Your search keyword '"Samaddar, S."' showing total 522 results

1. Mapping quantum Hall edge states in graphene by scanning tunneling microscopy

Author

Johnsen, T., Schattauer, C., Samaddar, S., Weston, A., Hamer, M., Watanabe, K., Taniguchi, T., Gorbachev, R., Libisch, F., and Morgenstern, M.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Other Condensed Matter, Condensed Matter - Quantum Gases

Abstract

Quantum Hall edge states are the paradigmatic example of the bulk-boundary correspondence. They are prone to intricate reconstructions calling for their detailed investigation at high spatial resolution. Here, we map quantum Hall edge states of monolayer graphene at a magnetic field of 7 T with scanning tunneling microscopy. The graphene sample features a gate-tunable lateral interface between areas of different filling factor. We compare the results with detailed tight-binding calculations quantitatively accounting for the perturbation by the tip-induced quantum dot. We find that the edge state pattern is mapped with little perturbation by adequate choice of gate voltage. We observe extended compressible regions, the antinodal structure of edge states and their meandering along the lateral interface., Comment: 23 pages, 23 figures

Published

2022

2. Cascading effects of composts and cover crops on soil chemistry, bacterial communities and the survival of foodborne pathogens.

Author

Devarajan, N, McGarvey, JA, Scow, K, Jones, MS, Lee, S, Samaddar, S, Schmidt, R, Tran, TD, and Karp, DS

Subjects

Animals, Salmonella enterica, Manure, Soil, Fertilizers, Soil Microbiology, Composting, Listeria, Salmonella, biological soil amendment of animal origin, co-management, compost, food safety, healthy soil, manure, organic, soil amendment, co&#8208, management, Prevention, Emerging Infectious Diseases, Digestive Diseases, Infectious Diseases, Foodborne Illness, Infection, Microbiology

Abstract

AimsRecent foodborne disease outbreaks have caused farmers to re-evaluate their practices. In particular, concern that soil amendments could introduce foodborne pathogens onto farms and promote their survival in soils has led farmers to reduce or eliminate the application of animal-based composts. However, organic amendments (such as composts and cover crops) could bolster food safety by increasing soil microbial diversity and activity, which can act as competitors or antagonists and reduce pathogen survival.Methods and resultsLeveraging a study of a 27-year experiment comparing organic and conventional soil management, we evaluate the impacts of composted poultry litter and cover crops on soil chemistry, bacterial communities and survival of Salmonella enterica and Listeria monocytogenes. We found that bacterial community composition strongly affected pathogen survival in soils. Specifically, organic soils managed with cover crops and composts hosted more macronutrients and bacterial communities that were better able to suppress Salmonella and Listeria. For example, after incubating soils for 10 days at 20°C, soils without composts retained fourfold to fivefold more Salmonella compared to compost-amended soils. However, treatment effects dissipated as bacterial communities converged over the growing season.ConclusionsOur results suggest that composts and cover crops may be used to build healthy soils without increasing foodborne pathogen survival.Significance and impact of the studyOur work suggests that animal-based composts do not promote pathogen survival and may even promote bacterial communities that suppress pathogens. Critically, proper composting techniques are known to reduce pathogen populations in biological soil amendments of animal origin, which can reduce the risks of introducing pathogens to farm fields in soil amendments. Thus, animal-based composts and cover crops may be a safe alternative to conventional fertilizers, both because of the known benefits of composts for soil health and because it may be possible to apply amendments in such a way that food-safety risks are mitigated rather than exacerbated.

Published

2021

3. Constraining nuclear matter parameters from correlation systematics:a mean-field perspective

Author

Agrawal, B. K., Malik, Tuhin, De, J. N., and Samaddar, S. K.

