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Abstract:
In the framework of effective field theory, we derive the formula for the decay width of neutrinoless double beta-decay with the S-matrix theory, considering only the contribution from the exchange of light neutrinos. Our results agree with previous derivations for a Left-Right symmetric model. Detailed analyses of the nuclear matrix elements for 76Ge, 82Se, 130Te, and 136Xe from Quasi-particle Random Phase Approximation method with realistic force and large scale shell model calculations are performed. We compare the results between two many-body approaches and discuss possible origins of the deviation. We also compare our results with those from the so-called master formula, and find decent agreement between the two schemes. A deviation for the q-term in our scheme compared with the counterpart in the master formula can be accounted for as the distortion of the electron wave function under the static Coulomb field. We also provide constraints for the Low energy effective field theory Wilson coefficients\begin{document}$ C_{VL}^{(6)} $\end{document} ![]()
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\begin{document}$ C_{VR}^{(6)} $\end{document} ![]()
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In the framework of effective field theory, we derive the formula for the decay width of neutrinoless double beta-decay with the S-matrix theory, considering only the contribution from the exchange of light neutrinos. Our results agree with previous derivations for a Left-Right symmetric model. Detailed analyses of the nuclear matrix elements for 76Ge, 82Se, 130Te, and 136Xe from Quasi-particle Random Phase Approximation method with realistic force and large scale shell model calculations are performed. We compare the results between two many-body approaches and discuss possible origins of the deviation. We also compare our results with those from the so-called master formula, and find decent agreement between the two schemes. A deviation for the q-term in our scheme compared with the counterpart in the master formula can be accounted for as the distortion of the electron wave function under the static Coulomb field. We also provide constraints for the Low energy effective field theory Wilson coefficients
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, doi: 10.1088/1674-1137/ae167b
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The Royer law is a widely used empirical relation for calculating α-decay half-lives but requires 12 parity-dependent parameters. It exhibits systematic deviations near the\begin{document}$ N = 126 $\end{document} ![]()
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\begin{document}$ Z = 117-120 $\end{document} ![]()
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The Royer law is a widely used empirical relation for calculating α-decay half-lives but requires 12 parity-dependent parameters. It exhibits systematic deviations near the
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We perform the calculation of nuclear matrix elements for the neutrinoless double beta decays under a Left-Right symmetric model mediated by light neutrinos, and we adopt the spherical quasi-particle random-phase approximation (QRPA) approach with a realistic force. For eight nuclei: 76Ge, 82Se, 96Zr, 100Mo, 116Cd, 128Te, 130Te, and 136Xe, related nuclear matrix elements are given. We analyze each term, and the details of contributions from different parts are also provided. For the q term, we find that the weak-magnetism components of the nucleon current contribute equally to other components such as the axial-vector. We also discuss the influence of short-range correlations on these NMEs. It is found that the R term is more sensitive to short-range correlations than other terms due to the large portion of the contribution from high exchange momenta.
We perform the calculation of nuclear matrix elements for the neutrinoless double beta decays under a Left-Right symmetric model mediated by light neutrinos, and we adopt the spherical quasi-particle random-phase approximation (QRPA) approach with a realistic force. For eight nuclei: 76Ge, 82Se, 96Zr, 100Mo, 116Cd, 128Te, 130Te, and 136Xe, related nuclear matrix elements are given. We analyze each term, and the details of contributions from different parts are also provided. For the q term, we find that the weak-magnetism components of the nucleon current contribute equally to other components such as the axial-vector. We also discuss the influence of short-range correlations on these NMEs. It is found that the R term is more sensitive to short-range correlations than other terms due to the large portion of the contribution from high exchange momenta.
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By employing backward ray-tracing techniques, we investigate the shadow image of rotating black holes in Kalb-Ramond gravity. We consider two primary emission models: a spherical source and a thin accretion disk, with the latter assumed to be optically and geometrically thin. The results reveal that enhanced black hole rotation parameter a amplifies the shadow's departure from circular symmetry, whereas spontaneous Lorentz symmetry-breaking parameters\begin{document}${\cal{G}}$\end{document} ![]()
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\begin{document}$\theta_o$\end{document} ![]()
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\begin{document}${\cal{G}}$\end{document} ![]()
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\begin{document}$\theta_o$\end{document} ![]()
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\begin{document}${\cal{G}}$\end{document} ![]()
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\begin{document}$\theta_o$\end{document} ![]()
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By employing backward ray-tracing techniques, we investigate the shadow image of rotating black holes in Kalb-Ramond gravity. We consider two primary emission models: a spherical source and a thin accretion disk, with the latter assumed to be optically and geometrically thin. The results reveal that enhanced black hole rotation parameter a amplifies the shadow's departure from circular symmetry, whereas spontaneous Lorentz symmetry-breaking parameters
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The swirling-Kerr black hole is a novel solution of vacuum general relativity and has an extra swirling parameter characterizing the rotation of spacetime background. We have studied the gravitational waves generated by extreme mass ratio inspirals (EMRIs) along eccentric orbits on equatorial plane in this novel swirling spacetime. Our findings indicate that this swirling parameter leads to a delayed phase shift in the gravitational waveforms. Furthermore, we have investigated effects of the swirling parameter on the potential issue of waveform confusion caused by the orbital eccentricity and semi-latus rectum parameters. As the swirling parameter increases, the relative variations in the eccentricity increase, while the variations in the semi-latus rectum decrease rapidly. These trends of the changes related to the orbital eccentricity and the semi-latus rectum with the swirling parameter resemble those observed with the MOG parameter in the Scalar-Tensor-Vector-Gravity (STVG) theory, but with different rates of change. Furthermore, our results also reveal that effects of the background swirling parameter on the relative variations in the eccentricity and the semi-latus rectum are distinctly different from those of the black hole spin parameter. These results provide deeper insights into the properties of EMRI gravitational waves and the background's swirling.
The swirling-Kerr black hole is a novel solution of vacuum general relativity and has an extra swirling parameter characterizing the rotation of spacetime background. We have studied the gravitational waves generated by extreme mass ratio inspirals (EMRIs) along eccentric orbits on equatorial plane in this novel swirling spacetime. Our findings indicate that this swirling parameter leads to a delayed phase shift in the gravitational waveforms. Furthermore, we have investigated effects of the swirling parameter on the potential issue of waveform confusion caused by the orbital eccentricity and semi-latus rectum parameters. As the swirling parameter increases, the relative variations in the eccentricity increase, while the variations in the semi-latus rectum decrease rapidly. These trends of the changes related to the orbital eccentricity and the semi-latus rectum with the swirling parameter resemble those observed with the MOG parameter in the Scalar-Tensor-Vector-Gravity (STVG) theory, but with different rates of change. Furthermore, our results also reveal that effects of the background swirling parameter on the relative variations in the eccentricity and the semi-latus rectum are distinctly different from those of the black hole spin parameter. These results provide deeper insights into the properties of EMRI gravitational waves and the background's swirling.
