Chinese Physics C

Phenomenological study of Ω_c → Ω⁻π⁺ at polarized electron-positron collider

Yunlu Wang, Yunlong Xiao, Pengcheng Hong

Published: , doi: 10.1088/1674-1137/ae6311

Abstract:
The exploration of symmetry laws stands as a cutting-edge direction in modern physics research. This work delves into the examination of P and

\begin{document}$ CP $\end{document}

symmetry properties within the charm quark system by analyzing asymmetry parameters in the two-body decay process of

\begin{document}$ \Omega_c $\end{document}

. By accounting for the polarization effects of electron and positron beams and employing the helicity formalism, we systematically analyze the decay characteristics of

\begin{document}$ \Omega_c $\end{document}

and its subsequent hyperon decays through specific asymmetry parameters. A comprehensive formulation of the angular distribution for these decay processes has been developed. The research assesses the detection sensitivity of asymmetry parameters in the

\begin{document}$ \Omega_c\rightarrow \Omega^-\pi^+ $\end{document}

decay mode across different experimental conditions, including varying data sample sizes and beam polarization configurations. These results contribute to enriching a theoretical foundation for forthcoming experimental endeavors at the STCF, offering significant implications for symmetry studies in the charm sector.

Probing the scalar-induced gravitational waves with the Five-hundred-meter Aperture Spherical radio Telescope and the Square Kilometer Array

Jun Li, Guanghai Guo, Pengfei Yan

Published: , doi: 10.1088/1674-1137/ae6630

Abstract:
Gravitational-wave astronomy offers a promising opportunity to directly observe scalar-induced gravitational waves originating from the early universe. Experiments—including ground-based interferometers such as LIGO and Virgo, and pulsar timing arrays (PTAs) based on facilities such as FAST and SKA—are poised to significantly enhance sensitivity to these signals. In this paper, we combine Cosmic Microwave Background (CMB) and Baryon Acoustic Oscillation (BAO) datasets with upper or lower limits on the stochastic gravitational-wave background provided by FAST or SKA to constrain scalar-induced gravitational waves. To provide a comprehensive forecast, we consider two scenarios at a given frequency: one in which FAST or SKA does not detect scalar-induced gravitational waves, thereby setting an upper limit on the fractional energy density; and another in which these waves are detected, thus establishing a lower limit. In the ΛCDM+r model, the scalar spectral index of the power-law power spectrum is constrained to

\begin{document}$ n_s=0.9598^{+0.0013}_{-0.0009} $\end{document}

from the combination of CMB+BAO+SKA datasets in the upper-limit scenario where scalar-induced gravitational waves propagate at the speed of light. The constraint shifts to

\begin{document}$ n_s = 0.9697\pm{0.0033} $\end{document}

in the lower-limit scenario. Compared with the constraint from the combination of CMB+BAO datasets, the scalar spectral index

\begin{document}$ n_s $\end{document}

in the upper-limit scenario exhibits significant changes, which could serve as an indicator of scalar-induced gravitational waves. In the ΛCDM+

\begin{document}$ \alpha_s $\end{document}

+r and ΛCDM+

\begin{document}$ \alpha_s $\end{document}

+

\begin{document}$ \beta_s $\end{document}

+r models, the running of the scalar spectral index

\begin{document}$ \alpha_s $\end{document}

and the running of the running

\begin{document}$ \beta_s $\end{document}

also show notable variations, suggesting potential indicators. The numerical findings clearly demonstrate the impact of the upper and lower limits provided by FAST or SKA.

Higgs Bosons at 95 and 125 GeV in the U(1)_XVLFM

Rong-Zhi Sun, Shu-Min Zhao, Meng-Zi Cao, Song Gao, Xing-Xing Dong

Published: , doi: 10.1088/1674-1137/ae5ef8

Abstract:
We present a systematic analysis of the Higgs signal strengths at 125 GeV and 95 GeV in a non-supersymmetric

\begin{document}$ U(1)_X $\end{document}

model with vector-like fermions (

\begin{document}$ U(1)_X $\end{document}

VLFM). This framework extends the Standard Model (SM) by introducing an additional

\begin{document}$ U(1)_X $\end{document}

gauge symmetry, three right-handed neutrinos, two singlet Higgs fields (ϕ and S), and one generation of vector-like quarks and leptons. The scalar fields mix in the neutral CP-even sector, yielding two Higgs-like states around 95 GeV and 125 GeV. We perform a

\begin{document}$ \chi^2 $\end{document}

analysis that combines the Higgs signal strength measurements at 125 GeV from ATLAS and CMS, including the

\begin{document}$ \gamma\gamma $\end{document}

,

\begin{document}$ WW^* $\end{document}

,

\begin{document}$ ZZ^* $\end{document}

,

\begin{document}$ b\bar{b} $\end{document}

, and

\begin{document}$ \tau\bar{\tau} $\end{document}

channels, together with the 95 GeV excesses observed in the diphoton and

\begin{document}$ b\bar{b} $\end{document}

final states reported by CMS and LEP. Our results indicate that the

\begin{document}$ U(1)_X $\end{document}

VLFM successfully reproduces the observed signal strengths of the 125 GeV Higgs while simultaneously explaining the 95 GeV excess. The parameters

\begin{document}$ g_X $\end{document}

,

\begin{document}$ g_{YX} $\end{document}

,

\begin{document}$ v_S $\end{document}

,

\begin{document}$ v_P $\end{document}

, and the new Yukawa couplings play a crucial role in achieving this consistency.

Neutrino tomography with a three-dimensional model of Earth's density

Jiayi Wei, Junhui Xing, Sujie Lin, Xiurong Li, Jiwei Tian

Published: , doi: 10.1088/1674-1137/ae5c85

Abstract:
Neutrino Earth tomography provides an observational approach to studying the Earth's deep three-dimensional structure that is distinct from seismology. However, most existing studies still rely on one-dimensional density models and therefore cannot adequately represent lateral heterogeneity within the Earth. To address this issue, this study integrates PREM, CRUST1.0, and HMSL-S06 on a tesseroid grid to construct a non-spherically symmetric three-dimensional Earth density model that includes large low-velocity provinces (LLVPs) in the deep mantle. We also develop a corresponding procedure for extracting neutrino propagation trajectories and derive closed-form expressions for the total mass and axial moment of inertia of the discrete model, which are used as global consistency checks. Within an exact three-flavor oscillation framework, we use public Super-Kamiokande data products to compare the event counts predicted by the three-dimensional model with those from a conventional one-dimensional spherically symmetric model. The results show that, under the present calculation scheme, the differences in the overall event count distributions between the three-dimensional model and the one-dimensional reference model remain limited. This study establishes a three-dimensional calculation framework that can provide a methodological basis for future investigations of how lateral density heterogeneity may affect atmospheric neutrino propagation.

