y B, Chen L H, Cui B Q, Tang X D, Gao B S, Wu Q, Sun L T, Wang S, Sheng Y D, Chen Y J, Zhang H, Li Z M, Song L Y, Jiang X Z, Nan W, Nan W K, Zhang L, Cao F Q, Jiao T Y, Ru L H, Cheng J P, Wiescher M, Liu W P 2023 Phys. Rev. Lett. 130 092701
Google Scholar
[84] Liu W P, Guo B, An Z, Cui B Q, Fang X, Fu C B, Gao B S, He J J, Jiang Y C, Lv C, Li E T, Li G X, Li Y J, Li Z H, Lian G, Lin W P, Liu Y H, Nan W, Nan W K, Shen Y P, Song N, Su J, Sun L T, Tang X D, Wang L H, Wang S, Wang Y B, Wu D, Xi X F, Yan S Q, Zhang L Y 2024 Nucl. Sci. Tech. 35 217
Google Scholar
[85] Randhawa J S, Ayyad Y, Mittig W, Meisel Z, Ahn T, Aguilar S, Alvarez-Pol H, Bardayan D W, Bazin D, Beceiro-Novo S, Blankstein D, Carpenter L, Cortesi M, Cortina-Gil D, Gastis P, Hall M, Henderson S, Kolata J J, Mijatovic T, Ndayisabye F, O’Malley P, Pereira J, Pierre A, Robert H, Santamaria C, Schatz H, Smith J, Watwood N, Zamora J C 2020 Phys. Rev. Lett. 125 202701
Google Scholar
[86] Nan W, Shen Y P, Guo B, Li Z H, Li Y J, Pang D Y, Su J, Yan S Q, Fan Q W, Liu J C, Chen C, Li X Y, Lian G, Ma T L, Nan W K, Wang Y B, Zeng S, Zhang H, Liu W P 2024 Phys. Rev. C 109 045808
Google Scholar
[87] Shen Y P, Guo B, deBoer R J, Li Z H, Li Y J, Tang X D, Pang D Y, Adhikari S, Basu C, Su J, Yan S Q, Fan Q W, Liu J C, Chen C, Han Z Y, Li X Y, Lian G, Ma T L, Nan W, Nan W K, Wang Y B, Zeng S, Zhang H, Liu W P 2022 Phys. Rev. Lett. 124 162701
[88] Wiescher M, deBoer R J, Görres J 2023 Eur. Phys. J. A 59 11
Google Scholar
[89] Longland R, Dermigny J, Marshall C 2018 Phys. Rev. C 98 025802
Google Scholar
[90] Mohr P, Longland R, Iliadis C 2014 Phys. Rev. C 90 065806
Google Scholar
[91] Wallner A, Bichler M, Coquard L, Dillmann I, Forstner O, Golser R, Heil M, Käppeler F, Kutschera W, Lederer-Woods C, Martschini M, Mengoni A, Merchel S, Michlmayr L, Priller A, Steier P, Wiescher M 2019 Phys. Rev. C 99 015804
Google Scholar
[92] Dermigny J, Iliadis C, Champagne A, Longland R 2020 Phys. Rev. C 102 014609
Google Scholar
[93] Bao Z Y, Beer H, Käppeler F, Voss F, Wisshak K, Rauscher T 2000 At. Data Nucl. Data Tables 76 70
Google Scholar
[94] 周勇, 李志宏, 张海黔 2015 原子能科学技术 11 1921
Zhou Y, Li Z H, Zhang H Q 2015 Atom. Energy Sci. Technol. 11 1921
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