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Understanding nuclear shape, behavior, and stability, as well as improving nuclear models, depends on the precise determination of ground-state nuclear charge radii. Existing experimental techniques are limited to very narrow regions of the nuclear chart; however, theoretical models, including relativistic Hartree-Bogoliubov (RHB) and Hartree-Fock-Bogoliubov (HFB), predict broad trends of nuclear properties but miss fine isotopic features such as odd-even staggering effects and shell-closure kinks. High computational time and cost are another obstacle to theoretical approaches. Although machine-learning algorithms have made significant progress in predicting charge radii, they are still hindered by a lack of balanced data and characteristics, primarily centered around\begin{document}$ A\ge40 $\end{document} ![]()
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\begin{document}$ Z\ge20 $\end{document} ![]()
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\begin{document}$ A\ge17 $\end{document} ![]()
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\begin{document}$ Z\ge8 $\end{document} ![]()
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\begin{document}$ N=50 $\end{document} ![]()
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Understanding nuclear shape, behavior, and stability, as well as improving nuclear models, depends on the precise determination of ground-state nuclear charge radii. Existing experimental techniques are limited to very narrow regions of the nuclear chart; however, theoretical models, including relativistic Hartree-Bogoliubov (RHB) and Hartree-Fock-Bogoliubov (HFB), predict broad trends of nuclear properties but miss fine isotopic features such as odd-even staggering effects and shell-closure kinks. High computational time and cost are another obstacle to theoretical approaches. Although machine-learning algorithms have made significant progress in predicting charge radii, they are still hindered by a lack of balanced data and characteristics, primarily centered around
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In this work, we investigate the resonance structures in the\begin{document}$ \Sigma(1/2^-) $\end{document} ![]()
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\begin{document}$ \Sigma(1/2^-) $\end{document} ![]()
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\begin{document}$ \Sigma(1750) $\end{document} ![]()
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\begin{document}$ \Sigma(1900) $\end{document} ![]()
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\begin{document}$ \Sigma \pi $\end{document} ![]()
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\begin{document}$ N \bar{K} $\end{document} ![]()
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\begin{document}$ N \bar{K}^{*} $\end{document} ![]()
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\begin{document}$ \Sigma(1/2^-) $\end{document} ![]()
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\begin{document}$ \Sigma \pi $\end{document} ![]()
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\begin{document}$ N \bar{K} $\end{document} ![]()
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\begin{document}$ \Lambda(1380) $\end{document} ![]()
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\begin{document}$ \Lambda(1405) $\end{document} ![]()
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\begin{document}$ \Sigma \pi $\end{document} ![]()
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\begin{document}$ N \bar{K} $\end{document} ![]()
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\begin{document}$ N \bar{K}^{*} $\end{document} ![]()
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\begin{document}$ \Sigma(1750) $\end{document} ![]()
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\begin{document}$ \Sigma(1900) $\end{document} ![]()
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\begin{document}$ N \bar{K}^{*} $\end{document} ![]()
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\begin{document}$ \Sigma(1750) $\end{document} ![]()
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\begin{document}$ \Sigma(1900) $\end{document} ![]()
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\begin{document}$ \Sigma \pi $\end{document} ![]()
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\begin{document}$ N \bar{K} $\end{document} ![]()
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\begin{document}$ \Lambda \pi $\end{document} ![]()
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\begin{document}$ \Sigma(1/2^-) $\end{document} ![]()
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\begin{document}$ \Lambda \pi $\end{document} ![]()
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In this work, we investigate the resonance structures in the
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Chiral effective theory has become a powerful tool for studying the low-energy properties of QCD. In this work, we apply an extended chiral effective theory—chiral-scale effective theory—including a dilatonic scalar meson to study nuclear matter and find that the properties around saturation density can be well reproduced. Compared to Walecka-type models in nuclear matter studies, our approach improves the behavior of symmetry energy in describing empirical data without introducing additional isovector scalar meson δ to make it soft at intermediate densities. Moreover, the predicted neutron star mass-radius relations fall within the constraints of GW170817, PSR J0740+6620, and PSR J0030+0451, while the maximum mass of neutron star mass can reach\begin{document}$\gtrsim 2.5M_{\odot}$\end{document} ![]()
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Chiral effective theory has become a powerful tool for studying the low-energy properties of QCD. In this work, we apply an extended chiral effective theory—chiral-scale effective theory—including a dilatonic scalar meson to study nuclear matter and find that the properties around saturation density can be well reproduced. Compared to Walecka-type models in nuclear matter studies, our approach improves the behavior of symmetry energy in describing empirical data without introducing additional isovector scalar meson δ to make it soft at intermediate densities. Moreover, the predicted neutron star mass-radius relations fall within the constraints of GW170817, PSR J0740+6620, and PSR J0030+0451, while the maximum mass of neutron star mass can reach
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, doi: 10.1088/1674-1137/ae1444
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This study made a statistical analysis on the correlation and uncertainty of parameters in the classical liquid drop mass formula (namely BW3 type) via the regression way, along with the theoretical impact of error propagation. Within the improved BW3 formula, the total deviation between evaluation and experiment can be reduced to 1.66 MeV, involving the reduction from 2.89 (2.42) MeV to 1.92 (1.89) MeV in the proton(neutron)-dripline region. The ridge regression validation verified this total deviation as the optimal point in the present mass model. Through trend coefficients and Pearson linear-correlation analysis, obvious collinearity was identified between volume, surface, Coulomb and curvature terms, with notable correlation among high-order symmetry energy and surface symmetry terms. The theoretical derivation of the distribution in the binding energy error was then achieved through error propagation analysis. Across the nuclide chart, the error uncertainty of mass predictions varies from 1.996 keV to 124.469 keV, demonstrating a convex trend of the initial decrease of evaluation error following by the increasing versus the neutron number.
This study made a statistical analysis on the correlation and uncertainty of parameters in the classical liquid drop mass formula (namely BW3 type) via the regression way, along with the theoretical impact of error propagation. Within the improved BW3 formula, the total deviation between evaluation and experiment can be reduced to 1.66 MeV, involving the reduction from 2.89 (2.42) MeV to 1.92 (1.89) MeV in the proton(neutron)-dripline region. The ridge regression validation verified this total deviation as the optimal point in the present mass model. Through trend coefficients and Pearson linear-correlation analysis, obvious collinearity was identified between volume, surface, Coulomb and curvature terms, with notable correlation among high-order symmetry energy and surface symmetry terms. The theoretical derivation of the distribution in the binding energy error was then achieved through error propagation analysis. Across the nuclide chart, the error uncertainty of mass predictions varies from 1.996 keV to 124.469 keV, demonstrating a convex trend of the initial decrease of evaluation error following by the increasing versus the neutron number.