Circular orbits and observational features of the rotating Simpson-Visser black hole surrounded by a thin accretion disk

Ziyang Li, Shou-Qi Liu, Jia-Hui Huang

Published: , doi: 10.1088/1674-1137/ae5ef3

Abstract:
Since the Event Horizon Telescope (EHT) collaboration released horizon-scale images of the supermassive black holes Sgr A* and M87*, a new observational window for probing black hole spacetimes in the strong-gravity regime has opened. As an important class of Kerr black hole mimickers, rotating Simpson-Visser (SV) black holes exhibit a degeneracy with Kerr black holes in terms of shadow size, making them difficult to distinguish using shadow observations alone. Motivated by this issue, we present a systematic investigation of the radiative properties and optical appearance of rotating SV black holes surrounded by a thin accretion disk, focusing on the influence of the regularization parameter g on the relevant observables. The results show that although the kinematic quantities and the location of the innermost stable circular orbit (ISCO) depend on the regularization parameter g, the radiative efficiency of the rotating SV black hole is the same as that of its Kerr counterpart. Within the Novikov-Thorne thin-disk model, we study the radiative flux, effective temperature, and spectral luminosity; adopting observational parameters relevant to Sgr A* and M87*, we compute concrete examples for rotating SV black holes and compare them with those for Kerr black holes. The results show that the parameter g suppresses the maximum values of these quantities. In addition, using a backward ray-tracing technique, we numerically simulate the optical appearance of rotating SV black holes and analyze the corresponding intensity images, redshift, and observed flux distributions. Our results indicate that these quantities are sensitive to g. In particular, as g increases, the observed intensity is significantly suppressed, and the photon ring region exhibits a remarkable increase in width. Our findings suggest that accretion-disk-related observables may provide important avenues to distinguish between rotating SV black holes and Kerr black holes, and offer theoretical guidance for future high-resolution observations.

Searching the possibility of a₀(1450) scalar state being a qq state structure via charmed meson semileptonic decays

Ya-Lin Song, Yin-Long Yang, Ye Cao, Xue Zheng, Hai-Bing Fu

Published: , doi: 10.1088/1674-1137/ae5ef7

Abstract:
The internal structure of the light scalar state

\begin{document}$ a_0(1450) $\end{document}

has not been definitively determined; it may comprise multiple possible configurations. Among these, it may be regarded as a

\begin{document}$ q\bar{q} $\end{document}

state. Based on this possibility, we use QCD light-cone sum rules to study the semileptonic decay process

\begin{document}$ D \to a_0(1450)\ell \nu_\ell $\end{document}

with

\begin{document}$ \ell=(e, \mu) $\end{document}

and to test this hypothesis. First, we construct two twist-2 light-cone distribution-amplitude schemes based on the light-cone harmonic-oscillator model, and present their moments

\begin{document}$ \langle\xi^{n}\rangle |_{\mu} $\end{document}

and Gegenbauer moments

\begin{document}$ a_{n}(\mu) $\end{document}

at

\begin{document}$ \mu_0=1\; {\rm{GeV}} $\end{document}

and

\begin{document}$ \mu_k= 1.4\; {\rm{GeV}} $\end{document}

for

\begin{document}$ n=(1,3,5) $\end{document}

. In the large-recoil region, we obtain the transition form factors (TFFs):

\begin{document}$ f_+^{({\rm{S}}1)}(0) = 0.836_{-0.119}^{+0.116} $\end{document}

,

\begin{document}$ f_+^{({\rm{S}}2)}(0)=0.767_{-0.105}^{+0.106} $\end{document}

, and

\begin{document}$ f_-(0)=0.630_{-0.077}^{+0.078} $\end{document}

. A simplified series expansion

\begin{document}$ z(q^2, t) $\end{document}

is used to extrapolate the TFFs to the entire physical

\begin{document}$ q^2 $\end{document}

region. For

\begin{document}$ q^2=10^{-5} \; {\rm{GeV}}^2 $\end{document}

, we compute the angular distribution of the differential decay width

\begin{document}$ {d\Gamma}/{d\cos\theta_\ell } $\end{document}

over the range

\begin{document}$ \cos\theta_\ell \in [-1,1] $\end{document}

. Subsequently, we obtain the differential decay widths and branching fractions for

\begin{document}$ D^0 \to a_0(1450)^- \ell^+ \nu_\ell $\end{document}

and

\begin{document}$ D^- \to a_0(1450)^0 \ell^- \bar{\nu}_\ell $\end{document}

, with branching fractions of order

\begin{document}$ 10^{-6} $\end{document}

. Finally, we analyze three angular observables for the semileptonic decay process

\begin{document}$ D^- \to a_0(1450)^0 \ell^- \bar{\nu}_\ell $\end{document}

: the forward–backward asymmetry

\begin{document}$ {\cal{A}}_{\rm{FB}} $\end{document}

, the lepton polarization asymmetry

\begin{document}$ {\cal{A}}_{\lambda_\ell} $\end{document}

, and the

\begin{document}$ q^2 $\end{document}

-differential flat term

\begin{document}$ {\cal{F}}_{\rm{H}} $\end{document}

.

Neutral scalar pair production via W-boson fusion at multi–TeV muon colliders

Khiem Hong Phan, Quang Hoang-Minh Pham

Published: , doi: 10.1088/1674-1137/ae62fa

Abstract:
In this work, we present the first computation of the full one-loop electroweak radiative corrections to the process

\begin{document}$ \mu^- \mu^+ \to W^\pm W^\mp \to hh $\end{document}

within the Standard Model (SM). Building upon this, we investigate neutral scalar pair production via vector boson fusion at multi–TeV muon colliders in the framework of the Two-Higgs-Doublet Model (2HDM). In our phenomenological analysis, we introduce an enhancement factor, defined as the ratio of the cross section for SM-like Higgs pair production in the 2HDM to the corresponding SM prediction. This factor is systematically evaluated across the allowed regions of parameter space in both Type-X and Type-Y 2HDMs. Our results indicate that, within the viable Type-X parameter space, this factor can reach a value of 3, whereas it remains between 0.91 and 0.95 across the allowed parameter space of the Type-Y scenario. We observe that the enhancement factor exhibits distinct behaviors in the Type-X and Type-Y 2HDMs. This feature provides a promising opportunity to discriminate between the two scenarios through precision measurements of double Higgs production at future multi–TeV colliders. Furthermore, we perform a detailed scan of the cross sections for both CP-odd and CP-even Higgs pair production over the viable parameter spaces of the Type-X and Type-Y 2HDMs. In the Type-Y scenario, at a center-of-mass (CoM) energy

\begin{document}$ \sqrt{s} = 10\; \text{TeV} $\end{document}

and an integrated luminosity of

\begin{document}$ {\cal{L}} = 10000\; \text{fb}^{-1} $\end{document}

, both CP-odd and CP-even Higgs pair production in the

\begin{document}$ t\bar{t}b\bar{b} $\end{document}

final state, with subsequent top-quark decays into leptons and bottom quarks, can be probed with a statistical significance exceeding the

\begin{document}$ 2\sigma $\end{document}

level at several viable parameter points.

