246 research outputs found

    Connection between effective-range expansion and nuclear vertex constant or asymptotic normalization coefficient

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    Explicit relations between the effective-range expansion and the nuclear vertex constant or asymptotic normalization coefficient (ANC) for the virtual decay B→A+aB\to A+a are derived for an arbitrary orbital momentum together with the corresponding location condition for the (A+aA+a) bound-state energy. They are valid both for the charged case and for the neutral case. Combining these relations with the standard effective-range function up to order six makes it possible to reduce to two the number of free effective-range parameters if an ANC value is known from experiment. Values for the scattering length, effective range, and form parameter are determined in this way for the 16^{16}O+pp, α+t\alpha+t and α+3\alpha+^3He collisions in partial waves where a bound state exists by using available ANCs deduced from experiments. The resulting effective-range expansions for these collisions are valid up to energies larger 5 MeV.Comment: 17 pages, 6 figure

    Acoustics of a Nonhomogeneous Moving Medium.

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    Theoretical basis of the acoustics of a moving nonhomogeneous medium is considered in this report. Experiments that illustrate or confirm some of the theoretical explanation or derivation of these acoustics are also included

    Coulomb renormalization and ratio of proton and neutron asymptotic normalization coefficients for mirror nuclei

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    Asymptotic normalization coefficients (ANCs) are fundamental nuclear constants playing important role in nuclear reactions, nuclear structure and nuclear astrophysics. In this paper the physical reasons of the Coulomb renormalization of the ANC are addressed. Using Pinkston-Satchler equation the ratio for the proton and neutron ANCs of mirror nuclei is obtained in terms of the Wronskians from the radial overlap functions and regular solutions of the two-body Schr\"odinger equation with the short-range interaction excluded. This ratio allows one to use microscopic overlap functions for mirror nuclei in the internal region, where they are the most accurate, to correctly predict the ratio of the ANCs for mirror nuclei, which determine the amplitudes of the tails of the overlap functions. Calculations presented for different nuclei demonstrate the Coulomb renormalization effects and independence of the ratio of the nucleon ANCs for mirror nuclei on the channel radius. This ratio is valid both for bound states and resonances. One of the goals of this paper is to draw attention on the possibility to use the Coulomb renormalized ANCs rather than the standard ones especially when the standard ANCs are too large.Comment: 20 pages, 14 figure

    Influence of low energy scattering on loosely bound states

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    Compact algebraic equations are derived, which connect the binding energy and the asymptotic normalization constant (ANC) of a subthreshold bound state with the effective-range expansion of the corresponding partial wave. These relations are established for positively-charged and neutral particles, using the analytic continuation of the scattering (S) matrix in the complex wave-number plane. Their accuracy is checked on simple local potential models for the 16O+n, 16O+p and 12C+alpha nuclear systems, with exotic nuclei and nuclear astrophysics applications in mind

    Quantum Monte Carlo calculations of spectroscopic overlaps in A≤7A \leq 7 nuclei

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    We present Green's function Monte Carlo calculations of spectroscopic overlaps for A≤7A \leq 7 nuclei. The realistic Argonne v18 two-nucleon and Illinois-7 three-nucleon interactions are used to generate the nuclear states. The overlap matrix elements are extrapolated from mixed estimates between variational Monte Carlo and Green's function Monte Carlo wave functions. The overlap functions are used to obtain spectroscopic factors and asymptotic normalization coefficients, and they can serve as an input for low-energy reaction calculations

    Generalized Faddeev equations in the AGS form for deuteron stripping with explicit inclusion of target excitations and Coulomb interaction

