Chinese Physics C

Cross section measurement of the ⁶Li(n,t)⁴He reaction in the MeV neutron energy range

Yu. M. Gledenov, I. Chuprakov, Guohui Zhang, G. Khuukhenkhuu, M. Odsuren, B. Usukhbayar, L. Krupa, E. Sansarbayar, Jie Liu, Haofan Bai, Cong Xia, Zepeng Wu, Wenkai Ren, D. Berikov, G. Ahmadov, A. K. Bekbayev, B. Mukhametuly, E. S. Korshikov, N. T. Temerbulatova, E. B. Myrzabekova, O. Daulbayev, Y. Arynbek

2025, 49(12): 124004. doi: 10.1088/1674-1137/ae0306

Abstract:
Cross sections of the ⁶Li(n, t)⁴He reaction were measured in the fast neutron energy range from 3.3 to 5.3 MeV using a gridded ionization chamber (GIC) and well–calibrated experimental setup at the EG–5 Van de Graaff accelerator of the Frank Laboratory of Neutron Physics, Joint Institute for Nuclear Research (FLNP, JINR). Lithium fluoride (⁶LiF) samples with varying thicknesses and krypton–CO₂ gas mixtures with different pressures were used to optimize the detection of both alpha particles and tritons. Neutron fluxes were monitored using two high–purity (99.999%) ²³⁸U₃O₈ samples placed inside the GIC, complemented by an externally calibrated ³He long counter. The measured ⁶Li(n, t)⁴He cross–section data were compared with existing results of measurements and evaluations from EXFOR and ENDF nuclear data libraries, and the results showed a good agreement in the measured neutron energy range. These new measurements provide reliable cross–section data that contribute to the refinement of evaluated nuclear data files and support applications in nuclear physics, tritium production, and reactor design.

Development of cesium laser resonance ionization schemes for PLASEN experiment

Yangfan Guo, Zhou Yan, Xiaofei Yang, Shaojie Chen, Wencong Mei, Hanrui Hu, Yinshen Liu, Dongyang Chen, Chen Zhang, Tianxu Gao, Yipin Jing, Yanlin Ye

2025, 49(12): 124002. doi: 10.1088/1674-1137/adf49e

Abstract:
To study the nuclear properties and deformation of neutron-rich cesium isotopes in their ground and isomeric states at the Beijing Rare Isotope Beam Facility (BRIF), optimal resonance ionization schemes and experimental conditions must be predetermined. In this study, we evaluated several three-step laser resonance ionization schemes for cesium atoms by accessing their ionization efficiency and spectral resolution under varying measurement conditions using high-resolution and high-sensitivity collinear resonance ionization spectroscopy system. Hence, we identified the currently most efficient resonance ionization scheme and optimal experimental conditions, achieving an overall measurement efficiency of 1: 400 with a spectral resolution of about 100 MHz. Under this condition, the extracted hyperfine structure parameters of ¹³³Cs showed excellent agreement with previously reported values. This study establishes a solid foundation for the forthcoming online measurement of neutron-rich cesium isotopes at BRIF.

³H and ³He nuclei production in a combined thermal and coalescence framework for heavy-ion collisions in the few-GeV energy regime

2026, 50(1): 014104. doi: 10.1088/1674-1137/ae099a

Abstract:
A thermal model describing hadron production in heavy-ion collisions in the few-GeV energy regime is combined with the concept of nucleon coalescence to make predictions for the production of ³H and ³He nuclei. A realistic parametrization of the freeze-out conditions is employed, which accurately reproduces the spectra of protons and pions. It also correctly predicts the deuteron yield, which agrees with experimental observations. However, the predicted yields of ³H and ³He are lower than the experimental results by approximately a factor of two. The model predictions for the spectra can be compared with future experimental data.

Low-lying states of odd-even N = 79 isotones within the nucleon-pair approximation

Yu-Chen Wu, Man Bao

2025, 49(12): 124109. doi: 10.1088/1674-1137/adf1f6

Abstract:
In this paper, we study low-lying states of odd-even $N = 79$ isotones, including $^{129}{\rm{Sn}}$, $^{131}{\rm{Te}}$, $^{133}{\rm{Xe}}$, $^{135}{\rm{Ba}}$, and $^{137}{\rm{Ce}}$, within the nucleon-pair approximation (NPA) of the shell model. Low-lying energy levels of these nuclei with both positive and negative parities, as well as $B(E2)$ transition rates and g factors of some low-lying states, are calculated. Most of them agree closely with experimental data. The wave functions of yrast $1/2^+_1$, $5/2^+_1$, $7/2^+_1$, $23/2^+_1$ states and negative parity $11/2^-_1 \sim 23/2^-_1$ and $27/2^-_2$ states of these nuclei are discussed in detail. The NPA calculations show that many of these states have a simple structure in the nucleon-pair basis.

Investigation of the α-decay half-lives for even-even nuclei within a deformed two-potential approach

2025, 49(12): 124111. doi: 10.1088/1674-1137/ae0430

Abstract:
In this study, we systematically investigate the α-decay half-lives of 195 even-even nuclei using a deformed two-potential approach (TPA). The cosh potential with fixed diffuseness parameter is adopted as the nuclear potential, for which deformation parameters are taken from the FRDM, WS4, and DRHBc models. The root mean square deviation (RMSD) decreases from 0.515 to 0.385, 0.401, and 0.436, respectively, indicating that incorporating nuclear deformations enables the deformed TPA to accurately reproduce experimental α-decay half-lives. Furthermore, by fitting the diffuseness parameter across various mass regions, the RMSD is further reduced, from 0.385 to 0.330, 0.401 to 0.343, and 0.436 to 0.363. Additionally, the deformed TPA, combined with the fitted diffuseness parameter, is extended to predict the α-decay half-lives of even-even nuclei with Z = 118 and 120. The results suggest that N = 184 may be the next neutron magic number, following N = 126.

Probing the cluster structure of ⁶Li with the ⁶Li + ¹²C nuclear reaction at 68 MeV

2026, 50(1): 014102. doi: 10.1088/1674-1137/ae072b

Abstract:
This study presents a combined experimental and theoretical investigation of the ⁶Li + ¹²C nuclear reaction at a laboratory energy of 68 MeV. The reaction products are identified via the standard $ \Delta E $–E technique. Angular distributions are constructed for the elastic, inelastic, and deuteron transfer channels by detecting emitted particles – ⁶Li and α. Elastic and inelastic scattering of ⁶Li off ¹²C are analyzed using the optical model and coupled channels approaches, with the interaction described by a double-folding potential. This potential is calculated based on the three-body wave function of ⁶Li. Pronounced coupled-channel effects that modify the potential and allow accurate reproduction of the experimental cross sections are observed. The resulting polarized potentials provide a more precise description of the initial-state interaction for further reaction modeling. The deuteron transfer channel, ¹²C(⁶Li, α)¹⁴N, is studied using the coupled reaction channels method. The coupling between the transfer and elastic channels is implemented using the three-body wave function of ⁶Li. As an alternative, a regular wave function constructed with a phenomenological Woods–Saxon potential is also employed. Comparison between the calculated differential cross sections and experimental data reveals a more complex and nuanced reaction mechanism, which supports the cluster structure of ⁶Li.