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, doi: 10.1088/1674-1137/ae167d
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The cross section for the\begin{document}$ J^{\pi}(T)=3^{+}(0) $\end{document} ![]()
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\begin{document}$ ^{6} $\end{document} ![]()
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\begin{document}$ ^{6} $\end{document} ![]()
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\begin{document}$ T=0 $\end{document} ![]()
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\begin{document}$ J^{\pi}(T)=0^{+}(1) $\end{document} ![]()
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\begin{document}$ T=1 $\end{document} ![]()
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\begin{document}$ ^{6} $\end{document} ![]()
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The cross section for the
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, doi: 10.1088/1674-1137/ae120b
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Recently, the BESIII Collaboration has observed the three-body decays\begin{document}$ D_s^+\to \eta \omega\pi^+ $\end{document} ![]()
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\begin{document}$ D^+\to K^0_S\pi^+\omega $\end{document} ![]()
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\begin{document}$ D^0\to K^-\pi^+\omega $\end{document} ![]()
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\begin{document}$ \rho^+\to \omega\pi^+ $\end{document} ![]()
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\begin{document}$ D \to h\omega\pi $\end{document} ![]()
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\begin{document}$ \rho^+= \{\rho(770)^+, \rho(1450)^+, \rho(770)^+\&\rho(1450)^+\} $\end{document} ![]()
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\begin{document}$ h=\{ \eta, K^0_S, K^-\} $\end{document} ![]()
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\begin{document}$ F_{\omega\pi} $\end{document} ![]()
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\begin{document}$ e^+e^- $\end{document} ![]()
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\begin{document}$ D_s^+\to\eta[\rho^+\to]\omega\pi^+ $\end{document} ![]()
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\begin{document}$ D^+\to K^0_S[\rho^+\to]\omega\pi^+ $\end{document} ![]()
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\begin{document}$ D^0\to K^-[\rho^+\to]\omega\pi^+ $\end{document} ![]()
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\begin{document}$ \rho(770)^+\to\omega\pi^+ $\end{document} ![]()
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\begin{document}$ D_s^+\to\eta \omega\pi^+ $\end{document} ![]()
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\begin{document}$ D^+\to K^0_S \omega\pi^+ $\end{document} ![]()
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\begin{document}$ D^0\to K^- \omega\pi^+ $\end{document} ![]()
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\begin{document}$ \rho(770)^+ $\end{document} ![]()
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\begin{document}$ D_s^+\to\eta \omega\pi^+ $\end{document} ![]()
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\begin{document}$ D^+\to K^0_S \omega\pi^+ $\end{document} ![]()
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\begin{document}$ \rho(770)^+ $\end{document} ![]()
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\begin{document}$ \rho(1450)^+ $\end{document} ![]()
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Recently, the BESIII Collaboration has observed the three-body decays
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Symmetry studies represent one of the most promising frontiers in particle physics research. This investigation focuses on exploring P and\begin{document}$ CP $\end{document} ![]()
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\begin{document}$ \Xi_c^{+} $\end{document} ![]()
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\begin{document}$ \Xi_c^{+} $\end{document} ![]()
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\begin{document}$ \Xi_c^{+} \to \Xi^{-}\pi^{+}\pi^{+} $\end{document} ![]()
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Symmetry studies represent one of the most promising frontiers in particle physics research. This investigation focuses on exploring P and
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We investigate the physical properties of quark stars within the framework of\begin{document}$f(R,L_{m},T)$\end{document} ![]()
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We investigate the physical properties of quark stars within the framework of
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, doi: 10.1088/1674-1137/ae1183
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The root mean square (rms) nuclear proton radii of 6,7,8Li and 10,11B projectiles are systematically investigated through the analyses of elastic scattering data from target nuclei with mass numbers ranging from 40 to 209 at incident energies above the Coulomb barriers. The analyses employs a consistent single-folding model potential based on the Bruyères Jeukenne-Lejeune-Mahaux (JLMB) nucleon-nucleus interaction model, incorporating 112 sets of elastic scattering data to derive the projectile nuclear radii. This approach yields individual radii for each set, from which the mean rms proton radius is extracted as a characteristic parameter for the projectile nuclei. The rms proton radii of 6,7Li and 10,11B nuclei obtained from optical model fits demonstrate good agreement with both experimental measurements and existing theoretical predictions. Notably, a significantly smaller nuclear radius of 8Li is observed compared to values derived from intermediate-energy proton elastic scattering cross-section measurements, which may be attributed to additional dynamical effects specific to the 8Li projectile.
The root mean square (rms) nuclear proton radii of 6,7,8Li and 10,11B projectiles are systematically investigated through the analyses of elastic scattering data from target nuclei with mass numbers ranging from 40 to 209 at incident energies above the Coulomb barriers. The analyses employs a consistent single-folding model potential based on the Bruyères Jeukenne-Lejeune-Mahaux (JLMB) nucleon-nucleus interaction model, incorporating 112 sets of elastic scattering data to derive the projectile nuclear radii. This approach yields individual radii for each set, from which the mean rms proton radius is extracted as a characteristic parameter for the projectile nuclei. The rms proton radii of 6,7Li and 10,11B nuclei obtained from optical model fits demonstrate good agreement with both experimental measurements and existing theoretical predictions. Notably, a significantly smaller nuclear radius of 8Li is observed compared to values derived from intermediate-energy proton elastic scattering cross-section measurements, which may be attributed to additional dynamical effects specific to the 8Li projectile.
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, doi: 10.1088/1674-1137/ae1195
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In this work, we investigate possible bound states in the\begin{document}$ D_s\bar{D}_s $\end{document} ![]()
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\begin{document}$ J/\psi $\end{document} ![]()
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\begin{document}$ D_s\bar{D}_s $\end{document} ![]()
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\begin{document}$ D\bar{D} $\end{document} ![]()
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\begin{document}$ \eta_c\eta $\end{document} ![]()
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\begin{document}$ J/\psi\omega $\end{document} ![]()
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\begin{document}$ D_s\bar{D}_s $\end{document} ![]()
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\begin{document}$ D\bar{D} $\end{document} ![]()
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In this work, we investigate possible bound states in the
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, doi: 10.1088/1674-1137/ae1189
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We consider the three-dimensional rotating motions of neutron stars blown by the “axion wind”. Neutron star precession and spin can change from the magnetic moment coupling to the oscillating axion background field, in analogy to the gyroscope motions with a driving force and the laboratory Nuclear Magnetic Resonance (NMR) detections of the axion. This effect modulates the pulse arrival time of pulsar timing arrays through changes in the pulsars' periods. It appears as a signal in the timing residual and two-point correlation function of recent Nanograv and PPTA data. The current measurement of PTAs can thus cast constraints on the axion-nucleon coupling as\begin{document}$ g_\text{ann} \sim 10^{-12}\text{GeV}^{-1} $\end{document} ![]()
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\begin{document}$ 10^{-23} $\end{document} ![]()
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\begin{document}$ \mathrm{eV} $\end{document} ![]()
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We consider the three-dimensional rotating motions of neutron stars blown by the “axion wind”. Neutron star precession and spin can change from the magnetic moment coupling to the oscillating axion background field, in analogy to the gyroscope motions with a driving force and the laboratory Nuclear Magnetic Resonance (NMR) detections of the axion. This effect modulates the pulse arrival time of pulsar timing arrays through changes in the pulsars' periods. It appears as a signal in the timing residual and two-point correlation function of recent Nanograv and PPTA data. The current measurement of PTAs can thus cast constraints on the axion-nucleon coupling as
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Mirror symmetry is combined with the radial basis function (RBF) approach to improve the prediction accuracy of proton separation energy. Compared with the traditional RBF approach, the RBF approach combine with mirror symmetry (RBFms) mainly involves training the residual of the one/two-proton separation energy deviation of the nucleus and the one/two-neutron separation energy deviation of its mirror nucleus. The KTUY model combined with the RBFms approach yields an root-mean-square (rms) deviation of 0.113 MeV for one-proton separation energies of 143 nuclei, while the DZ31 model combined with the RBFms approach achieves rms deviation of 0.089 MeV for two-proton separation energies of 115 nuclei. In the region where the proton number\begin{document}$ Z=14-38 $\end{document} ![]()
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Mirror symmetry is combined with the radial basis function (RBF) approach to improve the prediction accuracy of proton separation energy. Compared with the traditional RBF approach, the RBF approach combine with mirror symmetry (RBFms) mainly involves training the residual of the one/two-proton separation energy deviation of the nucleus and the one/two-neutron separation energy deviation of its mirror nucleus. The KTUY model combined with the RBFms approach yields an root-mean-square (rms) deviation of 0.113 MeV for one-proton separation energies of 143 nuclei, while the DZ31 model combined with the RBFms approach achieves rms deviation of 0.089 MeV for two-proton separation energies of 115 nuclei. In the region where the proton number