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    Theoretical description of reactions in general, and the theory for (d,p)(d,p) reactions, in particular, needs to advance into the new century. Here deuteron stripping processes off a target nucleus consisting of A{A} nucleons are treated within the framework of the few-body integral equations theory. The generalized Faddeev equations in the AGS form, which take into account the target excitations, with realistic optical potentials provide the most advanced and complete description of the deuteron stripping. The main problem in practical application of such equations is the screening of the Coulomb potential, which works only for light nuclei. In this paper we present a new formulation of the Faddeev equations in the AGS form taking into account the target excitations with explicit inclusion of the Coulomb interaction. By projecting the (A+2)(A+2)-body operators onto target states, matrix three-body integral equations are derived which allow for the incorporation of the excited states of the target nucleons. Using the explicit equations for the partial Coulomb scattering wave functions in the momentum space we present the AGS equations in the Coulomb distorted wave representation without screening procedure. We also use the explicit expression for the off-shell two-body Coulomb scattering TT-matrix which is needed to calculate the effective potentials in the AGS equations. The integrals containing the off-shell Coulomb T-matrix are regularized to make the obtained equations suitable for calculations. For NNNN and nucleon-target nuclear interactions we assume the separable potentials what significantly simplifies solution of the AGS equations.Comment: 34 pages, 13 figure

    Relation between widths of proton resonances and neutron asymptotic normalization coefficients in mirror states of light nuclei in a microscopic cluster model

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    It has been suggested recently ({\it Phys. Rev. Lett.} 91, 232501 (2003)) that the widths of narrow proton resonances are related to neutron Asymptotic Normalization Coefficients (ANCs) of their bound mirror analogs because of charge symmetry of nucleon-nucleon interactions. This relation is approximated by a simple analytical formula which involves proton resonance energies, neutron separation energies, charges of residual nuclei and the range of their strong interaction with the last nucleon. In the present paper, we perform microscopic-cluster model calculations for the ratio of proton widths to neutron ANCs squared in mirror states for several light nuclei. We compare them to predictions of the analytical formula and to estimates made within a single-particle potential model. A knowledge of this ratio can be used to predict unknown proton widths for very narrow low-lying resonances in the neutron-deficient region of the sdsd- and pfpf-shells, which is important for understanding the nucleosynthesis in the rprp-process.Comment: 13 pages, 5 figures, submitted to PR

    {Once more about astrophysical SS factor for the α+d→6Li+γ\alpha + d \to {}^{6}{\rm Li} + \gamma reaction

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    Recently to study the radiative capture α+d→6Li+γ\alpha + d \to {}^{6}{\rm Li} + \gamma process a new measurement of the 6Li(A 150 MeV){}^{6}{\rm Li}({\rm A\,150\,MeV}) dissociation in the field of 208Pb{}^{208}{\rm Pb} has been reported in [F. Hammache {\it et al.} Phys. Rev C82{\bf C 82}, 065803 (2010)]. However, the dominance of the nuclear breakup over the Coulomb one prevented from obtaining the information about the α+d→6Li+γ\alpha + d \to {}^{6}{\rm Li} + \gamma process from the breakup data. The astrophysical S24(E)S_{24}(E) factor has been calculated within the α−d\alpha-d two-body potential model with potentials determined from the fits to the α−d\alpha-d elastic scattering phase shifts. However, the scattering phase shift itself doesn't provide a unique α−d\alpha-d bound state potential, which is the most crucial input when calculating the S24(E)S_{24}(E) astrophysical factor at astrophysical energies. In this work we emphasize an important role of the asymptotic normalization coefficient (ANC) for 6Li→α+d{}^{6}{\rm Li} \to \alpha + d, which controls the overall normalization of the peripheral α+d→6Li+γ\alpha + d \to {}^{6}{\rm Li} + \gamma process and is determined by the adopted α−d\alpha-d bound state potential. We demonstrate that the ANC previously determined from the α−d\alpha-d elastic scattering ss-wave phase shift in [Blokhintsev {\it et. al} Phys. Rev. {\bf C 48}, 2390 (1993)] gives S24(E)S_{24}(E), which is at low energies about 38% lower than the one reported in [F. Hammache {\it et al.} Phys. Rev C82{\bf C 82}, 065803 (2010)]. We recalculate also the reaction rates, which are also lower than those obtained in [F. Hammache {\it et al.} Phys. Rev C82{\bf C 82}, 065803 (2010)].Comment: 6 pages and 2 figure

    Astrophysical SS factor for the 15N(p,γ)16O{}^{15}{\rm N}(p,\gamma){}^{16}{\rm O} reaction from RR-matrix analysis and asymptotic normalization coefficient for 16O→15N+p{}^{16}{\rm O} \to {}^{15}{\rm N} + p. Is any fit acceptable?