Investigating the transverse-momentum- and pseudorapidity-dependent flow vector decorrelation in p–Pb collisions with a multi-phase transport model

Siyu Tang, Zuman Zhang, Chao Zhang, Liang Zheng, Renzhuo Wan

2025, 49(12): 124104. doi: 10.1088/1674-1137/adef1b

Abstract:
Event-by-event fluctuations in the initial energy density of nuclear collisions lead to the decorrelation of second order flow vector, which is known as its transverse-momentum ($ p_{\mathrm{T}} $) and pseudorapidity (η) dependence as observed in high-energy heavy-ion collisions. Existing measurements at the CERN Large Hadron Collider showed that these decorrelations are also observed in small collision systems. In this work, a systematic study of the transverse-momentum- and pseudorapidity-dependent flow vector decorrelation is performed in p–Pb collisions at the 5.02 TeV with A Multi-Phase Transport (AMPT) model using different tunings of initial conditions and partonic and hadronic interactions. The string-melting version of the AMPT model provides a reasonable description of the measured flow vector decorrelation as a function of $ p_{\mathrm{T}} $ and η. We demonstrate that hadronic scatterings do not have a significant effect on decorrelation in p–Pb collisions for different centrality selections, while both initial conditions and partonic interactions affect the magnitude of the decorrelations. In addition, we found that the subtraction of the nonflow, especially the long-range jet correlation, is crucial for the accurate extraction of flow vector decorrelation in small collision systems. The comparison of data and model presented in this paper provide further insights in understanding the fluctuations of the flow vector with $ p_{\mathrm{T}} $ and η in small collision systems and has referential value for future measurements.

Feasibility study of measuring interaction cross sections of hypernuclei produced in projectile fragmentation reactions with WASA-FRS setup

Yiming Gao, Yoshiki K. Tanaka, Vasyl Drozd, Hiroyuki Ekawa, Samuel Escrig, Yan He, Ayumi Kasagi, Enqiang Liu, Manami Nakagawa, Christophe Rappold, Takehiko R. Saito, Ryohei Sekiya, He Wang, Ayari Yanai, Xiaohong Zhou

2025, 49(12): 124003. doi: 10.1088/1674-1137/adf4b2

Abstract:
A novel method is proposed to measure the interaction cross sections of short-lived hypernuclei with the WASA-FRS experimental setup at GSI and FAIR. The interaction cross sections of hypernuclei, produced in projectile fragmentation reactions at relativistic energies, can be determined from their production point distribution within a target. The feasibility of such a measurement is evaluated through detailed Monte Carlo simulations. The results indicate that an aimed uncertainty on the order of 10% can be achieved for the case of a hypertriton, demonstrating the potential of this method for studying matter radii and the possible hyperon halo structure of hypernuclei.

Investigation of cluster states around ²⁰Ne including spin-orbit coupling and its extension to heavier nuclei

Tao Wan, Shu-Lin Tang, Yi-Bin Qian

2025, 49(12): 124103. doi: 10.1088/1674-1137/adf317

Abstract:
Clustering, as a fundamental dynamical feature existing widely in many-body systems, has aroused tremendous interest in nuclear physics over the last few decades. The α-cluster concept has been used successfully to describe the energy spectra and electromagnetic transitions for a series of nuclei above the doubly magic core. In the present study, we have systematically investigated the spectroscopic properties of three-nucleon and α-cluster states in ¹⁹F and ²¹Ne within the binary cluster-core model (BCM) plus the extra spin-orbit potential. The calculated energy levels and electromagnetic transition strengths, with few exceptions, are in good agreement with experimental data, confirming the reliability and integrity of BCM. Furthermore, such a BCM is extended to the case of cluster states approaching shell closures in heavier nuclei, such as ⁴³Sc, ⁵⁹Cu, and ⁹³Mo, leading to satisfactory reproductions and predictions on energy levels and reduced transition rates. It is expected that the present study can provide further insight into the cluster degrees of freedom in odd-A nuclei.

Effects of energy levels on the double-differential cross sections of outgoing charged particles for the n+¹⁹F reaction below 20 MeV

Hanmei Cao, Fanglei Zou, Xiaojun Sun, Jingshang Zhang

2025, 49(12): 124107. doi: 10.1088/1674-1137/adf49f

Abstract:
The double-differential cross sections (DDCSs) for the n+¹⁹F reaction are crucial for elucidating the mechanisms of nuclear reaction processes, advancing applications in nuclear engineering and technology, and supporting fundamental research in nuclear astrophysics. The quantitative description of the DDCS for emission products presents a persistent theoretical challenge, primarily due to the effects of energy levels being more intricate than those of 1p-shell nuclei. The pick-up mechanism of complex particles, as one of the important components of the statistical theory for light nuclear reactions (STLN), is improved to describe the DDCSs of outgoing charged particles, considering the effect of energy levels with energy, angular momentum, and parity conservations. A comprehensive analysis of all open reaction channels is performed for the n+¹⁹F reaction below 20 MeV. After ensuring the acquisition of the high-quality DDCS of the emitted neutrons, the DDCSs of outgoing charged particles (including $ p, d, t, \alpha $) are self-consistently obtained. The results of this study are not only in good agreement with recently measured experimental data at $ E_n $=14.2 MeV but also superior to the data recommended by current major nuclear databases. Thus, the LUNF code for the n+¹⁹F reaction is developed to obtain an ENDF-6 formatted DDCS file of the nucleon and light composite charged particles.