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We construct a formalism which describes the resonances decaying into four pseudoscalar meson final states. This method is fully covariant and can be directly applied for the partial-wave analysis of high statistical data. Two topologies of the process are considered: two intermediate resonances each decaying into two final mesons and cascade decay via three meson intermediate states. In particular, we consider the production of such states in the central collision reactions and in radiative\begin{document}$J/\Psi$\end{document} ![]()
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We construct a formalism which describes the resonances decaying into four pseudoscalar meson final states. This method is fully covariant and can be directly applied for the partial-wave analysis of high statistical data. Two topologies of the process are considered: two intermediate resonances each decaying into two final mesons and cascade decay via three meson intermediate states. In particular, we consider the production of such states in the central collision reactions and in radiative
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We present a systematic study of the elliptic flow\begin{document}$ v_2 $\end{document} ![]()
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\begin{document}$ \sqrt{s_{NN}} = 7.7 $\end{document} ![]()
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\begin{document}$ v_{2}^{\text{PP}} $\end{document} ![]()
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\begin{document}$ v_{2}^{\text{RP}} $\end{document} ![]()
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\begin{document}$ \sqrt{s_{NN}} \approx 62.4 $\end{document} ![]()
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We present a systematic study of the elliptic flow
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We research dynamic shadows of a black hole with a self-interacting massive complex scalar hair. The complex scalar field\begin{document}$\psi$\end{document} ![]()
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\begin{document}$|\psi_{h}|$\end{document} ![]()
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\begin{document}$r_{ps}$\end{document} ![]()
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\begin{document}$|\psi_{h}|$\end{document} ![]()
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\begin{document}$\psi$\end{document} ![]()
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\begin{document}$r_{h}$\end{document} ![]()
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\begin{document}$R_{sh}$\end{document} ![]()
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\begin{document}$t_{o}$\end{document} ![]()
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\begin{document}$t_{o}$\end{document} ![]()
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\begin{document}$t$\end{document} ![]()
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\begin{document}$R_{sh}$\end{document} ![]()
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\begin{document}$r_{h}$\end{document} ![]()
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\begin{document}$R_{sh}$\end{document} ![]()
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\begin{document}$r_{ps}$\end{document} ![]()
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\begin{document}$r_{ps}$\end{document} ![]()
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\begin{document}$\psi$\end{document} ![]()
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\begin{document}$\psi$\end{document} ![]()
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\begin{document}$\psi$\end{document} ![]()
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\begin{document}$R_{sh}$\end{document} ![]()
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\begin{document}$\Delta t$\end{document} ![]()
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We research dynamic shadows of a black hole with a self-interacting massive complex scalar hair. The complex scalar field
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Probing the nature of dark matter (DM) remains an outstanding problem in modern cosmology. The 21 cm signal, as a sensitive tracer of neutral hydrogen during cosmic dawn, provides a unique means to investigate DM nature during this critical epoch. Annihilation and decay of DM particles, as well as Hawking radiation of primordial black holes (PBHs), can modify the thermal and ionization histories of the early universe, leaving distinctive imprints on the 21 cm power spectrum. Therefore, the redshifted 21 cm power spectrum serves as a powerful tool to investigate such DM processes. In this work, we systematically assess the potential of the upcoming Square Kilometre Array (SKA) to constrain DM and PBH parameters using the 21 cm power spectrum. Assuming 10,000 hours of integration time, the SKA is projected to reach sensitivities of\begin{document}$ \langle\sigma v\rangle \leq 10^{-28}\,{{\rm{cm}}}^{3}\,{{\rm{s}}}^{-1} $\end{document} ![]()
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\begin{document}$ \tau\geq 10^{28}\,{{\rm{seconds}}} $\end{document} ![]()
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\begin{document}$ 10 {{\rm{GeV}}} $\end{document} ![]()
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\begin{document}$ 10^{16}\,{{\rm{g}}} $\end{document} ![]()
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\begin{document}$ f_{{{\rm{PBH}}}} \leq 10^{-6} $\end{document} ![]()
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\begin{document}$ 10^{17}\,{{\rm{g}}} $\end{document} ![]()
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Probing the nature of dark matter (DM) remains an outstanding problem in modern cosmology. The 21 cm signal, as a sensitive tracer of neutral hydrogen during cosmic dawn, provides a unique means to investigate DM nature during this critical epoch. Annihilation and decay of DM particles, as well as Hawking radiation of primordial black holes (PBHs), can modify the thermal and ionization histories of the early universe, leaving distinctive imprints on the 21 cm power spectrum. Therefore, the redshifted 21 cm power spectrum serves as a powerful tool to investigate such DM processes. In this work, we systematically assess the potential of the upcoming Square Kilometre Array (SKA) to constrain DM and PBH parameters using the 21 cm power spectrum. Assuming 10,000 hours of integration time, the SKA is projected to reach sensitivities of
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Recent studies have shown that observing entangled particle states at a particle collider like Large Hadron Collider (LHC) and testing violation of Bell inequality in them can open up new research area for high energy physics study. We examine the presence of quantum entanglement in the\begin{document}$ pp\to ZZ\to 4\ell $\end{document} ![]()
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\begin{document}$ \sigma $\end{document} ![]()
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\begin{document}$ \sigma $\end{document} ![]()
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Recent studies have shown that observing entangled particle states at a particle collider like Large Hadron Collider (LHC) and testing violation of Bell inequality in them can open up new research area for high energy physics study. We examine the presence of quantum entanglement in the
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In this work we study the isospin-violating decays of\begin{document}$ B_{c}(1P)^{+}\to B_{c}^{(*)+}\pi^{0} $\end{document} ![]()
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\begin{document}$ B_{c}(1P)^{+} $\end{document} ![]()
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\begin{document}$ B_{c}(1P)^{+}\to B_{c}^{(*)+}\pi^{0} $\end{document} ![]()
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\begin{document}$ B_{c0}^{*+}\to B_{c}^{+}\pi^{0} $\end{document} ![]()
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\begin{document}$ B_{c2}^{*+}\to B_{c}^{+}\pi^{0} $\end{document} ![]()
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\begin{document}$ B_{c0}^{*+} $\end{document} ![]()
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\begin{document}$ B_{c}^{+}\pi^{0} $\end{document} ![]()
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\begin{document}$ B_{c1}^{+}/B_{c1}'^{+} $\end{document} ![]()
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\begin{document}$ B_{c1}^{+}/B_{c1}'^{+}\to B_{c}^{*+}\pi^{0} $\end{document} ![]()
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In this work we study the isospin-violating decays of
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In 2022, the CDF Collaboration reported the W-boson mass,\begin{document}$ M_W=80.4335\pm0.0094\; \text{GeV} $\end{document} ![]()
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\begin{document}$ M_W^{\rm SM}=80.357\pm0.006\; \text{GeV} $\end{document} ![]()
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\begin{document}$ 7\sigma $\end{document} ![]()
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\begin{document}$ M_W=80.3602\pm0.0099\; \text{GeV} $\end{document} ![]()
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\begin{document}$ \sim80.357\; \text{GeV} $\end{document} ![]()
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\begin{document}$ (S,T,U) $\end{document} ![]()
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\begin{document}$ H^\pm $\end{document} ![]()
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\begin{document}$ h_1 $\end{document} ![]()
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\begin{document}$ m_{h_1}\simeq125 $\end{document} ![]()
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\begin{document}$ |\cos(\beta-\alpha)|\lesssim0.06 $\end{document} ![]()
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\begin{document}$ 17\lesssim\tan\beta\lesssim39 $\end{document} ![]()
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\begin{document}$ 144\lesssim m_{h_2}\lesssim414 $\end{document} ![]()
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\begin{document}$ 435\lesssim m_{A,H^{\pm}}\lesssim685 $\end{document} ![]()
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\begin{document}$ 3\sigma $\end{document} ![]()
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\begin{document}$ M_W=80.4335\pm0.0094\; \text{GeV} $\end{document} ![]()
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\begin{document}$ \lesssim2\sigma $\end{document} ![]()
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\begin{document}$ (S,T,U) $\end{document} ![]()
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\begin{document}$ W- $\end{document} ![]()
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\begin{document}$ 2\sigma $\end{document} ![]()
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In 2022, the CDF Collaboration reported the W-boson mass,
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The Schrödinger equation with Woods-Saxon type potentials is solved by the Green's function (GF) method. Taking the nucleus\begin{document}$^{40}\mathrm{Ca}$\end{document} ![]()