Subjects

Nuclear Theory, Astrophysics - High Energy Astrophysical Phenomena

Abstract

The nuclear matter parameters define the nuclear equation of state (EoS), they appear as coefficients of expansion around the saturation density of symmetric and asymmetric nuclear matter. We review their correlations with several properties of finite nuclei and of neutron stars within mean-field frameworks. The lower order nuclear matter parameters such as the binding energy per nucleon, incompressibility and the symmetry energy coefficients are found to be constrained in narrow limits through their strong ties with selective properties of finite nuclei. From the correlations of nuclear matter parameters with neutron star observables, we further review how precision knowledge of the radii and tidal deformability of neutron stars in the mass range $1 - 2 M_\odot$ may help cast them in narrower bounds. The higher order parameters such as the density slope and the curvature of the symmetry energy or the skewness of the symmetric nuclear matter EoS are, however, plagued with larger uncertainty. From inter-correlation of these higher order nuclear matter parameters with lower order ones, we explore how they can be brought to more harmonious bounds., Comment: to be appeared in EPJST

Published

2020

4. Tides in merging neutron stars: Consistency of the GW170817 event with experimental data on finite nuclei

Author

Malik, Tuhin, Agrawal, B. K., De, J. N., Samaddar, S. K., Providência, C., Mondal, C., and Jha, T. K.

Subjects

Nuclear Theory, General Relativity and Quantum Cosmology, High Energy Physics - Phenomenology

Abstract

The agreement of the nuclear equation of state (EoS) deduced from the GW170817 based tidal deformability with the one obtained from empirical data on microscopic nuclei is examined. It is found that suitably chosen experimental data on isoscalar and isovector modes of nuclear excitations together with the observed maximum neutron star mass constrain the EoS which displays a very good congruence with the GW170817 inspired one. The giant resonances in nuclei are found to be instrumental in limiting the tidal deformability parameter and the radius of neutron star in somewhat narrower bounds. At the 1$\sigma$ level, the values of the canonical tidal deformability $\Lambda_{1.4}$ and the neutron star radius $R_{1.4}$ come out to be $267\pm144$ and $11.6\pm1.0$ km, respectively., Comment: 6 pages, 3 figures

Published

2019

5. The nucleon effective mass and its isovector splitting

Author

Malik, Tuhin, Mondal, C., Agrawal, B. K., De, J. N., and Samaddar, S. K.

Subjects

Nuclear Theory

Abstract

Using an energy density functional (EDF) based on the thermodynamic Gibbs-Duhem relation, found equivalent to the standard Skyrme EDF for infinite nuclear matter, it is demonstrated that the parameters of this EDF are not uniquely determined from the fit of the empirical and theoretical data related to nuclear matter. This prevents an unambiguous determination of the nucleon effective mass ($\frac{m_0^*}{m}$) and its isovector splitting ($\Delta m_0^*$). Complementary information from dipole polarizability of atomic nuclei helps in removing this ambiguity and plausible values of $\frac{m_0^*}{m}$ and $\Delta m_0^*$ can be arrived at. Presently considered fit data on infinite nuclear matter and dipole polarizability of finite nuclei yield $\frac{m_0^*}{m} =0.68 \pm 0.04 $ and $\Delta m_0^* =(-0.20 \pm 0.09)\delta $. This EDF is consistent with the constraint on the maximum mass of the neutron star., Comment: 9 pages, 6 figures, accepted as a regular article in Phys. Rev. C

Published

2018

6. Correlations among symmetry energy elements in Skyrme models

Author

Mondal, C., Agrawal, B. K., De, J. N., and Samaddar, S. K.