Design optimization of isochronous mode in the HIAF-SRing

Wen-Wen Ge, You-Jin Yuan, Jian-Cheng Yang, S. Litvinov, Geng Wang, Rui-Jiu Chen, Xin-Liang Yan, Hang Ren, Guo-Dong Shen

2025, 49(12): 124001. doi: 10.1088/1674-1137/adcf0e

Abstract:
The measurement of mass, or equivalently the binding energy, of exotic nuclei has reached the limits of nuclear existence, which are characterized by tiny production cross-sections and short half-lives. The isochronous mode of the Spectrometer Ring at the High Intensity heavy-ion Accelerator Facility project in China (HIAF-SRing) offers the capacity for such measurements. However, many factors limit the revolution time resolution of the isochronous mode of the large acceptance HIAF-SRing. Nonlinear field errors as well as fringe fields of the wide aperture dipoles and quadrupoles strongly excite the higher-order aberrations, which negatively affect the revolution time resolution. Moreover, the transverse emittance of the beam is inversely proportional to the revolution time resolution. Their influence is investigated here, and a possible correction scheme with sextupoles and octupoles is shown. With higher-order corrections, a mass resolution of $R({\rm FWHM}) = 1\times10^{6}$, corresponding to a relative revolution time of $\sigma(T)/T \sim 4.9\times 10^{-7} $, is with the isochronous setting $\gamma_t=1.43$ within the momentum acceptance of $\pm0.2$%.

Polarized neutron beams from polarized deuterium-tritium fusion with applications to magnetic field imaging in high-energy-density plasmas

Ronghao Hu, Qike Gu, Kejian Shi, Zezhong Wei, Meng Lv, Shiyang Zou, Yongkun Ding

2025, 49(12): 124102. doi: 10.1088/1674-1137/adec4f

Abstract:
When the spins of deuteron and triton are aligned in parallel, the fusion cross-section increases by approximately 50%. The emitted neutrons are anisotropic and polarized in specific directions. The polarized neutron beams can be used to measure strong magnetic fields in high-energy-density plasmas, offering a potential alternative to the well-established proton imaging technique. In contrast to protons, neutrons are not deflected by electromagnetic fields and are not sensitive to electric fields, thus reducing the complexity of magnetic field reconstruction. Three-dimensional spin transport hydrodynamics simulations are employed to investigate the polarized neutron beams generated from spin-polarized deuterium-tritium target implosions. Synthetic polarized neutron images of magnetic fields are generated from Monte Carlo simulations. Based on a comparison of the results of finite-size sources and an ideal point source, a method to compensate the finite-source-size blurring effect is proposed to reduce the error in magnetic field reconstruction.

Theoretical study of Strong gravitational lensing around Dyonic ModMax black hole: constraints from EHT observations

Lola Meliyeva, Obid Xoldorov, Olmos Tursunboyev, Shavkat Karshiboev, Sardor Murodov, Isomiddin Nishonov, Bekzod Rahmatov

2025, 49(12): 125102. doi: 10.1088/1674-1137/adf4a0

Abstract:
In this study, we investigate the properties of the Dyonic ModMax black hole solution using strong gravitational lensing. Additionally, we calculate the time delay between two relativistic images of a background object. First, we analyze expressions for the photon orbits in the spacetime of the Dyonic ModMax black hole. To obtain observational consequences, we provide expressions for the observable quantities, such as angular radius and magnifications. The numerous observations suggest that many nearby galaxies contain supermassive central black holes. In our model, such a supermassive black hole can be characterized by two additional parameters: γ and Q. Notably, the bending angle $ \alpha_D(b) $ and the angular position $ \theta_\infty $ decrease with increasing charge of the black hole Q, while the parameter γ displays opposite behavior to that of Q. By using observational data of supermassive black holes $ \mathrm{SgrA}^* $ and $ \mathrm{M}87^* $, we obtain constraints for these parameters.

Refinement of an analytical capture cross section formula

Ning Wang

2025, 49(12): 124106. doi: 10.1088/1674-1137/adfe53

Abstract:
An analytical formula with high accuracy is proposed for a systematic description of the capture cross sections at near-barrier energies from light to superheavy reaction systems. Based on the empirical barrier distribution method, three key input quantities are refined by introducing nuclear surface correction to the Coulomb parameter z for calculating the barrier height, incorporating the reaction Q-value and shell correction into the barrier distribution width calculations, and considering the deep inelastic scattering effects of superheavy systems on the barrier radius. With these refinements, the accuracy of not only the calculated barrier height but also the predicted capture cross sections is substantially improved. The average deviation (in logarithmic scale) between the predicted cross sections and the experimental data for 426 reaction systems with $ 35 < Z_1 Z_2 < 2600 $ is sharply reduced from 3.485 to 0.113.

System-size dependence of γ-jet modifications in heavy-ion collisions

Yu-Xin Xiao, Qing-Fei Han, He-Xia Zhang, Han-zhong Zhang

2025, 49(12): 124101. doi: 10.1088/1674-1137/adef24

Abstract:
Medium modifications of γ-triggered jets are investigated with the linear Boltzmann transport model in heavy-ion collisions with varying system sizes, focusing on centrality dependence in Pb+Pb and Xe+Xe collisions at the LHC. Our numerical results reveal that jets produced in central collisions exhibit a wider transverse asymmetry ($ A_N^y $) distribution, broader jet shape, and more pronounced γ-jet transverse momentum imbalance ($ X_{J\gamma}=p_T^{\rm jet}/p_T^\gamma $) compared with peripheral collisions. These effects arise from the longer path length and stronger jet-medium interactions in central collisions, leading to enhanced jet quenching and medium response. Our findings demonstrate that the magnitude of γ-jet modifications is sensitive to the size and centrality of the collision system, with larger systems inducing more significant alterations owing to increased energy loss and medium feedback.

Bayesian inference of nuclear incompressibility from collective flow in mid-central Au+Au collisions at 400–1500 MeV/nucleon

J. M. Wang, X. G. Deng, W. J. Xie, B. A. Li, Y. G. Ma

2025, 49(12): 124105. doi: 10.1088/1674-1137/adf4a1

Abstract:
The incompressibility K of symmetric nuclear matter (SNM) is determined through a Bayesian analysis of collective flow data from Au + Au collisions at beam energies $E = 400 -1500$ MeV/nucleon. This analysis utilizes a Gaussian process (GP) emulator applied to the isospin-dependent quantum molecular dynamics (IQMD) model for heavy-ion collisions, both with and without incorporating the momentum dependence of the single-nucleon potentials. Specifically, at the 68% confidence level, using rapidity and transverse velocity dependence of proton elliptic flow data with and without consideration of the momentum dependence, the inferred incompressibility values are $K=188.9^{+2.9}_{-4.5}$ MeV and $256.1^{+8.2}_{-8.7}$ MeV at $E = 400$ MeV/nucleon, respectively. When the transverse momentum dependence of proton-like directed flow data is included, the inferred incompressibility values become $K=222.3^{+9.0}_{-9.9}$ MeV and $K=285.5^{+6.7}_{-7.3}$ MeV, respectively. Furthermore, we found that the value of K derived from observables of proton elliptic flow increases with beam energy. This indicates that the equation of state (EoS) of nuclear matter hardens at higher densities and temperatures in reactions with higher beam energies.