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The Schrödinger equation with Woods-Saxon type potentials is solved by the Green's function (GF) method. Taking the nucleus
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An SU(3) flavor projection operator technique is implemented to construct the baryon-meson scattering amplitude in the framework of the\begin{document}$1/N_c$\end{document} ![]()
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\begin{document}$N_c$\end{document} ![]()
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\begin{document}${\cal{O}}(1/N_c^2)$\end{document} ![]()
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\begin{document}$N\pi\to N\pi$\end{document} ![]()
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An SU(3) flavor projection operator technique is implemented to construct the baryon-meson scattering amplitude in the framework of the
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We address a specific issue of the Newman-Janis algorithm: How to determine the general form of the complex transformation for the Schwarzschild metric and ensure that the resulting axisymmetric metric satisfies the zero-scalar-curvature condition,\begin{document}$ R=0 $\end{document} ![]()
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We address a specific issue of the Newman-Janis algorithm: How to determine the general form of the complex transformation for the Schwarzschild metric and ensure that the resulting axisymmetric metric satisfies the zero-scalar-curvature condition,
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Based on\begin{document}$ (10087\pm 44)\times10^{6} $\end{document} ![]()
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\begin{document}$ J/\psi $\end{document} ![]()
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\begin{document}$ J/\psi \to K^+K^+e^-e^- + c.c. $\end{document} ![]()
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\begin{document}$ 2.1 \times 10^{-9} $\end{document} ![]()
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\begin{document}$ J/\psi $\end{document} ![]()
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Based on
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Electroweak (EW) amplitudes in the gauge-Goldstone 5-component formalism have a distinctive property: gauge symmetry is imprinted in the amplitudes, manifested as the massive Ward identity (MWI)\begin{document}$ k^M{\cal{M}}_M=0 $\end{document} ![]()
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Electroweak (EW) amplitudes in the gauge-Goldstone 5-component formalism have a distinctive property: gauge symmetry is imprinted in the amplitudes, manifested as the massive Ward identity (MWI)
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Determining the spatial curvature of the Universe, a fundamental parameter defining the global geometry of spacetime, remains crucial yet contentious due to existing observational tensions. Although Planck satellite measurements have provided precise constraints on spatial curvature, discrepancies persist regarding whether the Universe is flat or closed. Here, we introduce a model-independent approach leveraging deep learning techniques, specifically residual neural networks (ResNet), to reconstruct the dimensionless Hubble parameter E(z) and the normalized comoving distance D(z) from H(z) data and multiple SNe Ia compilations. Our dual-block ResNet architecture, which integrates a model-driven block informed by\begin{document}$ \Lambda $\end{document} ![]()
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\begin{document}$ {\cal{O}}_k(z) $\end{document} ![]()
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\begin{document}$ \sigma $\end{document} ![]()
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Determining the spatial curvature of the Universe, a fundamental parameter defining the global geometry of spacetime, remains crucial yet contentious due to existing observational tensions. Although Planck satellite measurements have provided precise constraints on spatial curvature, discrepancies persist regarding whether the Universe is flat or closed. Here, we introduce a model-independent approach leveraging deep learning techniques, specifically residual neural networks (ResNet), to reconstruct the dimensionless Hubble parameter E(z) and the normalized comoving distance D(z) from H(z) data and multiple SNe Ia compilations. Our dual-block ResNet architecture, which integrates a model-driven block informed by
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The properties of neutrons from spectator sources produced in 107,124Sn + 120Sn collisions at 600 MeV/nucleon are studied. The isospin-dependent quantum molecular dynamics (IQMD) model is used to describe the dynamical process of the fragmentation, and the statistical model GEMINI is applied to simulate the secondly decay of the pre-fragments. The differential cross section and multiplicity of the neutrons emitted from the spectator source are used to prove the feasibility of the model. The temperatures of the spectator source are extracted by two-source-fitting the transverse momentum distributions of the neutrons using the classical Maxwellian functions. The temperatures of the spectator sources extracted from calculations are consistent with the experimental data, those from the SMM model, and the isotopic temperature\begin{document}$ T_{\text{HeLi}} $\end{document} ![]()
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The properties of neutrons from spectator sources produced in 107,124Sn + 120Sn collisions at 600 MeV/nucleon are studied. The isospin-dependent quantum molecular dynamics (IQMD) model is used to describe the dynamical process of the fragmentation, and the statistical model GEMINI is applied to simulate the secondly decay of the pre-fragments. The differential cross section and multiplicity of the neutrons emitted from the spectator source are used to prove the feasibility of the model. The temperatures of the spectator source are extracted by two-source-fitting the transverse momentum distributions of the neutrons using the classical Maxwellian functions. The temperatures of the spectator sources extracted from calculations are consistent with the experimental data, those from the SMM model, and the isotopic temperature
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, doi: 10.1088/1674-1137/ae07b8
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The tilted-axis-cranking covariant density functional theory is applied to investigate the three newly-observed positive-parity bands SI, SII, and SIII in 69Ga. The energy spectra and angular momenta are calculated and good agreements with the experimental data are realized. For the band SI, pairing correlations play a crucial role for the states with spin\begin{document}$I\leq 23/2\hbar$\end{document} ![]()
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\begin{document}$g_{9/2}$\end{document} ![]()
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\begin{document}$B(E2)$\end{document} ![]()
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The tilted-axis-cranking covariant density functional theory is applied to investigate the three newly-observed positive-parity bands SI, SII, and SIII in 69Ga. The energy spectra and angular momenta are calculated and good agreements with the experimental data are realized. For the band SI, pairing correlations play a crucial role for the states with spin
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, doi: 10.1088/1674-1137/ae0995
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High moments of conserved quantities such as net-baryon, net-electric charge, and net-strangeness in heavy-ion collisions are sensitive to fluctuations caused by the QCD critical point (CP). The event-by-event analysis of high moments of the conserved charges has been widely used in experiments to search for the CP, especially in the RHIC-STAR experiment. In order to establish a dynamical non-critical base line, especially at the high baryon density region, we have performed a systematic analysis of the proton multiplicity distributions from Au+Au collisions at\begin{document}$ 3 \leq \sqrt{s_{NN}} \leq 9.2 $\end{document} ![]()
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\begin{document}$ 4^{th} $\end{document} ![]()
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High moments of conserved quantities such as net-baryon, net-electric charge, and net-strangeness in heavy-ion collisions are sensitive to fluctuations caused by the QCD critical point (CP). The event-by-event analysis of high moments of the conserved charges has been widely used in experiments to search for the CP, especially in the RHIC-STAR experiment. In order to establish a dynamical non-critical base line, especially at the high baryon density region, we have performed a systematic analysis of the proton multiplicity distributions from Au+Au collisions at
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In this letter, we present rephasing invariant formulae\begin{document}$ \delta^{(\alpha i)} = \arg [{ V_{\alpha 1} V_{\alpha 2} V_{\alpha 3} V_{1i} V_{2i} V_{3i} / V_{\alpha i }^{3} \det V }] $\end{document} ![]()
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\begin{document}$ \delta^{(\alpha i)} $\end{document} ![]()
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\begin{document}$ \delta^{(\alpha i)} $\end{document} ![]()
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\begin{document}$ \Phi_{\alpha i} $\end{document} ![]()
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\begin{document}$ \delta^{(\alpha, i+2)} - \delta^{(\alpha, i+1)} = \Phi_{\alpha+1, i} - \Phi_{\alpha+2, i} $\end{document} ![]()
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\begin{document}$ \delta^{(\alpha+1, i)} - \delta^{(\alpha+2, i)} = \Phi_{\alpha, i+2} - \Phi_{\alpha, i+1} $\end{document} ![]()
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\begin{document}$ \delta_{\mathrm{PDG}}+\delta_{\mathrm{KM}}=\pi-\alpha+\gamma. $\end{document} ![]()
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In this letter, we present rephasing invariant formulae
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The breakup of weakly bound projectiles has been shown to significantly influence scattering processes, including elastic scattering. In this context, we revisit the angular distributions (ADs) for elastic scattering of 7Li from 118Sn and 120Sn targets. The study analyzes 7Li + 118Sn ADs over the energy range 18.15–48 MeV and 7Li + 120Sn ADs from 20–44 MeV, utilizing various nuclear interaction models. These include the São Paulo potential, the CDM3Y6 potential (with and without rearrangement term), and cluster folding model. Results indicate that the real component of the folded potentials must be scaled down by 40–65% to achieve an accurate fit to the experimental ADs, underscoring the prominent role of 7Li breakup effects. Interestingly, the conventional threshold anomaly observed in reactions involving tightly bound nuclei is not present. Further analysis using the continuum discretized coupled channels (CDCC) approach provides excellent agreement with the data, reinforcing these findings.