Holographic QCD equation of state constrained by lattice QCD: neural-ODE for probe-limit and a back-reaction test

Yutian Deng, Mei Huang, Lin Zhang

Published: , doi: 10.1088/1674-1137/ae62fc

Abstract:
We study the equation of state (EoS) of QCD matter in a bottom-up holographic setup that combines an Einstein-Maxwell-dilaton (EMD) sector with an improved Karch-Katz-Son-Stephanov (KKSS) flavor action. In the probe approximation, we perform an inverse reconstruction of the model functions by parameterizing them with neural networks and solving the EMD equations via a differentiable ODE solver (a neural ODE framework), calibrating the model to a reference thermodynamic table for

\begin{document}$(2+1)$\end{document}

-flavor QCD at finite temperature and finite baryon chemical potential. The reconstructed model functions are then parameterized and kept fixed across thermodynamic states. Next, viewing the EMD sector as an effective description of pure Yang-Mills theory, we fix its parameters by fitting the

\begin{document}$\mu_B=0$\end{document}

lattice pure-glue EoS using a hybrid optimization strategy. Finally, we go beyond the probe limit and solve the coupled EMD+KKSS equations with back-reaction, using the pure-glue-calibrated EMD sector as a fixed input and varying the KKSS couplings to compare with the

\begin{document}$\mu_B=0$\end{document}

two-flavor lattice EoS. We find a visible mismatch and a high-temperature behavior in which the back-reacted dimensionless ratios approach a nearly

\begin{document}$\beta_1$\end{document}

-insensitive plateau close to the pure-glue baseline, providing a simple structural diagnostic for the present flavor-sector truncation.

The atomic nucleus as a bound system of 3A quarks

B. P. Kosyakov, E. Yu. Popov, M. A. Vronski

Published: , doi: 10.1088/1674-1137/ae5ef6

Abstract:
The atomic nucleus, viewed as a system of bound quarks, should, in principle, be described within an effective theory of low-energy quantum chromodynamics. This paper provides an overview of recently developed models that embody essential features of the desired effective theory. The Fermi gas model helps explain why the number of d quarks is approximately equal to that of u quarks in stable light nuclei up to

\begin{document}$ {}^{40}_{20}{\rm Ca} $\end{document}

. A modified bag model accounts for the deviation from this rule in heavier nuclei. With this model, the static properties of a wide range of stable nuclei can be described with reasonable accuracy. To make the most of the modified bag model, it is useful to invoke gauge/gravity duality. A refined version of duality states: "The dynamics inside an extremal black hole in

\begin{document}$ {{\rm{AdS}}}_5 $\end{document}

is mapped onto the corresponding dynamics of a stable subnuclear system in

\begin{document}$ {\mathbb R}_{1,3} $\end{document}

". This version of duality allows one to predict the primary decay channel of the lightest glueball. Another implication is that this framework explains why the periodic table contains a finite number of stable elements. Duality makes it possible to calculate the maximum allowed charge

\begin{document}$ Z_{{\rm{max}}} $\end{document}

of stable heavy nuclei:

\begin{document}$ Z_{{\rm{max}}}\approx 82 $\end{document}

, which is the charge of the

\begin{document}$ {}^{208}_{82}{\rm Pb} $\end{document}

nucleus.

Analysis of molecular state η_cD^* and J/ψD^* in the effective Lagrangian approach

Na Li, Ye Xing, Jing-Rui Shi

Published: , doi: 10.1088/1674-1137/ae5f08

Abstract:
In this work, we investigate the production and decay of molecular states with quark content

\begin{document}$cc\bar c\bar q$\end{document}

and

\begin{document}$J^P=1^+$\end{document}

using a phenomenological analysis and an effective Lagrangian approach. Based on an SU(3) flavor-symmetry analysis to identify golden channels, we further explore the dynamics of these processes under the molecular assumptions of

\begin{document}${\eta_c D^*}$\end{document}

and

\begin{document}${J/\psi D^*}$\end{document}

. Our results indicate that the production branching ratio in

\begin{document}$B_c$\end{document}

decays is sizable: it can be of order

\begin{document}$10^{-4}$\end{document}

for the molecular configuration

\begin{document}${{\eta}_cD^*}$\end{document}

and

\begin{document}$10^{-5}$\end{document}

for the molecule

\begin{document}${J/\psi D^*}$\end{document}

. In addition, we find that the decay widths of the two molecular configurations

\begin{document}${{\eta}_cD^*}$\end{document}

and

\begin{document}${J/\psi D^*}$\end{document}

are not significant, at the level of

\begin{document}${\cal{O}}$\end{document}

(

\begin{document}$\text{MeV}$\end{document}

).

Enhanced evidence of X(7200) and improved measurements of X(6900) parameters from a combined LHCb-ATLAS-CMS analysis

Yuan Wang, Ran Li, Bin Zhong, Ya-Qian Wang

Published: , doi: 10.1088/1674-1137/ae643e

Abstract:
We report stronger evidence for the

\begin{document}$X(7200)$\end{document}

state and markedly improved measurements of the

\begin{document}$X(6900)$\end{document}

resonance parameters based on a combined analysis of the di-

\begin{document}$J/\psi$\end{document}

mass spectrum using published data from LHCb, ATLAS, and CMS. Through simultaneous fits to the datasets from all three experiments, we observe the

\begin{document}$X(6900)$\end{document}

with overwhelming significance (

\begin{document}$>12\sigma$\end{document}

) and determine its mass and width with improved precision. For the

\begin{document}$X(7200)$\end{document}

, we find consistent signals across multiple interference models, with significances ranging from

\begin{document}$3.7\sigma$\end{document}

to

\begin{document}$6.6\sigma$\end{document}

; in the best-fit model (the CMS three-resonance scheme), the significance reaches

\begin{document}$6.6\sigma$\end{document}

, providing substantially stronger evidence for this state. Our results underscore the essential role of interference effects in fully charmed tetraquark spectroscopy and offer new constraints on their production mechanisms at the LHC.

Probing decoupled Throats of AdS_D Black Holes in D=6, 7

Weichao Bu, Yang Lei

Published: , doi: 10.1088/1674-1137/ae5ef2

Abstract:
The Kerr/CFT correspondence establishes a correspondence between extremal black holes in higher dimensions and a chiral conformal field theory (CFT) in their near-horizon limit. A generalization of this framework, known as the EVH/CFT correspondence, has been developed for four- and five-dimensional AdS black holes. It was further proposed in [1] that, for

\begin{document}${\rm{AdS}}_{D=6,7}$\end{document}

black holes, a generalized duality between

\begin{document}$(D-2)$\end{document}

-dimensional geometry and

\begin{document}$(D-3)$\end{document}

-dimensional field theory may emerge in a suitably defined extremal vanishing horizon (EVH) limit. In this work, we show that, in the EVH limit, the near-EVH geometries of these

\begin{document}${\rm{AdS}}_{D=6,7}$\end{document}

black holes reduce to lower-dimensional black holes whose metrics are conformally related to solutions of Einstein-Maxwell-Maxwell-dilaton (EMMD) gravity. This structural resemblance suggests a potential route toward the microscopic counting of non-AdS black hole entropy via higher-dimensional AdS/CFT techniques.

