G. S. Singh scite author profile

Background: 34 Na is conjectured to play an important role in the production of seed nuclei in the alternate r -process paths involving light neutron rich nuclei very near the β-stability line, and as such, it is important to know its ground state properties and structure to calculate rates of the reactions it might be involved in, in the stellar plasma. Found in the region of 'island of inversion', its ground state might not be in agreement with normal shell model predictions.Purpose: The aim of this paper is to study the elastic Coulomb breakup of 34 Na on 208 Pb to give us a core of 33 Na with a neutron and in the process we try and investigate the one neutron separation energy and the ground state configuration of 34 Na.Method: A fully quantum mechanical Coulomb breakup theory within the architecture of post-form finite range distorted wave Born approximation extended to include the effects of deformation is used to research the elastic Coulomb breakup of 34 Na on 208 Pb at 100 MeV/u. The triple differential cross-section calculated for the breakup is integrated over the desired components to find the total cross-section, momentum and angular distributions as well as the average momenta, along with the energy-angular distributions.Results: The total one neutron removal cross-section is calculated to test the possible ground state configurations of 34 Na. The average momentum results along with energy-angular calculations indicate 34 Na to have a halo structure. The parallel momentum distributions with narrow full widths at half maxima signify the same. Conclusion:We have attempted to analyse the possible ground state configurations of 34 Na and in congruity with the patterns in the 'island of inversion' conclude that even without deformation, 34 Na should be a neutron halo with a predominant contribution to its ground state most probably coming from 33 Na(3/2 + ) ⊗ 2p 3/2 ν configuration. We also surmise that it would certainly be useful and rewarding to test our predictions with an experiment to put stricter limits on its ground state configuration and binding energy. * gagandph@iitr.ac.in

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Electronic structure of1T−TiS2

Sharma

Nautiyal

Singh

et al. 1999

Phys. Rev. B

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Analytical pair correlations in ideal quantum gases: Temperature-dependent bunching and antibunching

2011

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The fluctuation-dissipation theorem together with the exact density response spectrum for ideal quantum gases has been utilized to yield a new expression for the static structure factor, which we use to derive exact analytical expressions for the temperature-dependent pair distribution function g(r) of the ideal gases. The plots of bosonic and fermionic g(r) display "Bose pile" and "Fermi hole" typically akin to bunching and antibunching as observed experimentally for ultracold atomic gases. The behavior of spin-scaled pair correlation for fermions is almost featureless, but bosons show a rich structure including long-range correlations near T(c). The coherent state at T=0 shows no correlation at all, just like single-mode lasers. The depicted decreasing trend in correlation with decrease in temperature for T

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Geometry of hard ellipsoidal fluids and their virial coefficients

Singh

Kumar

1996

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This article is primarily addressed to the geometry of hard ellipsoidal molecules which is essentially required in the study of the fluid structure, thermodynamics and transport properties of the model hard-biaxial fluids or liquid crystals. A methodology has systematically been followed in obtaining the known as well as hitherto unknown results for a biaxial system. The computationally convenient and neat expressions have been achieved for the surface and volume elements of a biaxial molecule. New expressions have been obtained for the surface area S and the mean radius of curvature R of a rigid ellipsoid in terms of the elliptic integrals of the first and second kinds. In the limit when the two axes become equal, the expressions obtained for the ellipsoidal molecules reduce to those of the spheroidal systems. Exact expression has been obtained for the second virial coefficient of the ellipsoidal fluid and furthermore the significance of our analytical results for such a fluid are enunciated in the context of the study of the higher virial coefficients and equation of state.

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Exploring the structure of 29Ne

et al. 2021

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G. S. Singh

Elastic Coulomb breakup ofNa34

Electronic structure of1T−TiS2

Analytical pair correlations in ideal quantum gases: Temperature-dependent bunching and antibunching

Geometry of hard ellipsoidal fluids and their virial coefficients

Exploring the structure of 29Ne

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