Subjects

Nuclear Theory

Abstract

Motivated by the interrelationships found between the various symmetry energy elements of the energy density functionals (EDF) based on the Skyrme forces, possible correlations among them are explored. A total of 237 Skyrme EDFs are used for this purpose. As some of these EDFs yield values of a few nuclear observables far off from the present acceptable range, studies are done also with a subset of 162 EDFs that comply with a conservative set of constraints on the values of nuclear matter incompressibility coefficient, effective mass of the nucleon and the isovector splitting of effective nucleon masses to see the enhancement of the correlation strength, if any. The curvature parameter $K^0_{sym}$ and the skewness parameter $Q^0_{sym}$ of the symmetry energy are found to be very well correlated with the linear combination of the symmetry energy coefficient and its density derivative $L_0$ . The isovector splitting of the effective nucleon mass, however, displays a somewhat meaningful correlation with a linear combination of the symmetry energy, its slope and its curvature parameter., Comment: 8 pages, 3 figures, Accepted for publication in Int. Jour. of Mod. Phys. E

Published

2018

7. Interdependence of different symmetry energy elements

Author

Mondal, C., Agrawal, B. K., De, J. N., Samaddar, S. K., Centelles, M., and Viñas, X.

Subjects

Nuclear Theory

Abstract

Relations between the nuclear symmetry energy coefficient and its density derivatives are derived. The relations hold for a class of interactions with quadratic momentum dependence and a power-law density dependence. The structural connection between the different symmetry energy elements as obtained seems to be followed by almost all reasonable nuclear energy density functionals, both relativistic and non-relativistic, suggesting a universality in the correlation structure. This, coupled with known values of some well-accepted constants related to nuclear matter, helps in constraining values of different density derivatives of the nuclear symmetry energy shedding light on the isovector part of the nuclear interaction., Comment: 6 pages, 2 figures

Published

2017

8. Limiting symmetry energy elements from empirical evidence

Author

Agrawal, B. K., Samaddar, S. K., De, J. N., Mondal, C., and De, Subhranil

Subjects

Nuclear Theory

Abstract

In the framework of an equation of state (EoS) constructed from a momentum and density-dependent finite-range two-body effective interaction, the quantitative magnitudes of the different symmetry elements of infinite nuclear matter are explored. The parameters of this interaction are determined from well-accepted characteristic constants associated with homogeneous nuclear matter. The symmetry energy coefficient $a_2$, its density slope $L_0$, the symmetry incompressibility $K_\delta $ as well as the density dependent incompressibility $K(\rho )$ evaluated with this EoS are seen to be in good harmony with those obtained from other diverse perspectives. The higher order symmetry energy coefficients $a_4,~a_6$ etc are seen to be not very significant in the domain of densities relevant to finite nuclei, but gradually build up at supra-normal densities. The analysis carried with a Skyrme-inspired energy density functional obtained with the same input values for the empirical bulk data associated with nuclear matter yields nearly the same results., Comment: Accepted in "International journal of Modern Physics E"

Published

2017

9. Sensitivity of elements of the symmetry energy of nuclear matter to the properties of neutron-rich systems

Author

Mondal, C., Agrawal, B. K., De, J. N., and Samaddar, S. K.

Subjects

Nuclear Theory

Abstract

The sensitivity of nuclear symmetry energy elements at the saturation density to the binding energies of ultra neutron-rich nuclei (neutron to proton ratio $\sim$ 2) and the maximum mass of neutron star is explored within a relativistic mean field model. Values of the interaction parameters governing the isovector strengths and the symmetry elements are determined in tighter bounds. Assessments based on the sensitivity matrix reveal that the properties of extreme neutron-rich systems play a predominant role in narrowing down the uncertainties in the various symmetry energy parameters. The calculations are extended over a wide range of nuclear matter density and the results are discussed., Comment: 9 pages, 7 figures (Accepted in Physical Review C)

Published

2016

10. Charge Puddles in Graphene Near the Dirac Point

Author

Samaddar, S., Yudhistira, I., Adam, S., Courtois, H., and Winkelmann, C. B.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

The charge carrier density in graphene on a dielectric substrate such as SiO$_2$ displays inhomogeneities, the so-called charge puddles. Because of the linear dispersion relation in monolayer graphene, the puddles are predicted to grow near charge neutrality, a markedly distinct property from conventional two-dimensional electron gases. By performing scanning tunneling microscopy/spectroscopy on a mesoscopic graphene device, we directly observe the puddles' growth, both in spatial extent and in amplitude, as the Dirac point is approached. Self-consistent screening theory provides a unified description of both the macroscopic transport properties and the microscopically observed charge disorder.