Measurement of the neutron capture cross section using C₆D₆ detectors at the milli-barn scale: a case study of ²⁰⁹Bi

Jing Liu, Song Feng, Wei Jiang, Xinxiang Li, Min Xiao, Pinjing Cheng, Jieming Xue, Baoqian Li, Jirong Zhao, Luyan Tao, Peng Luan, Wenxin Huang, Youchun Xiao, Sijia Han, Cunzhi Deng, Shiqi Tang, Yixi Chen, Mengyan Wang, Shiqing Yuan, Bo Zheng

Published: , doi: 10.1088/1674-1137/ae5ef9

Abstract:
Accurate neutron capture cross section data are essential for validating nuclear models, understanding the origin of heavy elements, and improving reactor safety assessments. Measuring weakly absorbing nuclides at the milli-barn scale is challenging due to low-intensity signals, high-level environmental background, and sensitivity to target impurities. To investigate the capability of milli-barn scale neutron capture cross section measurement using the

\begin{document}$\text{C}_6\text{D}_6$\end{document}

detectors on the Back-n white neutron facility of the China Spallation Neutron Source (CSNS), an experiment on

\begin{document}$^{209}$\end{document}

Bi

\begin{document}$(n, \gamma)$\end{document}

was performed. The data were processed using the time-of-flight (TOF) method and the pulse height weighting technique (PHWT). Due to the very small capture cross section of

\begin{document}$^{209}$\end{document}

Bi and the complex background, the experimental consequence showed strong statistical fluctuations, making it difficult to identify resonance structures. To address this, the average capture cross section was determined by optimizing the energy binning. The reasons for the obscured resonance structures resulted by the background were analyzed, and possible solutions were proposed. This study provides useful experience for measuring low cross section nuclides using the

\begin{document}$\text{C}_6\text{D}_6$\end{document}

detectors.

Mixed large field inflation emerging from a quantum bounce in loop quantum cosmology

Yerlan Myrzakulov

Published: , doi: 10.1088/1674-1137/ae5c84

Abstract:
We study the pre-inflationary evolution of the universe within the framework of loop quantum cosmology for a scalar field with potential

\begin{document}$ V(\phi)=M^{4}\frac{\phi^{2}}{M_{Pl}^{2}}\left(1+\alpha\frac{\phi^{2}}{M_{Pl}^{2}}\right) $\end{document}

, where α is a positive constant. In this framework, the classical initial singularity is resolved and replaced by a non-singular quantum bounce occurring at a critical energy density. Starting from the bounce, we analyze the background dynamics for both kinetic-energy-dominated and potential-energy-dominated initial conditions. Our results show that slow-roll inflation with a sufficient number of e-folds emerges generically over a wide range of initial inflaton values. We further examine the associated phase portrait and demonstrate the attractor behavior of the slow-roll inflationary solutions. Additionally, we study the spectral index

\begin{document}$ n_s $\end{document}

and the tensor-to-scalar ratio r for three limiting cases of α, finding that the model is observationally viable in the intermediate regime.

Measurement of differential and angle-integrated cross sections for the ¹⁰B(n, α)⁷Li reaction from 0.3 eV to 3.0 MeV at CSNS Back-n

Wenkai Ren, Han Yi, Haofan Bai, Jie Liu, Kang Sun, Wei Jiang, Zepeng Wu, Cong Xia, Guohui Zhang, Yonghao Chen, Ruirui Fan, Qiwen Fan, Shixiang Peng, Wentian Cao, Tieshuan Fan

Published: , doi: 10.1088/1674-1137/ae5dae

Abstract:
In the present work, new measurements of differential and angle-integrated cross sections for the ¹⁰B(n, α₁)⁷Li^*, ¹⁰B(n, α₀)⁷Li and ¹⁰B(n, α)⁷Li reactions were performed at CSNS Back-n white neutron source. The Light-charged Particle Detector Array (LPDA) system was used to detect the charged particles. The ⁶Li-Si monitor was employed to measure the neutron flux. The differential cross sections for the ¹⁰B(n, α)⁷Li reaction were obtained from 20.2^o to 158.7^o (13 angles) in the neutron energy region from 0.3 eV to 3.0 MeV (70 energy points). The differential cross sections for the ¹⁰B(n, α₀)⁷Li and ¹⁰B(n, α₁)⁷Li^* reactions were also obtained at the same angular positions in the neutron energy region from 0.3 eV to 1.0 MeV (65 energy points). Fitting with the Legendre polynomial series, the angle-integrated cross sections of these three reactions were obtained through integration. The experimental data for these three reactions across such a wide neutron energy range are valuable references for future nuclear data evaluations.

Prospects for discovering strongly decaying doubly heavy T_bc tetraquark states at LHCb

Mingjie Feng, Yiming Li, Hua-Sheng Shao

Published: , doi: 10.1088/1674-1137/ae5a87

Abstract:
We investigate the discovery potential of the

\begin{document}$T_{bc}$\end{document}

state with

\begin{document}$J^P = 0^+$\end{document}

in proton-proton (

\begin{document}$pp$\end{document}

) collisions at LHCb at a center-of-mass energy of

\begin{document}$\sqrt{s} = 13~{\rm{TeV}}$\end{document}

. The study focuses on the decay channel

\begin{document}$T_{bc} \to B^- D^+$\end{document}

. A phenomenological approach is employed to construct the background model based on the associated production of B and D mesons, incorporating previously published LHCb results. Background processes are simulated using

\begin{document}${\mathtt{MadGraph5\_aMC@NLO}}$\end{document}

and

\begin{document}${\mathtt{Pythia8.3}}$\end{document}

. We explore the parameter space of the

\begin{document}$T_{bc}$\end{document}

mass, width, production cross section, and the effective double-parton scattering cross section (

\begin{document}$\sigma_{{\rm{eff}}}$\end{document}

) relevant for the

\begin{document}$B D$\end{document}

meson background. The integrated luminosity required for a

\begin{document}$5\sigma$\end{document}

discovery at LHCb is evaluated under various assumptions. In particular, we consider three representative

\begin{document}$T_{bc}$\end{document}

production cross section scenarios: an optimistic estimate of

\begin{document}$103~{\rm{nb}}$\end{document}

, an intermediate value of

\begin{document}$18~{\rm{nb}}$\end{document}

obtained by scaling from the

\begin{document}$T_{cc}^+$\end{document}

production cross section, and a conservative lower bound of

\begin{document}$0.3~{\rm{nb}}$\end{document}

. We find that a

\begin{document}$5\sigma$\end{document}

observation is achievable for a production cross section of

\begin{document}$103~{\rm{nb}}$\end{document}

, which is expected to be within reach during Run~4. In contrast, the more realistic cross section estimate of

\begin{document}$18~{\rm{nb}}$\end{document}

requires the full Run~5 dataset (

\begin{document}$300~{\rm{fb}}^{-1}$\end{document}

) under the most favorable parameter choices. For the conservative scenario, no significant signal would be observable even with

\begin{document}$300~{\rm{fb}}^{-1}$\end{document}

. In addition, we estimate the minimum observable

\begin{document}$\sigma(T_{bc}) \times {\cal{B}}(T_{bc} \to B^- D^+)$\end{document}

for a

\begin{document}$5\sigma$\end{document}

discovery under different luminosity scenarios, providing guidance for future experimental searches at LHCb.