Hawking tunneling radiation with thermodynamic pressure

Cheng Hu, Xiao-Xiong Zeng

2026, 50(1): 015103. doi: 10.1088/1674-1137/ae07b4

Abstract:
Hawking radiation elucidates black holes as quantum thermodynamic systems, thereby establishing a conceptual bridge between general relativity and quantum mechanics through particle emission phenomena. While conventional theoretical frameworks predominantly focus on classical spacetime configurations, recent advancements in extended phase space thermodynamics have redefined cosmological parameters (such as the Λ-term) as dynamic variables. Notably, the thermodynamics of anti-de Sitter (AdS) black holes has been successfully extended to incorporate thermodynamic pressure P. Within this extended phase space framework, although numerous intriguing physical phenomena have been identified, the tunneling mechanism of particles incorporating pressure and volume remains unexplored. This study investigates Hawking radiation through particle tunneling in Schwarzschild AdS black holes within the extended phase space, where the thermodynamic pressure P is introduced via a dynamic cosmological constant Λ. By employing semi-classical tunneling calculations with self-gravitation corrections, we demonstrate that emission probabilities exhibit a direct correlation with variations in Bekenstein-Hawking entropy. Significantly, the radiation spectrum deviates from pure thermality, aligning with unitary quantum evolution while maintaining consistency with standard phase space results. Moreover, through thermodynamic analysis, we verified that the emission rate of particles is related to the difference in Bekenstein-Hawking entropy of the emitted particles before and after they tunnel through the potential barrier. These findings establish particle tunneling as a unified probe of quantum gravitational effects in black hole thermodynamics.

Prospects for searching for sterile neutrinos in dynamical dark energy cosmologies using joint observations of gravitational waves and γ-ray bursts

Lu Feng, Tao Han, Jing-Fei Zhang, Xin Zhang

2026, 50(1): 1-12. doi: 10.1088/1674-1137/ae0b43

Abstract:
In the era of third-generation (3G) gravitational-wave (GW) detectors, GW standard siren observations from binary neutron star mergers provide a powerful tool for probing the expansion history of the universe. Because sterile neutrinos can influence cosmic evolution by modifying the radiation content and suppressing structure formation, GW standard sirens offer promising prospects for constraining sterile neutrino properties within a cosmological framework. Building on this, we investigate the prospects of detecting sterile neutrinos in dynamical dark energy (DE) models using joint observations from 3G GW detectors and a future short gamma-ray burst detector, such as a THESEUS-like telescope. We consider the wCDM, holographic DE (HDE), and Chevallier–Polarski–Linder (CPL) models. Our results show that the properties of DE can influence the constraints on sterile neutrino parameters. Moreover, the inclusion of GW data significantly improves constraints on both sterile neutrino parameters and other cosmological parameters across all three models compared to the current limits derived from CMB+BAO+SN (CBS) observations. When GW data are included in the CBS dataset, a preference for $ \Delta N_{\rm{eff}} > 0 $ emerges at approximately the $ 1\sigma $ level in the wCDM and CPL models, while it reaches approximately $ 3\sigma $ in the HDE model. Moreover, the upper limits on $ m_{\nu,{\rm{sterile}}}^{\rm{eff}} $ are reduced by approximately 13%, 75%, and 3% in the wCDM, HDE, and CPL models, respectively.

Constraints on Lorentz invariance violation from GRB 221009A using the DisCan method

Yu Xi, Fu-Wen Shu

2025, 49(12): 125101. doi: 10.1088/1674-1137/adfa01

Abstract:
Lorentz symmetry is a cornerstone of modern physics, and testing its validity remains a critical endeavor. In this study, we analyze the photon time-of-flight and time-shift data from LHAASO observations of Gamma-Ray Burst GRB 221009A to search for signatures of Lorentz violation. We employ the DisCan (dispersion cancellation) method with various information entropies as cost functions, designating the results obtained with Shannon entropy as our representative outcome. This choice is attributed to the parameter-free statistical properties of Shannon entropy, which has demonstrated remarkable stability as we continually refine and enhance our methodology. In the absence of more detailed data and physical context, it provides more stable and reliable results. We constrain the energy scale associated with Lorentz invariance violation. Our results yield 95% confidence level lower limits of $ E_{\text{QG},1} > 5.4 \times 10^{19} \, \text{GeV} $ (subluminal) and $ E_{\text{QG},1} > 2.7 \times 10^{19} \, \text{GeV} $ (superluminal) for the linear case (n = 1), and $ E_{\text{QG},2} > 10.0 \times 10^{12} \, \text{GeV} $ (subluminal) and $ E_{\text{QG},2} > 2.4 \times 10^{12} \, \text{GeV} $ (superluminal) for the quadratic case (n = 2). Subsequently, we incorporate WCDA photons and the Knuth binning method to further optimize and complement our approach while also performing filtering using information entropies. Furthermore, we demonstrate that employing different information entropy measures as cost functions does not alter the order of magnitude of these constraints.

Axial gravitational quasinormal modes of magnetically charged black holes

De-Cheng Zou, Xufen Zhang, Chao-Ming Zhang, Ming Zhang, Rui-Hong Yue

2025, 49(12): 125109. doi: 10.1088/1674-1137/adff01

Abstract:
In this study, we consider axial perturbations on the magnetically charged string-inspired Euler-Heisenberg black hole. As axial metric perturbation decouples from axial electromagnetic perturbation, we mainly focus on axial gravitational perturbation. By using the Wentzel–Kramers–Brillouin (WKB) approximation and asymptotic iteration method (AIM), we perform a detailed analysis of the gravitational quasinormal frequencies by varying the characteristic parameters of gravitational perturbation and black holes. The results obtained through the AIM are consistent with those obtained using the WKB method, including the results extracted from the time-domain profiles. The greybody factor is calculated using the WKB method. The effects of $ Q_m $, ϵ, and multipole number l on the greybody factor are also studied.

Radiation properties of the accretion disk around a quantum-corrected black hole

Mirjavoxir Mirkhaydarov, Mirzabek Alloqulov, Sanjar Shaymatov

2025, 49(12): 125107. doi: 10.1088/1674-1137/adfa83

Abstract:
In this work, we study the radiation properties of the quantum-corrected black hole (BH). For simplicity, we consider test particles around the quantum-corrected BH. With this aim, we define the important quantities of test particles around the quantum-corrected BH: the effective potential, energy, angular momentum, and innermost stable circular orbit (ISCO). In addition, we explore the radiation properties of the accretion disk around the quantum-corrected BH considering the Novikov-Thorne model. We find that the values of the flux of the electromagnetic radiation and the temperature of the disk increase slightly with the increase of the quantum correction parameter α. To obtain more information, we plot the temperature profile using a color map. Finally, we consider the spectral luminosity of the accretion disk under the influence of the quantum correction parameter α.