The breakup of weakly bound projectiles has been shown to significantly influence scattering processes, including elastic scattering. In this context, we revisit the angular distributions (ADs) for elastic scattering of 7Li from 118Sn and 120Sn targets. The study analyzes 7Li + 118Sn ADs over the energy range 18.15–48 MeV and 7Li + 120Sn ADs from 20–44 MeV, utilizing various nuclear interaction models. These include the São Paulo potential, the CDM3Y6 potential (with and without rearrangement term), and cluster folding model. Results indicate that the real component of the folded potentials must be scaled down by 40–65% to achieve an accurate fit to the experimental ADs, underscoring the prominent role of 7Li breakup effects. Interestingly, the conventional threshold anomaly observed in reactions involving tightly bound nuclei is not present. Further analysis using the continuum discretized coupled channels (CDCC) approach provides excellent agreement with the data, reinforcing these findings.
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A relativistic Hartree-Bogoliubov (RHB) model based on quark-meson coupling is developed, with a new parametrization derived from experimental observables. Using this model, we systematically investigate the ground-state properties of even-even nuclei spanning\begin{document}$ 8\leq Z\leq118 $\end{document} ![]()
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A relativistic Hartree-Bogoliubov (RHB) model based on quark-meson coupling is developed, with a new parametrization derived from experimental observables. Using this model, we systematically investigate the ground-state properties of even-even nuclei spanning
Evaluation of the moments of inertia of forced split fragments for nuclei 232Th (n,f) and 238U (n,f)
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This study develops an innovative theoretical framework that integrates macroscopic liquid-drop model with microscopic superfluid theory to calculate moments of inertia for fission fragments, extending our previous spontaneous fission approach to include neutron-induced threshold fission of\begin{document}$ {}^{232}Th\left( {n,f} \right) $\end{document} ![]()
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\begin{document}$ {}^{238}{\text{U}}\left( {n,f} \right) $\end{document} ![]()
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This study develops an innovative theoretical framework that integrates macroscopic liquid-drop model with microscopic superfluid theory to calculate moments of inertia for fission fragments, extending our previous spontaneous fission approach to include neutron-induced threshold fission of
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We investigated the impact of a constant external magnetic field on the dressed propagators of up-, down-, and strange quarks. In the weak field limit, we derive a general momentum-space representation for the propagator and numerically solve the corresponding gap equation. Our analysis reveals that the vector term of the propagator can be decomposed into components parallel and perpendicular to the magnetic field, resulting in anisotropic effective masses, with the transverse mass consistently exceeding the longitudinal mass. This mass disparity exhibits a power law dependence on the magnetic field strength and is less pronounced for the strange quark compared to up and down quarks. Additionally, the magnetic field induces axial-vector and tensor terms, highlighting the Zeeman effect resulting from quark interactions with the magnetic field. These findings have important implications for (inverse) magnetic catalysis, and phenomena such as vector meson and pion condensations.
We investigated the impact of a constant external magnetic field on the dressed propagators of up-, down-, and strange quarks. In the weak field limit, we derive a general momentum-space representation for the propagator and numerically solve the corresponding gap equation. Our analysis reveals that the vector term of the propagator can be decomposed into components parallel and perpendicular to the magnetic field, resulting in anisotropic effective masses, with the transverse mass consistently exceeding the longitudinal mass. This mass disparity exhibits a power law dependence on the magnetic field strength and is less pronounced for the strange quark compared to up and down quarks. Additionally, the magnetic field induces axial-vector and tensor terms, highlighting the Zeeman effect resulting from quark interactions with the magnetic field. These findings have important implications for (inverse) magnetic catalysis, and phenomena such as vector meson and pion condensations.
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Event shape measurements are crucial for understanding the underlying event and multiple-parton interactions (MPIs) in high energy proton-proton (pp) collisions. In this paper, the Tsallis Blast-Wave model with independent non-extensive parameters for mesons and baryons, was applied to analyze transverse momentum spectra of charged pions, kaons, and protons in pp collision events at\begin{document}$ \sqrt{s}=13 $\end{document} ![]()
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Event shape measurements are crucial for understanding the underlying event and multiple-parton interactions (MPIs) in high energy proton-proton (pp) collisions. In this paper, the Tsallis Blast-Wave model with independent non-extensive parameters for mesons and baryons, was applied to analyze transverse momentum spectra of charged pions, kaons, and protons in pp collision events at
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\begin{document}$F(R)$\end{document} ![]()
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\begin{document}$R^2$\end{document} ![]()
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\begin{document}$F(R)$\end{document} ![]()
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\begin{document}$R^2$\end{document} ![]()
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\begin{document}$F(R)$\end{document} ![]()
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A novel framework for analyzing unstable composite particles using Green's functions and dispersion relations is presented. As an illustrative example, we explore the ρ vector meson decay process\begin{document}$\rho\to\pi\pi$\end{document} ![]()
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\begin{document}$\Delta M $\end{document} ![]()
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\begin{document}$\Gamma(M)$\end{document} ![]()
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A novel framework for analyzing unstable composite particles using Green's functions and dispersion relations is presented. As an illustrative example, we explore the ρ vector meson decay process
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, doi: 10.1088/1674-1137/adfe55
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A sensitivity study was performed to investigate the impact of individual nuclear masses on r-process rare-earth peak abundances in different astrophysical scenarios. The most impactful nuclei are primarily distributed in two regions on the nuclear chart: one located 20-30 neutrons away from stability (defined as region I) and another 7-15 neutrons away from stability (defined as region II), as previously reported in Phys. Lett. B 844, 138092 (2023). In this work, we extend our analysis by focusing on the role of fission in the mass sensitivity study. The results show that in astrophysical scenarios involving fission, the sensitivity of nuclei in region I is diminished due to the deposition of a large number of fission fragments in the rare-earth mass region. However, nuclei in region II retain high sensitivity because the contribution of fission decreases in the later stages of nucleosynthesis. This study highlights the impact of fission on the sensitivity of r-process abundances to nuclear masses and helps to enhance the understanding of the rare-earth peak formation mechanism.