Systematic study of odd-even staggering in elemental fragmentation cross sections for N=Z nuclei from ³⁶Ar to ²⁸Si at ~ 300 MeV/nucleon

Yu-Nan Song, Yong Zheng, Guang-Shuai Li, Bao-Hua Sun, Jun Su, Ge Guo, Kai-Long Wang, Jun-Yao Xu, Xiao-Dong Xu, Ji-Chao Zhang, Meng Wang, Xiu-Lin Wei, Yong Cao, Bing-Shui Gao, Yun Qin, Lu-Ping Wan, Chang-Jian Wang, Xin-Xu Wang, Wen-Wen Zhang, Xiao-Bin Zhang, Zi-Cheng Zhou

Published: , doi: 10.1088/1674-1137/ae5d27

Abstract:
Elemental fragmentation cross sections (EFCSs) of the

\begin{document}$N=Z$\end{document}

nuclei

\begin{document}$^{36}$\end{document}

Ar,

\begin{document}$^{34}$\end{document}

Cl,

\begin{document}$^{32}$\end{document}

S,

\begin{document}$^{30}$\end{document}

P, and

\begin{document}$^{28}$\end{document}

Si on a carbon target were measured at approximately 300 MeV/nucleon using the RIBLL2 fragment separator at HIRFL. Among these, the cross sections for

\begin{document}$^{34}$\end{document}

Cl and

\begin{document}$^{30}$\end{document}

P are reported here for the first time, providing new data and extending EFCS measurements along the

\begin{document}$N=Z$\end{document}

chain. The measured cross sections exhibit significant odd-even staggering as a function of the charge change

\begin{document}$\Delta Z$\end{document}

. The experimental results are compared with several empirical parametrizations, including Cummings, EPAX3, and FRACS, as well as with the isospin-dependent quantum molecular dynamics model (IQMD) coupled to the statistical decay code GEMINI. The IQMD+GEMINI calculations reproduce the experimental cross sections with an accuracy of approximately 7% and reasonably reproduce the observed odd-even staggering. Consistent with previous studies, comparisons between model predictions at different reaction stages demonstrate that the odd-even staggering in EFCSs predominantly originates from the de-excitation of excited primary fragments. These results further establish the robustness of this interpretation by extending its validation to the

\begin{document}$N=Z$\end{document}

region.

Sensitivity study of $\bar{K}_1(1270)$ decay dynamics using four $D\to \bar{K}_1(1270)(\to \bar K\pi\pi)e^+\nu$ decay channels

Ying'ao Tang, Liang Sun, Panting Ge, Menghao Wang

Published: , doi: 10.1088/1674-1137/ae5c70

Abstract:
A sensitivity study of

\begin{document}$ \bar{K}_1(1270) $\end{document}

decay-mode measurements is performed using semileptonic D-meson decays. The BESIII experiment is used as a case study, in which a simultaneous analysis of

\begin{document}$ \bar{K}_1(1270) $\end{document}

decays to the four three-body final states

\begin{document}$ K^-\pi^+\pi^- $\end{document}

,

\begin{document}$ K^-\pi^+\pi^0 $\end{document}

,

\begin{document}$ K_S^0\pi^+\pi^- $\end{document}

, and

\begin{document}$ K_S^0\pi^-\pi^0 $\end{document}

is presented, and a model-independent determination of

\begin{document}$ {\cal{B}}(\bar{K}_1(1270)\to \bar K\pi\pi) $\end{document}

that does not require detailed knowledge of intermediate resonant contributions is proposed.

Revisiting critical orbits of test particles traveling in a black hole background

Ping Li, Jun Cheng, Jiang-he Yang

Published: , doi: 10.1088/1674-1137/ae5d29

Abstract:
This paper systematically revisits the critical orbits of test particles in various black hole backgrounds, including Schwarzschild, Reissner–Nordströom, Kerr, and Kerr–Newman spacetimes. We identify the critical orbits directly from the root structure of the radial equation, and we provide explicit expressions that relate the relevant parameters—energy, angular momentum, and charge-to-mass ratio—to the critical radius, as well as explicit formulas for the critical orbits in each case. Special attention is given to the relationships among the photon spheres, black hole shadows, and critical null geodesics. We also present extensive numerical results.

Relativistic corrections to hadron-hadron scattering phase shift and correlation function

Zeyu Zeng, Baoyi Chen, Jiaxing Zhao

Published: , doi: 10.1088/1674-1137/ae5884

Abstract:
Femtoscopy offers a sensitive probe of hadron emission sources and hadronic interactions. In this study, we examine relativistic corrections to scattering phase shifts and correlation functions using the two-body Dirac equation framework. We analyze the impact of the Darwin term and spin-dependent potentials, showing that these relativistic effects, especially spin-related interactions, significantly enhance the proton-proton correlation function. Our findings emphasize the necessity of including relativistic corrections for precise femtoscopic analyses.

Nonlinear diffusive shock acceleration with upstream escape reproduces DAMPE observations

Han-Xiang Hu, Xing-Jian Lv, Xiao-Jun Bi, Tian-Lu Chen, Kun Fang, Peng-Fei Yin

Published: , doi: 10.1088/1674-1137/ae5c7d

Abstract:
We develop a self-consistent nonlinear extension of diffusive shock acceleration that incorporates cosmic-ray (CR) backreaction on the shock precursor together with a physically motivated upstream escape mechanism that yields an exponential high-energy cutoff. The CR pressure gradient decelerates the upstream flow ahead of the shock, generating an extended precursor in which higher-rigidity particles sample a larger cumulative velocity gradient and thereby acquire a progressively harder spectrum. Finite-size and escape effects are modeled by a momentum-dependent loss term, which naturally terminates acceleration and steepens the spectrum near the cutoff. The precursor compression ratio is not imposed as a closure condition; instead, it is determined dynamically by enforcing consistency between the injection rate inferred from thermal leakage at the subshock and the injection strength required by the nonlinear shock modification, with CR-driven wave heating providing stabilizing negative feedback. Applying the model to young supernova-remnant–like parameters and standard one-zone Galactic diffusion, we reproduce the main features of the latest DAMPE proton spectrum: gradual hardening from hundreds of GeV to multi-TeV energies, followed by an exponential cutoff at tens of TeV. The resulting spectral evolution follows directly from the competition between precursor-mediated nonlinear feedback and upstream escape.

Structure of the β-Decay Strength Function

I.N. Izosimov

Published:

Abstract:
An analysis of experimental data on measurements of the resonant and fine structure of the β-decay strength function

\begin{document}$S_{\beta}(E)$\end{document}

in spherical, transitional, deformed, and halo nuclei has been conducted. Modern nuclear spectroscopy methods have revealed peak splitting in

\begin{document}$S_{\beta}(E)$\end{document}

for Gamow–Teller (GT) type β-transitions, caused by nuclear deformation. The resonant structure of

\begin{document}$S_{\beta}(E)$\end{document}

for first-forbidden (FF) β-transitions has been experimentally confirmed in both spherical and deformed nuclei. It is shown that at certain nuclear excitation energies, FF β-transitions can reach intensities comparable to those of GT β-transitions. An analysis of the evolution of the energy difference (

\begin{document}$E_{\text {GTR}}{-}E_{\text {IAR}})$\end{document}

between the Gamow–Teller resonance (GTR) and the isobaric analogue resonance (IAR) with increasing neutron excess in nuclei has been performed. A region exhibiting Wigner spin–isospin

\begin{document}$SU(4)$\end{document}

symmetry has been predicted.