Revised classification of the CHIME fast radio bursts with machine learning

Liang Liu, Hai-Nan Lin, Li Tang

2026, 50(1): 015102. doi: 10.1088/1674-1137/ae0725

Abstract:
Fast radio bursts (FRBs) are short-duration and energetic radio transients of unknown origin. Observationally, they are commonly categorized into repeaters and non-repeaters. However, this binary classification may be influenced by observational limitations such as sensitivity and time coverage of telescopes. In this study, we employ unsupervised machine learning techniques to re-examine the CHIME/FRB catalog, with the goal of identifying intrinsic groupings in the FRB population without relying on preassigned labels. Using t-distributed stochastic neighbor embedding (t-SNE) for dimensionality reduction and hierarchical density-based spatial clustering of applications with noise (HDBSCAN) for clustering, we find that the FRB sample naturally separates into two major clusters. One cluster contains nearly all known repeaters but is contaminated by some apparently non-repeaters, while the other cluster is dominated by non-repeaters. This suggests that certain FRBs previously labeled as non-repeaters may share intrinsic similarities with repeaters. Mutual information analysis reveals that rest-frame frequency width and peak frequency are the most informative features governing the clustering structure. Even when reducing the input space to just these two features, the classification remains robust.

Dark matter subhalo evaporation by Coulomb-like interaction with galactic gas

Yugen Lin, Yu Gao

2026, 50(1): 015104. doi: 10.1088/1674-1137/ae07be

Abstract:
Coulomb-like interactions typically have a cross-section that scales with relative particle velocity according to $ \sigma=\sigma_0 v^{-4} $. The momentum transfer rate between slightly charged dark matter (DM) and ionized particles increases significantly at low velocity, producing prominent evaporation effects on small-sized DM overdensities, which is a non-negligible influence for the evolution of DM subhalos. We calculate the subhalo evaporation rate in the ionized galactic region and show that, below the limits from current cosmic microwave background and baryon acoustic oscillation data, galactic ionized particles can effectively evaporate subhalos with masses below $ 10^{7.5} \;M_\odot $ at a kilo-parsec distance from the galactic center, which can potentially affect the subhalo distribution in the inner galaxy. We also show the evaporation limits in terms of the electron-recoil direct detection cross-section and show that the evaporation effects can readily extend to the sub-MeV range, which is unconstrained in direct detection experiments.

Testing Einstein-Maxwell Power-Yang-Mills hair via black hole photon rings

2026, 50(1): 015101. doi: 10.1088/1674-1137/ae039c

Abstract:
In this paper, the optical appearance of static and spherically symmetric hairy black holes is studied under the standard Einstein-Maxwell theory considering the p-power Yang-Mills term. During the research process, the specific case of $ p=1/2 $ was primarily selected for discussion. To understand the impact of the hairy parameter on black holes, we have studied the event horizon radius $ r_{\rm h} $, photon sphere radius $ r_{\rm ph} $, and radius of the innermost stable circular orbit $ r_{\rm isco} $ of this hairy black hole. Subsequently, we utilize the backward ray-tracing method to analyze the geodesics of photons around this black hole and discuss the influence of the hairy parameter on the photon geodesics. In addition, we calculate the distinctive shadow and photon ring structures of the black hole illuminated by a static thin accretion disk using three toy-model emission functions, and we briefly compare the optical appearance of the black hole in this nonlinear case ($ p=1/2 $) with that in the standard Yang-Mills case ($ p=1 $). The research results show that as the hairy parameter gradually increases, $ r_{\rm h} $, $ r_{\rm ph} $, $ r_{\rm isco} $, and the critical impact parameter $ b_{\rm ph} $ of the black hole all exhibit a decreasing trend. Meanwhile, it also causes the area of the black hole shadow and the photon ring to decrease accordingly. Compared with the standard case ($ p=1 $), the nonlinear Einstein-Maxwell Yang-Mills black hole exhibits a larger shadow radius and brighter ring radius but with an overall dimmer brightness relative to the standard scenario, demonstrating observable differences. Consequently, for the static and spherically symmetric Einstein-Maxwell power-Yang-Mills hairy black hole, no degeneracy occurs in the photon ring and shadow. Theoretically, it can reflect different black hole solutions and thus verify the Yang-Mills hair.

Corrected first law of thermodynamics for dynamical regular black holes

Tianxu Huo, Chengzhou Liu

2025, 49(12): 125104. doi: 10.1088/1674-1137/adf541

Abstract:
In this study, we establish the corrected first law of thermodynamics for dynamical regular black holes on both the event and apparent horizons. We found that the temperature of dynamical regular black holes derived from the traditional first law differs from that obtained through other approaches. This indicates that, similar to static cases, the first law of thermodynamics requires correction. We derived the corrected first law of thermodynamics from the Einstein field equations. Our analysis reveals that the corrected factor originates from the fact that the $T_v^v$ component of the energy-momentum tensor depends on the black hole mass. This dependence implies that the mass of a regular black hole can no longer be directly identified as the internal energy, leading to corrections of the first law of thermodynamics.

Shadow and accretion disk images of the rotation loop quantum black bounce

Ke-Jian He, Huan Ye, Xiao-Xiong Zeng, Li-Fang Li, Peng Xu

2025, 49(12): 125103. doi: 10.1088/1674-1137/adf4a2

Abstract:
In this study, we investigate the shadow and observational image of the Kerr-like Loop Quantum Gravity (LQG) inspired black bounce with the help of the celestial light and thin disk sources by employing the backward ray-tracing method. The results indicate that both the LQG parameter α and rotation parameter a contribute to a reduction in the shadow size. However, the influence of a is predominant, whereas that of α is supplementary. For the accretion disk model, we extend its inner edge to the black hole's event horizon, and the motion of particles is different in the regions inside and outside the innermost stable circular orbit. We find that the correlation parameters ($a, \alpha$), along with the observer’s inclination angle, affect the image’s asymmetry and the distortion of the inner shadow. As the inclination increases, the direct and lensed images diverge, creating a structure resembling a hat. Moreover, we investigate the redshift distribution of the direct lensed images of the accretion disk under different parameters and observation angles. The results show that the redshift distribution and observed intensity are evidently related to the behavior of accretion flow. These results may provide a potential approach for limiting black hole parameters, detecting quantum gravity effects, and distinguishing the LQG black hole from other black hole models.