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    The 15N(p,γ)16O^{15}{\rm N}(p,\gamma)^{16}{\rm O} reaction provides a path from the CN cycle to the CNO bi-cycle and CNO tri-cycle. The measured astrophysical factor for this reaction is dominated by resonant capture through two strong Jπ=1−J^{\pi}=1^{-} resonances at ER=312E_{R}= 312 and 962 keV and direct capture to the ground state. Recently, a new measurement of the astrophysical factor for the 15N(p,γ)16O^{15}{\rm N}(p,\gamma)^{16}{\rm O} reaction has been published [P. J. LeBlanc {\it et al.}, Phys. Rev. {\bf C 82}, 055804 (2010)]. The analysis has been done using the RR-matrix approach with unconstrained variation of all parameters including the asymptotic normalization coefficient (ANC). The best fit has been obtained for the square of the ANC C2=539.2C^{2}= 539.2 fm−1{}^{-1}, which exceeds the previously measured value by a factor of ≈3\approx 3. Here we present a new RR-matrix analysis of the Notre Dame-LUNA data with the fixed within the experimental uncertainties square of the ANC C2=200.34C^{2}=200.34 fm−1{}^{-1}. Rather than varying the ANC we add the contribution from a background resonance that effectively takes into account contributions from higher levels. Altogether we present 8 fits, five unconstrained and three constrained. In all the fits the ANC is fixed at the previously determined experimental value C2=200.34C^{2}=200.34 fm−1{}^{-1}. For the unconstrained fit with the boundary condition Bc=Sc(E2)B_{c}=S_{c}(E_{2}), where E2E_{2} is the energy of the second level, we get S(0)=39.0±1.1S(0)=39.0 \pm 1.1 keVb and normalized χ~2=1.84{\tilde \chi}^{2}=1.84, i.e. the result which is similar to [P. J. LeBlanc {\it et al.}, Phys. Rev. {\bf C 82}, 055804 (2010)]. From all our fits we get the range 33.1≤S(0)≤40.133.1 \leq S(0) \leq 40.1 keVb which overlaps with the result of [P. J. LeBlanc {\it et al.}, Phys. Rev. {\bf C 82}, 055804 (2010)]. We address also physical interpretation of the fitting parameters.Comment: Submitted to PR

    Bound, virtual and resonance SS-matrix poles from the Schr\"odinger equation

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    A general method, which we call the potential SS-matrix pole method, is developed for obtaining the SS-matrix pole parameters for bound, virtual and resonant states based on numerical solutions of the Schr\"odinger equation. This method is well-known for bound states. In this work we generalize it for resonant and virtual states, although the corresponding solutions increase exponentially when r→∞r\to\infty. Concrete calculations are performed for the 1+1^+ ground and the 0+0^+ first excited states of 14N^{14}\rm{N}, the resonance 15F^{15}\rm{F} states (1/2+1/2^+, 5/2+5/2^+), low-lying states of 11Be^{11}\rm{Be} and 11N^{11}\rm{N}, and the subthreshold resonances in the proton-proton system. We also demonstrate that in the case the broad resonances their energy and width can be found from the fitting of the experimental phase shifts using the analytical expression for the elastic scattering SS-matrix. We compare the SS-matrix pole and the RR-matrix for broad s1/2s_{1/2} resonance in 15F{}^{15}{\rm F}Comment: 14 pages, 5 figures (figures 3 and 4 consist of two figures each) and 4 table
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