Cosmological Perturbation in New General Relativity: Propagating mode from the violation of local Lorentz invariance

Kyosuke Tomonari, Taishi Katsuragawa, Shin'ichi Nojiri

Published: , doi: 10.1088/1674-1137/ae4dd8

Abstract:
We investigate the propagating modes of New General Relativity (NGR) in second-order linear perturbations in the Lagrangian density (first-order in field equations). The Dirac-Bergmann analysis has revealed a violation of local Lorentz invariance in NGR. We review the recent status of NGR, considering the results of its Dirac-Bergmann analysis. We then reconsider the vierbein perturbation framework and identify the origin of each perturbation field in the vierbein field components. This identification is mandatory for adequately fixing gauges while guaranteeing consistency with the invariance ensured by the Dirac-Bergmann analysis. We find that the spatially flat gauge is adequate for analyzing a theory with the violation of local Lorentz invariance. Based on the established vierbein perturbative framework, introducing a real scalar field as matter, we perform a second-order perturbative analysis of NGR with respect to tensor, scalar, pseudo-scalar, and vector and pseudo-vector modes. We reveal the possible propagating modes of each type of NGR. In particular, we find that Type 3 has stable five propagating modes, i.e., tensor, scalar, and vector modes, compared to five non-linear degrees of freedom, which results in its Dirac-Bergmann analysis; The linear perturbation theory of Type 3 is preferable for applications to cosmology. Finally, we discuss our results in comparison to previous related work and conclude this study.

Update analysis of $ \psi(3686)\to p\bar{p}$

Zhi Gao, Rong-Gang Ping, Minggang Zhao

Published: , doi: 10.1088/1674-1137/ae4a0c

Abstract:
We present an updated analysis of the angular distribution for

\begin{document}$ \psi(3686) \to p\bar{p} $\end{document}

decay, taking into account transverse beam polarization, to investigate potential sources of forward-backward asymmetry and azimuthal modulation beyond the simple

\begin{document}$ 1+\alpha\cos^2\theta $\end{document}

form. We focus on the interference between the

\begin{document}$ \psi(3686) $\end{document}

resonance and the two-photon exchange continuum process, as well as the background from initial-state–final-state radiation interference. A maximum-likelihood fit to the

\begin{document}$ \cos\theta $\end{document}

distribution of

\begin{document}$ \psi(3686)\to p\bar{p} $\end{document}

yields

\begin{document}$ \alpha = 1.00 \pm 0.03 $\end{document}

, consistent with previous results. The fitted contributions from the two-photon interference are small but non-negligible, while the ISR–FSR background is negligible. Our model predicts a significant

\begin{document}$ \sin(2\phi) $\end{document}

modulation in the azimuthal angle, indicating the influence of transverse beam polarization. These findings motivate future two-dimensional angular analyses to fully disentangle the polarization and interference dynamics in charmonium decays to baryon pairs.

NLO QCD sum rules analysis of 1⁻⁺ tetraquark states

Wei-Yang Lai, Hong-Ying Jin

Published:

Abstract:
We performed a next-to-leading-order (NLO) QCD sum rules analysis of the

\begin{document}$1^{-+}$\end{document}

light tetraquark states. By investigating various compact and molecular tetraquark currents, we extracted the mass spectra of the corresponding states, all of which lie above

\begin{document}$1.7\,\text{GeV}$\end{document}

. We find multiple

\begin{document}$1^{-+}$\end{document}

states around

\begin{document}$2.0\,\text{GeV}$\end{document}

that match well with

\begin{document}$\pi_{1}(2015)$\end{document}

, which makes us confident that

\begin{document}$\pi_{1}(2015)$\end{document}

is an excellent tetraquark candidate. In contrast, our calculations exclude the possibility that the

\begin{document}$\pi_{1}(1400)$\end{document}

is a tetraquark or hybrid-tetraquark mixture. This suggests that it may not exist, which is consistent with recent experimental results.

Quantum Gravitational Corrections to Reissner-Nordström Black Hole Thermodynamics and Their Implications for the Weak Gravity Conjecture

Yong Xiao, Qiang Wang, Aonan Zhang

Published: , doi: 10.1088/1674-1137/ae457a

Abstract:
In this paper, we investigate the quantum gravitational corrections to the thermodynamical quantities of Reissner-Nordstr?m black holes within the framework of effective field theory. The effective action originates from integrating out massless particles, including gravitons, at the one-loop level. We perform a complete thermodynamic analysis for both non-extremal and extremal black holes and are mainly concerned with the shift in the charge-to-mass ratio

\begin{document}$ q/M$\end{document}

, which plays an important role in analyzing the weak gravity conjecture. For non-extremal black holes, we identify a relationship between the shift in the charge-to-mass ratio and the thermodynamic stability of the black holes. For extremal black holes, we show that quantum gravity effects naturally lead to the super-extremality

\begin{document}$ q/M>1$\end{document}

of charged black holes.

Higgs Decays to Zγ and γγ in the Flavor-Gauged Two Higgs Doublet Model

Feng-Zhi Chen, Qiaoyi Wen, Fanrong Xu

Published:

Abstract:
This work examines the

\begin{document}$ h\to Z\gamma $\end{document}

and

\begin{document}$ h\to\gamma\gamma $\end{document}

decays in the flavor-gauged two Higgs doublet model (FG2HDM), which augments the Standard Model (SM) with an additional scalar doublet, a singlet, and a

\begin{document}$ U(1)' $\end{document}

flavor gauge symmetry. Beyond the SM spectrum, the FG2HDM predicts five additional physical scalars and a new neutral gauge boson,

\begin{document}$ Z' $\end{document}

. We demonstrate that while both decay channels are sensitive to charged Higgs loops,

\begin{document}$ h \to Z\gamma $\end{document}

is uniquely modified by fermion-antifermion-Z (

\begin{document}$ f\bar{f}Z $\end{document}

) vertex corrections. These vertex corrections further impact top-quark observables and the flavor-changing neutral current (FCNC) process

\begin{document}$ b\to s\ell^+\ell^- $\end{document}

. Our analysis identifies a viable parameter space (

\begin{document}$ m_{H^\pm}>200 $\end{document}

GeV and

\begin{document}$ \lambda_{hH^+H^-}<0 $\end{document}

) consistent with current

\begin{document}$ 1\sigma $\end{document}

experimental limits, where the signal strength

\begin{document}$ \mu_{\gamma\gamma} $\end{document}

remains the primary constraint on scalar sector parameters. Regarding the

\begin{document}$ f\bar{f}Z $\end{document}

couplings, we delineate the allowed regions in the

\begin{document}$ \mathcal{Q}_{tL} $\end{document}

-

\begin{document}$ \mathcal{Q}_{tR} $\end{document}

plane by evaluating the leading top-quark contributions, revealing that

\begin{document}$ b\to s\ell^+\ell^- $\end{document}

imposes the most stringent bounds. Finally, we highlight that the

\begin{document}$ 14\% $\end{document}

projected precision for

\begin{document}$ \mu_{Z\gamma} $\end{document}

at the High-Luminosity LHC (HL-LHC) will significantly enhance the sensitivity to the FG2HDM.