A sensitivity study was performed to investigate the impact of individual nuclear masses on r-process rare-earth peak abundances in different astrophysical scenarios. The most impactful nuclei are primarily distributed in two regions on the nuclear chart: one located 20-30 neutrons away from stability (defined as region I) and another 7-15 neutrons away from stability (defined as region II), as previously reported in Phys. Lett. B 844, 138092 (2023). In this work, we extend our analysis by focusing on the role of fission in the mass sensitivity study. The results show that in astrophysical scenarios involving fission, the sensitivity of nuclei in region I is diminished due to the deposition of a large number of fission fragments in the rare-earth mass region. However, nuclei in region II retain high sensitivity because the contribution of fission decreases in the later stages of nucleosynthesis. This study highlights the impact of fission on the sensitivity of r-process abundances to nuclear masses and helps to enhance the understanding of the rare-earth peak formation mechanism.
Existence of quark stars in gravity's Rainbow: the significance of strongly interacting quark matter
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This paper explores the internal composition and equation of state (EoS) of quark stars (QSs) characterised by pressure anisotropy, considering recent astrophysical findings within the framework of gravity's rainbow. By employing perturbative quantum chromodynamics (QCD) corrections and the concept of color superconductivity, the EoS was formulated as a dimensionless function reliant on a single parameter, thereby offering an in-depth analysis of the effects of strong interactions. The study is further extended by rescaling the EoS and applying dimensionless variables, thus covering a range from non-interacting quark matter to extreme stiffness characterized by a parameter\begin{document}$\bar{\lambda}$\end{document} ![]()
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This paper explores the internal composition and equation of state (EoS) of quark stars (QSs) characterised by pressure anisotropy, considering recent astrophysical findings within the framework of gravity's rainbow. By employing perturbative quantum chromodynamics (QCD) corrections and the concept of color superconductivity, the EoS was formulated as a dimensionless function reliant on a single parameter, thereby offering an in-depth analysis of the effects of strong interactions. The study is further extended by rescaling the EoS and applying dimensionless variables, thus covering a range from non-interacting quark matter to extreme stiffness characterized by a parameter
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, doi: 10.1088/1674-1137/ae042f
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We have modified the Deformed Gamow-like Model (DGLM) by incorporating the impact of daughter nucleus deformation on the Coulomb interaction between the daughter nucleus and emitted proton. Using this modified DGLM, we have systematically calculated the half-lives of both single-proton and two-proton radioactivity within a unified framework. The computational results demonstrate remarkable consistency with experimental radioactivity half-lives. Additionally, our study explores how deformation influences penetration probabilities and establishes a universal curve that relates penetration probability to experimental half-lives, thereby validating the efficacy of the DGLM. We also made unified predictions for the half-lives of potential single-proton and two-proton radioactive nuclei, which align well with other models, underscoring the reliability of the DGLM in predicting proton radioactivity.
We have modified the Deformed Gamow-like Model (DGLM) by incorporating the impact of daughter nucleus deformation on the Coulomb interaction between the daughter nucleus and emitted proton. Using this modified DGLM, we have systematically calculated the half-lives of both single-proton and two-proton radioactivity within a unified framework. The computational results demonstrate remarkable consistency with experimental radioactivity half-lives. Additionally, our study explores how deformation influences penetration probabilities and establishes a universal curve that relates penetration probability to experimental half-lives, thereby validating the efficacy of the DGLM. We also made unified predictions for the half-lives of potential single-proton and two-proton radioactive nuclei, which align well with other models, underscoring the reliability of the DGLM in predicting proton radioactivity.
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, doi: 10.1088/1674-1137/adfe54
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The low-lying excitation energies of the\begin{document}$2_1^+, 4_1^+,2_2^+, 0_2^+,3_1^-, 0_3^+$\end{document} ![]()
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\begin{document}$2_1^+$\end{document} ![]()
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\begin{document}$2_2^+$\end{document} ![]()
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\begin{document}$2_1^+$\end{document} ![]()
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\begin{document}$2_2^+$\end{document} ![]()
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The low-lying excitation energies of the
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The radial oscillations of neutron stars are studied using equations of state derived from density-dependent relativistic mean-field (DDRMF) models, which effectively describe the ground-state properties of finite nuclei. A novel numerical approach, the finite volume method (FVM), is employed to solve the eigenvalue problem associated with oscillation frequencies. Compared to conventional methods such as the finite difference method and shooting method, the FVM avoids the numerical instability encountered at high frequencies with an equation of state that includes a discontinuous adiabatic index and offers greater computational efficiency. The oscillation frequencies of high-order modes exhibit a similar trend of change. The radial displacements and pressure perturbations are largely influenced by the EOSs of crust region.The frequency of the first excited state shows a strong linear relationship with both the slope and skewness parameters of the symmetry energy. These findings suggest that the density dependence of the symmetry energy can be constrained through observations of neutron star radial oscillation frequencies.
The radial oscillations of neutron stars are studied using equations of state derived from density-dependent relativistic mean-field (DDRMF) models, which effectively describe the ground-state properties of finite nuclei. A novel numerical approach, the finite volume method (FVM), is employed to solve the eigenvalue problem associated with oscillation frequencies. Compared to conventional methods such as the finite difference method and shooting method, the FVM avoids the numerical instability encountered at high frequencies with an equation of state that includes a discontinuous adiabatic index and offers greater computational efficiency. The oscillation frequencies of high-order modes exhibit a similar trend of change. The radial displacements and pressure perturbations are largely influenced by the EOSs of crust region.The frequency of the first excited state shows a strong linear relationship with both the slope and skewness parameters of the symmetry energy. These findings suggest that the density dependence of the symmetry energy can be constrained through observations of neutron star radial oscillation frequencies.
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, doi: 10.1088/1674-1137/adfa74
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We investigate the quasi-normal modes (QNMs) under the gravitational field perturbations and the grey-body factors for a class of regular black holes with sub-Planckian curvature and Minkowski core. Specifically, we compute the QNMs with the pseudospectral method and the WKB method. It is found that as the deviation parameter of the regular black hole changes, the trajectory of the QNMs displays non-monotonic and spiral behavior. Then we compute the grey-body factors with the WKB method and compare them with the results obtained by the correspondence relation recently revealed in [1 ]. We find the discrepancy exhibits minor errors, indicating that this relation is effective for computing the grey-body factors of such regular black holes.