Published

2015

11. Reassessing nuclear matter incompressibility and its density dependence

Author

De, J. N., Samaddar, S. K., and Agrawal, B. K.

Subjects

Nuclear Theory

Abstract

Experimental giant monopole resonance energies are now known to constrain nuclear incompressibility of symmetric nuclear matter $K$ and its density slope $M$ at a particular value of sub-saturation density, the crossing density $\rho_c$. Consistent with these constraints, we propose a reasonable way to construct a plausible equation of state of symmetric nuclear matter in a broad density region around the saturation density $\rho_0$. Help of two additional empirical inputs, the value of $\rho_0$ and that of the energy per nucleon $e(\rho_0)$ are needed. The value of $K(\rho_0)$ comes out to be $211.9\pm 24.5$ MeV., Comment: 5 page including 4 figures. Phys. Rev. C (in press)

Published

2015

12. Constraining nuclear matter parameters from correlation systematics: a mean-field perspective

Author

Agrawal, B. K., Malik, Tuhin, De, J. N., and Samaddar, S. K.

Published

2021

13. Ionization and Electron Capture Cross Sections for Single-Electron Removal from Biological Molecules by Swift Ion

Author

Purkait, K., Samaddar, S., Jana, D., and Purkait, M.

Published

2021

14. Equation of state of nuclear matter from empirical constraints

Author

Alam, N., Agrawal, B. K., De, J. N., Samaddar, S. K., and Colò, G.

Subjects

Nuclear Theory

Abstract

From empirically determined values of some of the characteristic constants associated with homogeneous nuclear matter at saturation and sub-saturation densities, within the framework of a Skyrme-inspired energy density functional, we construct an equation of state (EoS) of nuclear matter.This EoS is then used to predict values of density slope parameters of symmetry energy $L(\rho)$, isoscalar incompressibility $K(\rho)$ and a few related quantities. The close consonance of our predicted values with the currently available ones for the density dependence of symmetry energy and incompressibility gleaned from diverse approaches offers the possibility that our method may help in settling their values in tighter bounds. Extrapolation of our EoS at supranormal densities shows that it is in good harmony with the one extracted from experimental data., Comment: 8 pages including 4 figures, Phys. Rev. C (accepted)

Published

2014

15. Thermal properties of the nuclear surface

Author

Agrawal, B. K., Bandyopadhyay, D., De, J. N., and Samaddar, S. K.

Subjects

Nuclear Theory

Abstract

The thermal evolution of a few thermodynamic properties of the nuclear surface like its thermodynamic potential energy, entropy and the symmetry free energy are examined for both semi-infinite nuclear matter and finite nuclei. The Thomas-Fermi model is employed. Three Skyrme interactions, namely, SkM$^*$, SLy4 and SK255 are used for the calculations to gauge the dependence of the nuclear surface properties on the energy density functionals. For finite nuclei, the surface observables are computed from a global liquid-drop inspired fit of the energies and free energies of a host of nuclei covering the entire periodic table. The hot nuclear system is modelled in a subtracted Thomas-Fermi framework. Compared to semi-infinite nuclear matter, substantial changes in the surface symmetry energy of finite nuclei are indicated; surface thermodynamic potential energies for the two systems are, however, not too different. Analytic expressions to fit the temperature and asymmetry dependence of the surface thermodynamic potential of semi-infinite nuclear matter and the temperature dependence of the surface free energy of finite nuclei are given., Comment: 10 pages including 8 figures. Phys. Rev. C (accepted, in press)