Negative potential-induced scalarization in the Einstein-Euler-Heisenberg black hole

Hong Guo, Miok Park, Yun Soo Myung

Published:

Abstract:
We investigate a negative potential-induced scalarization of the Einstein-Euler-Heisenberg (EEH) black hole in the EEH-scalar theory, characterized by mass M, Euler-Heisenberg parameter μ and magnetic charge q. In the regime

\begin{document}$ \mu>\mu_{{\rm{max}}} = 0.019 $\end{document}

(with

\begin{document}$ M=1/2 $\end{document}

), the black hole admits a single horizon and allows for overcharged configurations with

\begin{document}$ q/M \gt 1 $\end{document}

. We obtain a single branch of scalarized EEH (sEEH) black holes for

\begin{document}$ q>0 $\end{document}

which is considered as the simplest model for scalarization of EEH black holes. We find that this class of hairy black holes is not thermodynamically favored, and their quasinormal modes indicate they are dynamically unstable. An notable feature is that the scalar charge depends weakly on q for

\begin{document}$ q<1/2 $\end{document}

, but grows more rapidly for

\begin{document}$ q>1/2 $\end{document}

, suggesting a transition from primary- to secondary-type scalar charge. This finding reveals characteristic properties of hairy black holes in EEH theory, specifically in the overcharging regime.

Analytical Study of Fundamental Oscillation Frequencies Around Black Holes in Non-Local Gravity

Rana Muhammad Zulqarnain, Phongpichit Channuie, Abdelmalek Bouzenada, Asifa Ashraf, Farruh Atamurotov, Ikhtiyor Saidov

Published:

Abstract:
In this study, we investigate the dynamics of test particles in the spacetime of a static, spherically symmetric black hole (BH), illustrated within the non-local gravity models. In this case, after presenting the BH geometries and horizon structures, we examine the motion of particles by analyzing the effective potential, the innermost stable circular orbits (ISCOs), and the corresponding effective force. Also, we then extend the study to small perturbations of circular orbits, exploring harmonic oscillations characterized by the frequencies measured both by local observers and by distant ones, as well as the periastron precession effects. Particular attention is devoted to the interplay between the non-local gravity corrections and the stability properties of geodesics. In this case, we analyze the center-of-mass energy (CME) of colliding particles near the event horizon and show the influence of BH parameters on energy extraction processes. In this context, the results show how non-local modifications of gravity affect the standard predictions of BH structure, orbital stability, and high-energy particle dynamics, with possible implications for astrophysical observations and theoretical models of strong gravity. This study examines the differences between the inverse electrodynamics BH and the Schwarzschild BH configuration, showing how additional parameters influence the dynamics and stability of the test particles.

Exploring toroidal α-cluster configurations in ²⁸Si within the 7α cluster model

Su-Yu Zhou, Bo Zhou

Published: , doi: 10.1088/1674-1137/ae4578

Abstract:
Two

\begin{document}$ 7\alpha $\end{document}

cluster configurations in

\begin{document}$ ^{28}\mathrm{Si} $\end{document}

—a uniform toroidal configuration and a disk-like configuration—are investigated within the framework of the generator coordinate method (GCM) with Brink-Bloch 7α wave functions by taking the edge length as the generator coordinate. Within the framework of the 7α cluster model with imposed geometric symmetry, we observe that a uniform toroidal configuration may emerge at approximately 40 MeV above the 7α threshold. This provides a cluster-model perspective that complements some mean-field descriptions of toroidal structure in

\begin{document}$ ^{28}\mathrm{Si} $\end{document}

.

Determination of the Fission-Cycling Onset in the r-Process

Mei-Yue-Nan Ma, Zhi-Hong LI, Ge-Xing LI, Chao Dong, Na SONG, Chen CHEN, Jun-Wen TIAN, Jia-Ying-Hao LI, Zhi-Cheng ZHANG, Hui-Ling TIAN

Published: , doi: 10.1088/1674-1137/ae5ef5

Abstract:
Identifying the thermodynamic conditions marking the onset of fission cycling is crucial for modeling heavy-element production in the r-process. In this work, we develop a framework to determine this onset over the

\begin{document}$ (T_9, n_n) $\end{document}

plane. We define a heavy-region condition band near

\begin{document}$ N \approx 184 $\end{document}

and construct an equilibrium path band based on the effective neutron separation energy

\begin{document}$ S_n^{0}(T_9, n_n) $\end{document}

. We then compare the lifetimes of neutron-induced fission and β-decay for nuclei with

\begin{document}$ 94 \leqslant Z \leqslant 106 $\end{document}

. Within this framework, we construct a continuous map of actinide nuclei along the equilibrium path band, identifying where neutron-induced fission first overtakes β-decay. We find that, with increasing temperature and neutron density, the onset shifts toward nuclei with lower proton number (Z) and smaller mass number (A), transitioning from the Es-Cf region to the Am region. These results provide a quantitative benchmark for identifying the conditions under which fission cycling occurs in heavy r-process environments.

Testing a Linear Relation: Short-Range Correlations and the EMC Effect for Gluons and Quarks in Nuclei

Shu-Man Hu, Wei Wang, Ji Xu, Xing-Hua Yang, Shuai Zhao

Published: , doi: 10.1088/1674-1137/ae62f8

Abstract:
In this work, we focus on the possible linear relationship between short-range correlations (SRCs) and the EMC effect for partons in nuclei. First, we test a linear relationship pertaining to gluons in bound nuclei; it is manifested as a correlation between the slope of the reduced cross-section ratio in deep inelastic scattering (DIS) and the cross-section of sub-threshold

\begin{document}$ J/\psi $\end{document}

photoproduction. For comparison, results from four different global analysis groups of nuclear parton distribution functions (nPDFs) are utilized. These results show a good linear correlation between the gluons in bound nuclei and the slope of the reduced cross-section ratio, consistent with the possible presence of nuclear effects in the gluon distributions. Second, we investigate the linear relationship of quarks in the proton-induced Drell-Yan process. The corresponding results for quarks show strong sensitivity to the parameterization forms adopted by the different groups. These findings enhance our understanding of the substructure in bound nuclei and provide a valuable reference for future global fitting of nPDFs.

Design of LACT Detector Layout and Expectation for Gamma-ray Sources Observation

Wei Liu, Jiali Liu, Shoushan Zhang, Yun Zhang, Zhipeng Zhang, Ruizhi Yang, Yudong Wang, Zhen Min, Shaohui Feng, Lisi Geng, Zhen Cao

Published: , doi: 10.1088/1674-1137/ae5c6f

Abstract:
The Large Array of imaging atmospheric Cherenkov Telescopes (LACT) is a next-generation Cherenkov telescope array designed to study the morphology and energy spectra of ultra-high-energy gamma-ray sources in hybrid operation with the Large High Altitude Air Shower Observatory (LHAASO). With its excellent angular resolution, large effective area, and powerful gamma/hadron discrimination capabilities, LACT achieves outstanding sensitivity for observations of gamma-ray sources In this paper, we present an optimized configuration for the LACT array, developed through comprehensive Monte Carlo simulations. Based on these simulations, we conducted on-site surveys at the LHAASO site and selected the most effective array layout. Detailed performance studies show that this optimized configuration delivers excellent sensitivity across various observational modes. Furthermore, we present a detailed outlook on LACT's potential observations of gamma-ray sources in the LHAASO catalog. By incorporating the measured energy spectra from LHAASO and accounting for LACT's detector response function at different zenith angles, we estimate the number of detectable events over a one-year observation period. This analysis provides a foundation for developing a preliminary observation strategy for LACT in the coming years.