Generation of axions and axion-like particles through mass parametric resonance induced by scalar perturbations in the early universe

2025, 49(12): 125108. doi: 10.1088/1674-1137/adfa82

Abstract:
Axions and axion-like particles can be generated in the early universe through mechanisms such as misalignment production, thermal processes, and the decay of topological defects. In this study, we show that scalar perturbations in the early universe can produce a significant amount of these particles primarily through mass parametric resonance effects. Scalar perturbations induce temperature fluctuations during the particle mass transition era, e.g., during the QCD phase transition. These temperature fluctuations modulate the particle mass, transferring energy into the field through parametric mass resonance, a nonlinear process. This mechanism exhibits substantially unstable regions that could lead to explosive particle production. Notably, it does not generate additional isocurvature perturbations.

Valence quark distributions of pions: insights from Tsallis entropy

Jingxuan Chen, Xiaopeng Wang, Yanbing Cai, Xurong Chen, Qian Wang

2026, 50(1): 013103. doi: 10.1088/1674-1137/ae0998

Abstract:
We investigate the valence quark distributions of pions at a low initial scale ($Q^2_0$) using Tsallis entropy, a non-extensive measure that effectively captures long-range correlations among internal constituents. Utilizing the maximum entropy approach, we adopt two distinct functional forms and fit experimental data using the elegant GLR-MQ-ZRS evolution equation to derive the model parameters. Our findings indicate that the resulting valence quark distributions provide an optimal fit to the experimental data, with q values deviating from unity. This deviation indicates that correlations among valence quarks play a significant role in shaping understanding of the internal structures of pions. Additionally, our computations of the first three moments of the pion quark distributions at $ Q^2 = 4$ GeV² display consistency with other theoretical models, thereby reinforcing the importance of incorporating valence quark correlations within this analytical framework.

Soft pattern of gravitational Rutherford scattering from heavy target mass expansion

2026, 50(1): 013102. doi: 10.1088/1674-1137/ad62d6

Abstract:
We investigate the soft behavior of the tree-level Rutherford scattering processes mediated via t-channel one-graviton exchange. We consider two types of Rutherford scattering processes: a low-energy massless structureless projectile (up to spin-1) hits a static massive composite particle carrying various spins (up to spin-2), and slowly moving light projectile hits a heavy static composite target. The unpolarized cross sections in the first type exhibit universal forms at the first two orders in $ 1/M $ expansion, yet differ at the next-to-next-to-leading order, though some terms at this order still remain universal or depend on the target spin in a definite manner. The unpolarized cross sections in the second type are universal at the lowest order in projectile velocity expansion and through all orders in $ 1/M $, independent on the spins of both projectile and target. The universality partially breaks down at relative order-$ v^2/M^2 $, albeit some terms at this order still depend on the target spin in a specific manner.

Unveiling the inner structure of the Pion’s first excited state

Xiaobin Wang, Lei Chang

2025, 49(12): 123107. doi: 10.1088/1674-1137/adfc34

Abstract:
By capturing the characteristics of the Bethe-Salpeter amplitude for the pion excitation state, we construct an algebraic model to provide the overall features of the pion’s first excitation state parton distribution amplitude and distribution function. We find that, at the hadronic scale, the distribution amplitude of the excited state exhibits nodes, while the distribution function is unimodal, with a peak at $x=1/2 $ and distinct concave and convex fluctuations in the valence region. These findings provide new insights into the partonic structure of excited mesons and contribute significantly to our understanding of hadronic excitations.

Search for η₁(1855) in χ_cJ → ηηη′ decays

M. Ablikim, M. N. Achasov, P. Adlarson, X. C. Ai, R. Aliberti, A. Amoroso, Q. An, Y. Bai, O. Bakina, Y. Ban, H.-R. Bao, V. Batozskaya, K. Begzsuren, N. Berger, M. Berlowski, M. Bertani, D. Bettoni, F. Bianchi, E. Bianco, A. Bortone, I. Boyko, R. A. Briere, A. Brueggemann, H. Cai, M. H. Cai, X. Cai, A. Calcaterra, G. F. Cao, N. Cao, S. A. Cetin, X. Y. Chai, J. F. Chang, G. R. Che, Y. Z. Che, C. H. Chen, Chao Chen, G. Chen, H. S. Chen, H. Y. Chen, M. L. Chen, S. J. Chen, S. L. Chen, S. M. Chen, T. Chen, X. R. Chen, X. T. Chen, X. Y. Chen, Y. B. Chen, Y. Q. Chen, Z. Chen, Z. J. Chen, Z. K. Chen, S. K. Choi, X. Chu, G. Cibinetto, F. Cossio, J. Cottee-Meldrum, J. J. Cui, H. L. Dai, J. P. Dai, A. Dbeyssi, R. E. de Boer, D. Dedovich, C. Q. Deng, Z. Y. Deng, A. Denig, I. Denysenko, M. Destefanis, F. De Mori, B. Ding, X. X. Ding, Y. Ding, Y. X. Ding, J. Dong, L. Y. Dong, M. Y. Dong, X. Dong, M. C. Du, S. X. Du, Y. Y. Duan, P. Egorov, G. F. Fan, J. J. Fan, Y. H. Fan, J. Fang, S. S. Fang, W. X. Fang, Y. Q. Fang, R. Fari

2025, 49(12): 123001. doi: 10.1088/1674-1137/addfcc

Abstract:
Based on a sample of $2.7\times10^{9}$ $\psi(3686)$ events collected by the BESIII detector operating at the BEPCII collider, the decay $\psi(3686)\to\gamma\chi_{cJ}, \chi_{cJ}\to\eta\eta\eta^{\prime}$ is analyzed. The decay modes $\chi_{c1}$ and $\chi_{c2}\to\eta\eta\eta^{\prime}$ are observed for the first time, and their corresponding branching fractions are determined to be ${\cal{B}}(\chi_{c1}\to\eta\eta\eta^{\prime}) = $$ (1.40\, \pm 0.13\, (\text{stat.}) \pm 0.09\, (\text{sys.})) \times 10^{-4}$ and ${\cal{B}}(\chi_{c2}\to\eta\eta\eta^{\prime}) = (4.18\, \pm 0.84\, (\text{stat.}) \pm 0.48\, (\text{sys.})) \times 10^{-5}$. An upper limit on the branching fraction of $\chi_{c0}\to\eta\eta\eta^{\prime}$ is set as $2.59 \times 10^{-5}$ at a 90% confidence level (CL). A partial wave analysis (PWA) of the decay $\chi_{c1}\to\eta\eta\eta^{\prime}$ is performed to search for the $1^{-+}$ exotic state $\eta_1(1855)$. The PWA result indicates that the structure in the $\eta\eta^{\prime}$ mass spectrum is attributed to $f_0(1500)$, while in the $\eta\eta$ mass spectrum, it is attributed to the $0^{++}$ phase space. The upper limit of ${\cal{B}}(\chi_{c1}\to\eta_{1}(1855)\eta) \cdot {\cal{B}}(\eta_{1}(1855)\to\eta\eta^{\prime})< $$ 9.79 \times 10^{-5}$ is set based on the PWA at 90% CL.