Published

2014

16. Development And In Vitro Characterization Of Bladder Tumor Cell Targeted Lipid-Coated Polyplex For Dual Delivery Of Plasmids And Small Molecules

Author

Samaddar S, Mazur J, Boehm D, and Thompson DH

Subjects

dual delivery, bladder cancer, gene therapy, Medicine (General), R5-920

Abstract

Shayak Samaddar, Joshua Mazur, Devin Boehm, David H Thompson Department of Chemistry, Purdue University, Bindley Bioscience Center, West Lafayette, Indiana 47906, USACorrespondence: David H ThompsonDepartment of Chemistry, Purdue University, Bindley Bioscience Center, 1203 W. State St., West Lafayette, Indiana 47906, USATel +1 765-494-0386Email davethom@purdue.eduBackground: Bladder cancer is the fourth most common cancer in men and eleventh most common in women. Combination therapy using a gene and chemotherapeutic drug is a potentially useful strategy for treating bladder cancer in cases where a synergistic benefit can be achieved successfully. This approach relies on developing drug combinations using carrier systems that can load both hydrophilic genes and hydrophobic drugs. Ideally, the formulation for carrier system should be free of traditional high shear techniques such as sonication and extrusion to reduce shear-induced nucleic acid strand breakage. Moreover, the system should be able to protect the nucleic acid from enzymatic attack and deliver it specifically to the tumor site.Materials and methods: A dual payload carrier system that was formulated using a simple flow mixing technique to complex anionic plasmid (EGFP-NLS) using a cationic polymer (CD-PEI2.5kD) followed by coating of the polyplex using lipid membranes. The resulting lipid-coated polyplex (LCP) formulations are targeted to bladder cancer cells by employing a bacterial adhesive peptide sequence, RWFV, that targets the LCP to the tumor stroma for efficiently delivering reporter plasmid, EGFP-NLS and a model small molecule drug, pyrene, to the cancer cells.Results: Encapsulation efficiency of the peptide targeted carrier for the plasmid was 50% ± 0.4% and for pyrene it was 16% ± 0.4%. The ability of the targeted LCP to transfect murine bladder cancer cells was 4-fold higher than LCP bearing a scrambled peptide sequence. Fluorescence of cells due to pyrene delivery was highest after 4 hrs using targeted LCP. Finally, we loaded the peptide targeted LCP with anti-cancer agent, curcumin. The targeted formulation of curcumin resulted in only 45% viable cancer cells at a concentration of 5 μg/mL, whereas the empty and non-targeted formulations did not result any significant cell death.Conclusion: These results demonstrate the specificity of the targeting peptide sequence in engaging tumor cells and the utility of the developed carrier platform to deliver a dual payload to bladder tumor cells.Keywords: dual delivery, bladder cancer, gene therapy

Published

2019

17. Electron emission cross sections for collisions of heavy ions with atomic targets

Author

Purkait, K., Samaddar, S., Halder, S., Mandal, C. R., and Purkait, M.

Published

2020

18. Effect of Projectile Charge State on Electron Emission Spectra from He Atom

Author

Halder, S., Samaddar, S., Purkait, K., and Purkait, M.

Published

2020

19. Two-center interference effects for single electron capture in fast ion-molecule collisions

Author

Halder, S., Samaddar, S., Purkait, K., Mandal, C. R., and Purkait, M.

Published

2020

20. Symmetry energy of warm nuclear systems

Author

Agrawal, B. K., De, J. N., Samaddar, S. K., Centelles, M., and Viñas, X.