Observational Constraints on Dissipative Chaplygin Gas Cosmology in the Framework of Coincident f(Q) Gravity

Sayantan Ghosh, Raja Solanki, P.K. Sahoo

Published: , doi: 10.1088/1674-1137/ae50e5

Abstract:
In this current work, we shed light on the unified approach to both dark energy and dark matter via the generalized Chaplygin gas model in symmetric teleparallel gravity (STGR). We have employed the equation of state provided by the generalized Chaplygin gas, which naturally arises in string theory, tachyonic field theory, and Randall-Sundrum type brane world solutions. We show that such a generalized Chaplygin gas can not only provide a lucrative candidate for dark energy but also a viable candidate for dark matter via Bose-Einstein Condensation (BEC). We have also taken into account the interaction between dark matter and dark energy to provide a more realistic perspective. We performed MCMC analysis with combined Hubble and Pantheon data sets. We have also performed the Om diagnostics and the

\begin{document}$ r-s $\end{document}

plot to comment on the late behavior of our model. We have also found that through Om diagnostics, the values are in Phantom regions, and we have given physical reasons why this is expected. Finally, we outline some future directions for our work to be carried out.

Multinucleon transfer products in ⁴⁸Ca, ⁵⁴Cr +²⁴³ Am and ⁵⁴Cr +²³⁸ U reactions

G. Xie, Z. Y. Zhang, J. G. Wang, L. Ma, M. H. Huang, C. L. Yang, X. L. Wu, Z. G. Gan, H. B. Yang, M. M. Zhang, Y. L. Tian, Y. S. Wang, J. Y. Wang, Y. H. Qiang, L. Zhu, X. Y. Huang, S. Y. Xu, Z. Zhao, Z. C. Li, X. Zhang, H. Zhou, J. H. Zheng, L. C. Sun, F. Guan, W. X. Huang, Z. Qin, Y. Wang, X. J. Yin, Y. F. Cui, Y. He, L. T. Sun, Z. Z. Ren, S. G. Zhou, V. K. Utyonkov, A. A. Voinov, Yu. S. Tsyganov, A. N. Polyakov, D. I. Solovyev, D. Ibadullayev, M. V. Shumeiko

Published:

Abstract:
Experiments with the ⁴⁸Ca and ⁵⁴Cr induced reactions were performed at the gas-filled recoil separator SHANS2 (Spectrometer for Heavy Atoms and Nuclear Structure-2) of the China Accelerator Facility for superheavy Elements (CAFE2). The isotopic distributions of nuclei produced in the reactions ⁴⁸Ca +²⁴³ Am, ⁵⁴Cr +²⁴³ Am, and ⁵⁴Cr +²³⁸ U were investigated. Bombardments were conducted at the energies near the respective Coulomb barriers, with the SHANS2 magnetic rigidities set to collect fusion-evaporation residues. α-decay spectroscopy was employed to identify products, revealing 58 different isotopes in these experiments. The analysis indicates that the distribution of nuclides produced in different reactions exhibits clear systematic trends. Based on their mass distributions, these nuclei were attributed to the products from the quasi-fission (QF) process. In addition, several short-lived fission events were identified and attributed to the fission isomers near the target.

Bayesian Extraction of HQET Parameters from Inclusive Semi-Leptonic Decay of the Λ_c⁺ Baryon

Dong Xiao, Kangkang Shao

Published:

Abstract:
We extract the non-perturbative Heavy Quark Effective Theory (HQET) parameters from the inclusive semi-leptonic decay

\begin{document}$ \Lambda_c^+ \to X e^+ \nu_e $\end{document}

. Unlike charmed mesons produced near threshold,

\begin{document}$ \Lambda_c^+ $\end{document}

baryons produced in

\begin{document}$ e^+e^- $\end{document}

annihilation exhibit a complex momentum distribution, making the transformation of the electron energy spectrum from the laboratory frame to the

\begin{document}$ \Lambda_c^+ $\end{document}

rest-frame non-trivial. To address this, we develop a novel Bayesian inference method to reconstruct the electron energy moments in the

\begin{document}$ \Lambda_c^+ $\end{document}

rest-frame. By performing a global fit of theoretical predictions in the 1S mass scheme to these extracted moments, we determine the HQET parameters

\begin{document}$ \mu_\pi^2(\Lambda_c^+) $\end{document}

and

\begin{document}$ \rho_D^3(\Lambda_c^+) $\end{document}

for the first time using a purely data-driven approach.

The perturbation solutions to the Blandford-Znajek mechanism in the Kerr-Sen black hole

Haiyuan Feng, Ziqiang Cai, Rong-Jia Yang, Jinjun Zhang

Published:

Abstract:
We investigate the steady, axisymmetric, force-free magnetosphere of Kerr–Sen black hole (BH) within the framework of the Einstein–Maxwell–dilaton–axion (EMDA) theory. By perturbatively solving the nonlinear Grad–Shafranov (GS) equation, we determine the magnetic field configuration and quantify the influence of the dilaton parameter r₂ on the energy extraction rate and radiative efficiency. Our results show that both the energy extraction power and the radiative efficiency increase with r₂, exceeding those of the standard Kerr BH, whereas the extraction efficiency remain consistent with the Kerr case. In addition, we perform χ² statistical analysis using observational data from six binary BH systems, which indicates that the Kerr BH currently provides a better fit for bulk Lorentz factors Γ = 2 and 5.

The resonance effect for the CP asymmetry associated with the process ${\boldsymbol\omega{\bf\to}{\boldsymbol\pi}^+{\boldsymbol\pi}^-{\boldsymbol\pi}^{\bf 0} }$

Xi-Liang Yuan, Gang Lü, Na Wang, Chao Wang

Published: , doi: 10.1088/1674-1137/ad8ec2

Abstract:
The direct CP asymmetry in the weak decay process of hadrons is commonly attributed to the weak phase of the CKM matrix and the indeterminate strong phase. We propose a method to generate a significant phase difference through the interference between ρ and ω mesons, taking into account the G-parity allowed decay process of

\begin{document}$\omega \rightarrow \pi^{+}\pi^{-}\pi^{0}$\end{document}

and the G-parity-suppressed decay process of

\begin{document}$\rho^{0} \rightarrow \pi^{+}\pi^{-}\pi^{0}$\end{document}

in B meson decays. This interference can lead to notable changes in the CP asymmetry within the interference region. Additionally, we calculate the integral results for different phase space regions of the four-body decay process. We hope that our work provides valuable theoretical guidance for future experimental investigations on CP asymmetry in these decays.

Just Accepted