We investigate the quasi-normal modes (QNMs) under the gravitational field perturbations and the grey-body factors for a class of regular black holes with sub-Planckian curvature and Minkowski core. Specifically, we compute the QNMs with the pseudospectral method and the WKB method. It is found that as the deviation parameter of the regular black hole changes, the trajectory of the QNMs displays non-monotonic and spiral behavior. Then we compute the grey-body factors with the WKB method and compare them with the results obtained by the correspondence relation recently revealed in [
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High-precision regression of physical parameters from black hole images generated by General Relativistic Ray Tracing (GRRT) is essential for investigating spacetime curvature and advancing black hole astrophysics. However, due to limitations in observational resolution, high observational costs, and imbalanced distributions of positive and negative samples, black hole images often suffer from data scarcity, sparse parameter spaces, and complex structural characteristics. These factors pose significant challenges to conventional regression methods based on simplified physical models. To overcome these challenges, this study introduces Multiscale Adaptive Network (MANet), a novel regression framework grounded in deep learning. MANet integrates an Adaptive Channel Attention (ACA) module to selectively enhance features in physically informative regions. Meanwhile, a Multiscale Enhancement Feature Pyramid (MEFP) is employed to capture fine-grained spatial structures such as photon rings and accretion disks, while alleviating information loss due to downsampling. Experimental evaluations on GRRT-simulated datasets demonstrate that MANet substantially improves parameter estimation accuracy and generalization capability in high-dimensional parameter spaces, outperforming existing baseline approaches. This framework presents a promising avenue for high-precision parameter regression in Event Horizon Telescope (EHT) data analysis and broader astrophysical imaging applications characterized by sparse and noisy data.
High-precision regression of physical parameters from black hole images generated by General Relativistic Ray Tracing (GRRT) is essential for investigating spacetime curvature and advancing black hole astrophysics. However, due to limitations in observational resolution, high observational costs, and imbalanced distributions of positive and negative samples, black hole images often suffer from data scarcity, sparse parameter spaces, and complex structural characteristics. These factors pose significant challenges to conventional regression methods based on simplified physical models. To overcome these challenges, this study introduces Multiscale Adaptive Network (MANet), a novel regression framework grounded in deep learning. MANet integrates an Adaptive Channel Attention (ACA) module to selectively enhance features in physically informative regions. Meanwhile, a Multiscale Enhancement Feature Pyramid (MEFP) is employed to capture fine-grained spatial structures such as photon rings and accretion disks, while alleviating information loss due to downsampling. Experimental evaluations on GRRT-simulated datasets demonstrate that MANet substantially improves parameter estimation accuracy and generalization capability in high-dimensional parameter spaces, outperforming existing baseline approaches. This framework presents a promising avenue for high-precision parameter regression in Event Horizon Telescope (EHT) data analysis and broader astrophysical imaging applications characterized by sparse and noisy data.
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We investigate the bound-state equations in two-dimensional QCD in the\begin{document}$ N_c\to \infty $\end{document} ![]()
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We investigate the bound-state equations in two-dimensional QCD in the
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We study a three-loop induced neutrino mass scenario from a non-holomorphic modular A4 flavor symmetry and reach the minimum scenario leading predictions of the lepton masses, mixing angles, and Dirac and Majorana phases, which are shown through the chi square analyses. In addition, we discuss the lepton flavor violations, muon anomalous magnetic moment, lepton universality, and relic density of the dark matter candidate. And, we find that we need to extend our model if we satisfy the observed relic density of dark matter within the limit of perturbation where it can be done by adding one singlet scalar boson without changing predictions in neutrino sector.
We study a three-loop induced neutrino mass scenario from a non-holomorphic modular A4 flavor symmetry and reach the minimum scenario leading predictions of the lepton masses, mixing angles, and Dirac and Majorana phases, which are shown through the chi square analyses. In addition, we discuss the lepton flavor violations, muon anomalous magnetic moment, lepton universality, and relic density of the dark matter candidate. And, we find that we need to extend our model if we satisfy the observed relic density of dark matter within the limit of perturbation where it can be done by adding one singlet scalar boson without changing predictions in neutrino sector.
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The decay of the Higgs boson and the nature of dark matter remain fundamental challenges in particle physics. We investigate the 95 GeV diphoton excess and dark matter within the framework of the triplet-extended Minimal Supersymmetric Standard Model (TMSSM). In this model, an additional Hypercharge\begin{document}$ Y=0 $\end{document} ![]()
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\begin{document}$ SU(2)_L $\end{document} ![]()
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\begin{document}$ \mu_{\gamma\gamma}^{{\rm{CMS+ATLAS}}} = 0.24_{-0.08}^{+0.09} $\end{document} ![]()
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\begin{document}$ Zb\bar{b} $\end{document} ![]()
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\begin{document}$ 2\sigma $\end{document} ![]()
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The decay of the Higgs boson and the nature of dark matter remain fundamental challenges in particle physics. We investigate the 95 GeV diphoton excess and dark matter within the framework of the triplet-extended Minimal Supersymmetric Standard Model (TMSSM). In this model, an additional Hypercharge
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The determination of non-linear corrections to the nuclear distribution functions due to the HIJING parameterization within the framework of perturbative QCD, specifically the GLR-MQ equations, is discussed. We analyze the possibility of constraining the non-linear corrections present in distribution functions using the inclusive observables that will be measured in future electron-ion colliders. The results show that non-linear corrections play an important role in heavy nuclear reduced cross sections at low x and low\begin{document}$ Q^2 $\end{document} ![]()
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The determination of non-linear corrections to the nuclear distribution functions due to the HIJING parameterization within the framework of perturbative QCD, specifically the GLR-MQ equations, is discussed. We analyze the possibility of constraining the non-linear corrections present in distribution functions using the inclusive observables that will be measured in future electron-ion colliders. The results show that non-linear corrections play an important role in heavy nuclear reduced cross sections at low x and low
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Recently a series of new measurements with both the neutral and charge current Drell–Yan processes have been performed at hadron colliders, showing deviations from the predictions of the current parton distribution functions (PDFs). In this article, the impact of these new measurements is studied by using their results to update the PDFs. Although these new measurements correspond to different boson propagators and colliding energies, they are found to have a similar impact to the light quark parton distributions with the momentum fraction x around 0.1. It manifests that the deviations are consistent with each other and favor a larger valence\begin{document}$ d_v/u_v $\end{document} ![]()
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Recently a series of new measurements with both the neutral and charge current Drell–Yan processes have been performed at hadron colliders, showing deviations from the predictions of the current parton distribution functions (PDFs). In this article, the impact of these new measurements is studied by using their results to update the PDFs. Although these new measurements correspond to different boson propagators and colliding energies, they are found to have a similar impact to the light quark parton distributions with the momentum fraction x around 0.1. It manifests that the deviations are consistent with each other and favor a larger valence
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The present study uses the minimal geometric deformation scheme within the paradigm of\begin{document}$ f({\cal{R}},{\cal{L}}_m,T) $\end{document} ![]()
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The present study uses the minimal geometric deformation scheme within the paradigm of
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The charmed baryon was first observed experimentally in 1975, one year after the charm quark's confirmation via the discovery of the\begin{document}$ J/\psi $\end{document} ![]()
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\begin{document}$ D_{(s)} $\end{document} ![]()
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The charmed baryon was first observed experimentally in 1975, one year after the charm quark's confirmation via the discovery of the
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, doi: 10.1088/1674-1137/ad8ec2
Abstract:
The direct CP asymmetry in the weak decay process of hadrons is commonly attributed to the weak phase of the CKM matrix and the indeterminate strong phase. We propose a method to generate a significant phase difference through the interference between ρ and ω mesons, taking into account the G-parity allowed decay process of\begin{document}$\omega \rightarrow \pi^{+}\pi^{-}\pi^{0}$\end{document} ![]()
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\begin{document}$\rho^{0} \rightarrow \pi^{+}\pi^{-}\pi^{0}$\end{document} ![]()
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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
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