Subjects

Nuclear Theory

Abstract

The temperature dependence of the symmetry energy and symmetry free energy coefficients of infinite nuclear matter and of finite nuclei is investigated. For infinite matter, both these coefficients are found to have a weaker dependence on temperature at densities close to saturation; at low but homogeneous densities, the temperature dependence becomes stronger. For finite systems, different definitions of symmetry energy coefficients are encountered in the literature yielding different values. A resolution to this problem is suggested from a global liquid-drop-inspired fit of the energies and free energies of a host of nuclei covering the entire periodic table. The hot nucleus is modeled in a subtracted finite-temperature-Thomas-Fermi framework, with dynamical surface phonon coupling to nucleonic motion plugged in. Contrary to infinite nuclear matter, a substantial change in the symmetry energy coefficients is observed for finite nuclei with temperature., Comment: 12 pages, including 11 figures, appearing in special issue of EPJ-A on Nuclear Symmetry Energy

Published

2013

21. Constraining the density dependence of symmetry energy from nuclear masses

Author

Agrawal, B. K., De, J. N., Samaddar, S. K., Colo, G., and Sulaksono, A.

Subjects

Nuclear Theory, Astrophysics - High Energy Astrophysical Phenomena

Abstract

Empirically determined values of the nuclear volume and surface symmetry energy coefficients from nuclear masses are expressed in terms of density distributions of nucleons in heavy nuclei in the local density approximation. This is then used to extract the value of the symmetry energy slope parameter $L$. The density distributions in both spherical and well deformed nuclei calculated within microscopic framework with different energy density functionals give $L = 59.0 \pm 13.0$ MeV. Application of the method also helps in a precision determination of the neutron skin thickness of nuclei that are difficult to measure accurately., Comment: 6 pages including 3 figures, accepted in Phys. Rev. C (Rapid Comm.)

Published

2013

22. Niobium-based superconducting nano-devices fabrication using all-metal suspended masks

Author

Samaddar, S., van Zanten, D., Fay, A., Sacépé, B., Courtois, H., and Winkelmann, C. B.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

We report a novel method for the fabrication of superconducting nanodevices based on niobium. The well-known difficulties of lithographic patterning of high-quality niobium are overcome by replacing the usual organic resist mask by a metallic one. The quality of the fabrication procedure is demonstrated by the realization and characterization of long and narrow superconducting lines and niobium-gold-niobium proximity SQUIDs.

Published

2013

23. Ripples and Charge Puddles in Graphene on a Metallic Substrate

Author

Martin, S. C., Samaddar, S., Sacépé, B., Kimouche, A., Coraux, J., Fuchs, F., Grévin, B., Courtois, H., and Winkelmann, C. B.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

Graphene on a dielectric substrate exhibits spatial doping inhomogeneities, forming electron-hole puddles. Understanding and controlling the latter is of crucial importance for unraveling many of graphene's fundamental properties at the Dirac point. Here we show the coexistence and correlation of charge puddles and topographic ripples in graphene decoupled from the metallic substrate it was grown on. The analysis of interferences of Dirac fermion-like electrons yields a linear dispersion relation, indicating that graphene on a metal can recover its intrinsic electronic properties., Comment: 4 figures

Published

2013

24. Determining the density content of symmetry energy and neutron skin: an empirical approach

Author

Agrawal, B. K., De, J. N., and Samaddar, S. K.

Subjects

Nuclear Theory, Astrophysics - High Energy Astrophysical Phenomena, Nuclear Experiment

Abstract

The density dependence of nuclear symmetry energy remains poorly constrained. Starting from precise empirical values of the nuclear volume and surface symmetry energy coefficients and the nuclear saturation density, we show how in the ambit of microscopic calculations with different energy density functionals, the value of the symmetry energy slope parameter $L$ alongwith that for neutron skin can be put in tighter bounds. The value of $L$ is found to be $L$= 64$\pm $5 MeV. For $^{208}$Pb, the neutron skin thickness comes out to be 0.188 $\pm $0.014 fm. Knowing $L$, the method can be applied to predict neutron skins of other nuclei., Comment: 5 pages, Phys. Rev. Lett. (accpeted)

Published

2012

25. Temperature dependence of volume and surface symmetry energy coefficients of nucle

Author

De, J. N., Samaddar, S. K., and Agrawal, B. K.