On the pole trajectory of the subthreshold negative parity nucleon with varying pion masses

Qu-Zhi Li, Zhiguang Xiao, Han-Qing Zheng

2025, 49(12): 123103. doi: 10.1088/1674-1137/adfa02

Abstract:
We study the pole trajectory of the recently established subthreshold negative-parity nucleon pole, namely the $N^*(920)$, with varying pion masses in the scheme of linear σ model with nucleons, using the $N/D$ unitarization method. We find that, as the pion mass increases, the pole moves toward the real axis. For larger pion masses, at tree level, the pole falls to a specific point on u-channel cut and crosses to the adjacent Riemann sheet defined by the logarithmic u-channel cut. At the one-loop level, the pole does not meet the u-cut up to $m_\pi=0.36$ GeV. We also re-examined the σ pole trajectory and found it to be in good agreement with the Roy equation analysis result.

Study of χ_cJ (J = 0,1,2) decays to light meson pairs based on SU(3) flavor symmetry/breaking analysis

Bo Lan, Qin-Ze Song, Jin-Huan Sheng, Yi Qiao, Ru-Min Wang

2025, 49(12): 123106. doi: 10.1088/1674-1137/adff00

Abstract:
Based on available experimental results on $ \chi _{cJ}(J=0,1,2) $ decays, we investigated the $ \chi_{cJ}\to PP $, $ VV $, $ PV $, and $ PT $ decays using the SU(3) flavor symmetry/breaking approach, where P, V, and T denote light pseudoscalar, vector, and tensor mesons, respectively. With the decay amplitude relations determined by SU(3) flavor symmetry/breaking, we present the branching ratios for all $ \chi_{cJ}\to PP $ and $ \chi_{cJ}\to VV $ modes, including those without experimental data. While theoretical considerations strongly suppress or even forbid most $ \chi_{cJ}\to PV $ and $ PT $ decays, we also provide quantitative predictions constrained by existing experimental data. Our results are expected to be accessible in future experiments at BESIII and the planned Super Tau-Charm Facility.

$ {{\boldsymbol D}^*_{ {({\boldsymbol s})}}{\bf\to} {\boldsymbol P} }$ form factors and their applications to semi-leptonic and non-leptonic weak decays

Hao Yang, Zhi-Qing Zhang, You-Ya Yang, Peng Li

2025, 49(12): 123104. doi: 10.1088/1674-1137/adfb5d

Abstract:
Similar to other heavy flavor mesons, the weak decays of $ D^*_{(s)} $ mesons can provide a platform to verify the standard model, explore new physics, and understand the mechanisms of weak interactions. At present, the theoretical and experimental studies on $ D^*_{(s)} $ mesons are relatively limited. In addition to the dominant electromagnetic decays, the $ D^*_{(s)} $ weak decays should be feasible to explore the $ D^*_{(s)} $ mesons. In this study, we used the covariant light-front quark model to study the form factors of the transitions $ D^*_{(s)}\to \pi, K, \eta_{q, s} $, and then calculated the branching ratios of the semi-leptonic decays $ D^*_{(s)}\to P\ell^{+}\nu_{\ell} $ and the non-leptonic decays $ D^*_{(s)}\to PP, PV $ with $ P=\pi, K, \eta^{(\prime)}, $$ V=\rho, K^*, \phi $, and $ \ell=e, \mu $. The channels $ D_{s}^{*+}\to\eta \ell^{+}\nu_{\ell} $ and $ D^{*+}_{s}\to \eta\rho^{+} $ possess the largest branching ratios, which can reach an order of $ 10^{-6} $ among these decays, and are most likely to be accessible in experiments at future high-luminosity colliders. Furthermore, we predict and discuss the longitudinal polarization fraction $ f_{\rm L} $ and the forward-backward asymmetry $ A_{\rm FB} $ for the considered semi-leptonic $ D^*_{(s)} $ decays.

Charmed meson structure across crossover from SU(4) Polyakov quark meson model with isospin asymmetry

Abdel Magied DIAB

2026, 50(1): 013101. doi: 10.1088/1674-1137/ae042d

Abstract:
The Polyakov Quark Meson (PQM) model is extended to SU(4) flavor symmetry by incorporating the charm quark and introducing a finite isospin asymmetry. This model incorporates the light, strange, and charm chiral condensates, along with the Polyakov-loop variables, to describe the confinement–deconfinement phase transition in a thermal and dense QCD medium. The inclusion of the charm quark condensate enhances the capability of the SU(4) PQM model to explore the spatial and thermal resolution of the chiral phase structure, particularly in the crossover and high-temperature regimes. We construct the QCD phase diagram ($ T/T_\chi-\mu_I/m_\pi $) plane, indicating a decrease in the pseudo-critical temperature as the isospin chemical potential increases, and explore thermodynamic quantities related to the QCD equation of state at very high temperatures. Fluctuations of quark flavors, conserved charges, and baryon-charm correlations are studied across a wide temperature range. The SU(4) PQM model exhibits good qualitative agreement with lattice QCD calculations. Additionally, we calculate the meson mass spectrum at zero and finite temperature, showing that the charm sector remains thermally stable over a wide temperature range. Overall, this study highlights the capability of the SU(4) PQM model to describe key features of the QCD matter at high temperatures and its relevance to heavy-ion collisions and astrophysical studies.

Phase transitions in dimensional reduction up to three loops

Mikael Chala, Luis Gil, Zhe Ren

2025, 49(12): 123105. doi: 10.1088/1674-1137/adf322

Abstract:
We perform the first computation of phase-transition parameters to cubic order in $ \lambda\sim m^2/T^2 $, where m is the scalar mass and T is the temperature, in a simple model resembling the Higgs sector of the SMEFT. We use dimensional reduction, including 1-loop matching corrections for terms of dimension 6 (in 4-dimensional units), 2-loop contributions for dimension-4 ones and 3-loops for the squared mass. We precisely quantify the size of the different corrections, including renormalization-group running as well as quantum effects from light fields in the effective theory provided by the Coleman-Weinberg potential, and discuss briefly the implications for gravitational waves. Our results suggest that, for strong phase transitions, 1-loop corrections from dimension-6 operators can compete with 2-loop ones from quartic couplings and largely surpass those from 3-loop thermal masses.

Extra charged gauge boson W′ in Alternative Left-Right Model at future muon collider

Liuxin Zhao, Honglei Li, Zhi-Long Han, Fei Huang, Xinyi Yan

2025, 49(12): 123102. doi: 10.1088/1674-1137/adec51

Abstract:
The study of extra charged gauge bosons beyond the Standard Model has always been of great interest. Future muon colliders will have a significant advantage in discovering exotic particles. In this paper, by studying the $ \mu^+ \mu^- \to W^{\prime +} W^{\prime -} \to e^+ e^- n_e \bar{n}_e $ process, we explore the properties of $ W^\prime $ in the alternative left-right model. The cross section and angular distribution of the final electron are investigated in a scenario of different $ W^\prime $ masses and right-handed coupling constants. The forward-backward asymmetry is also an important observable to reflect the properties of $ W^\prime $. We provide a method to effectively suppress the background processes by imposing constraints on the transverse momentum $ P_T $ and azimuthal angle of the final-state electrons α. With cuts of $ 600<P_T<3500 $ GeV and $ 0.5<\alpha<3 $, the significance exceeds 5σ for 4.8 TeV $ W^\prime $ at a collision energy of 10 TeV.

SU(3) flavor symmetry analysis of hyperon non-leptonic two body decays

2025, 49(12): 123101. doi: 10.1088/1674-1137/adf1f1

Abstract:
This paper presents a systematic study of hyperon non-leptonic two-body decays induced by light quark transitions, particularly the $ s \rightarrow u\bar{u}d $ process, within the framework of SU(3) flavor symmetry. The effective weak Hamiltonian is decomposed into irreducible SU(3) representations, including the 27-plet and octet components, and applied to analyze decays of octet and decuplet baryons and charmed baryons. Both the irreducible representation amplitude (IRA) approach and the topological diagrammatic analysis (TDA) are employed to construct decay amplitudes and constrain the parameter space. SU(3) symmetry-breaking effects arising from the strange quark mass are incorporated systematically. A global fit to current experimental data allows us to extract form factors and predict branching ratios and asymmetry parameters for several decay channels. Our results demonstrate the predictive power of SU(3) flavor symmetry while highlighting significant symmetry-breaking effects, especially in amplitudes related to the 27-plet. Notably, the $ \Sigma^+ \rightarrow p\pi^0 $ decay channel exhibits a deviation exceeding $ 1\sigma $from experimental measurements, suggesting the possible presence of new decay mechanisms or contributions beyond the Standard Model. Besides, we also evaluate the size of symmetry breaking. However, the large uncertainty of the experimental data makes it difficult to precisely determine the value of symmetry breaking. We strongly recommend that future experimental efforts aim to reduce the measurement uncertainties, especially for the processes $ \Lambda^0\to p\pi^- $ and $ \Lambda^0\to n\pi^0 $, which have larger experimental errors compared to other data and play an important role in determining the symmetry breaking parameter. This study provides a systematic framework for future tests of the Standard Model and the search for new physics in hyperon decays.

Towards a detection of reactor ${\overline {\boldsymbol v}_{\boldsymbol e} \boldsymbol\to \overline {\boldsymbol v}_{\boldsymbol\mu} }$ and ${\overline {\boldsymbol v}_{\boldsymbol e} \boldsymbol\to \overline {\boldsymbol v}_{\boldsymbol\tau} }$ oscillations with possible CP violation

Yifang Wang, Zhi-zhong Xing, Shun Zhou

2026, 50(1): 011001. doi: 10.1088/1674-1137/ae0996

Abstract:
We propose a novel method to detect reactor $ \overline{\nu}^{}_e \to \overline{\nu}^{}_\mu $ and $ \overline{\nu}^{}_e \to \overline{\nu}^{}_\tau $ oscillations by using elastic antineutrino-electron scattering processes $ \overline{\nu}^{}_\alpha + e^- \to \overline{\nu}^{}_\alpha + e^- $ (for $ \alpha = e, \mu, \tau $), among which the $ \overline{\nu}^{}_e $ events can be singled out by accurately measuring the $ \overline{\nu}^{}_e $ flux via the inverse beta decay $ \overline{\nu}^{}_e + p \to e^+ + n $. A proof-of-concept study shows that such measurements will not only be able to test the conservation of probability for reactor antineutrino oscillations, but also offer a new possibility to probe leptonic CP violation at the one-loop level.

Systematic study of α decay half-life within cluster-formation model

Wen-Chao Dai, Jie-Dong Jiang, Yin Fan, Xiao Liu, Peng-Cheng Chu, Xi-Jun Wu, Xiao-Hua Li

2026, 50(1): 014103. doi: 10.1088/1674-1137/ae042c

Abstract:
In this study, based on the Wentzel-Kramers-Brillouin (WKB) theory, by parameterizing the assault frequency $ \nu $ as a function of the $ \alpha $ decay energy and charge radius of parent nucleus, with the $ \alpha $ decay preformation factor $ P_\alpha $ being calculated through the cluster-formation model (CFM), we systematically investigate the $ \alpha $ decay half-lives of 559 nuclei from the ground state, including 177 even-even, 277 odd-A, and 105 odd-odd nuclei. The calculated results indicate that our model can effectively reproduce the experimental data, with a corresponding standard deviation of 0.408. In addition, we use this model to predict the $ \alpha $ decay half-lives of 70 even-even, odd-A, and odd-odd nuclei with Z = 119 and 120. For comparison, we also use the universal decay law (UDL) proposed by Qi et al. [Phys. Rev. Lett 103, 072501 (2009)] and the unitary Royer formula (DZR) proposed by Deng et al. [Phys. Rev. C 101, 034307 (2020)]. The calculated results are in good agreement.

Correlation between Zero-Sound modes and nuclear equation of state stiffness detected by light vector boson

2026, 50(1): 014101. doi: 10.1088/1674-1137/adfa81

Abstract:
We investigate zero-sound modes in nuclear matter and neutron star matter using the relativistic random phase approximation (RRPA), focusing on the role of a light vector U boson in stiffening the nuclear equation of state (EOS). The occurrence of zero sound is closely linked to the stiffness of the nuclear EOS. The additional vector repulsive potential induced by the U boson results in the occurrence of zero sound at high densities in models with a soft high-density EOS, and the density range for zero sound extends to higher densities with larger coupling strength of the U boson. This confirms the unambiguous role of stiffening the high-density EOS in resulting in the appearance of zero sound.

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