Subjects

Nuclear Theory

Abstract

The thermal evolution of the energies and free energies of a set of spherical and near-spherical nuclei spanning the whole periodic table are calculated in the subtracted finite-temperature Thomas- Fermi framework with the zero-range Skyrme-type KDE0 and the finite-range modified Seyler-Blanchard interaction. The calculated energies are subjected to a global fit in the spirit of the liquid-drop model. The extracted parameters in this model reflect the temperature dependence of the volume symmetry and surface symmetry coefficients of finite nuclei, in addition to that of the volume and surface energy coefficients. The temperature dependence of the surface symmetry energy is found to be very substantial whereas that of the volume symmetry energy turns out to be comparatively mild., Comment: 6 page including 5 figures, Phys. Lett. B (in press)

Published

2012

26. The effects of medium on nuclear properties in multifragmentation

Author

De, J. N., Samaddar, S. K., Viñas, X., Centelles, M., Mishustin, I. N., and Greiner, W.

Subjects

Nuclear Theory

Abstract

In multifragmentation of hot nuclear matter, properties of fragments embedded in a soup of nucleonic gas and other fragments should be modified as compared with isolated nuclei. Such modifications are studied within a simple model where only nucleons and one kind of heavy nuclei are considered. The interaction between different species is described with a momentum-dependent two-body potential whose parameters are fitted to reproduce properties of cold isolated nuclei. The internal energy of heavy fragments is parametrized according to a liquid-drop model with density and temperature dependent parameters. Calculations are carried out for several subnuclear densities and moderate temperatures, for isospin-symmetric and asymmetric systems. We find that the fragments get stretched due to interactions with the medium and their binding energies decrease with increasing temperature and density of nuclear matter., Comment: 12 pages, 11 figures, Phys. Rev.C (in press)

Published

2012

27. Temperature dependence of symmetry energy of finite nuclei

Author

De, J. N. and Samaddar, S. K.

Subjects

Nuclear Theory

Abstract

The temperature dependence of the symmetry energy and the symmetry free energy coefficients of atomic nuclei is investigated in a finite temperature Thomas-Fermi framework employing the subtraction procedure. A substantial decrement in the symmetry energy coefficient is obtained for finite systems,contrary to those seen for infinite nuclear matter at normal and somewhat subnormal densities. The effect of the coupling of the surface phonons to the nucleonic motion is also considered; this is found to decrease the symmetry energies somewhat at low temperatures., Comment: 9 pages including 8 figures; accepted for publication in Phys. Rev. C

Published

2012

28. Warm alpha-nucleon matter

Author

Samaddar, S. K. and De, J. N.

Subjects

Nuclear Theory

Abstract

The properties of warm dilute alpha-nucleon matter are studied in a variational approach in the Thomas-Fermi approximation starting from an effective two-body nucleon-nucleon interaction. The equation of state, symmetry energy, incompressibility of the said matter as well as the alpha fraction are in consonance with those evaluated from the virial approach that sets a bench-mark for such calculations at low densities., Comment: 10 pages, 10 figures, Phys. Rev C (in press)

Published

2011

29. Anatomy of symmetry energy of dilute nuclear matter

Author

De, J. N., Samaddar, S. K., and Agrawal, B. K.

Subjects

Nuclear Theory

Abstract

The symmetry energy coefficients of dilute clusterized nuclear matter are evaluated in the $S$-matrix framework. Employing a few different definitions commonly used in the literature for uniform nuclear matter, it is seen that the different definitions lead to perceptibly different results for the symmetry coefficients for dilute nuclear matter. They are found to be higher compared to those obtained for uniform matter in the low density domain. The calculated results are in reasonable consonance with those extracted recently from experimental data., Comment: 11 pages, 9 figures, Accepted in Phys. Rev. C

Published

2010

30. The efficacy of isotope thermometry: examining in the S-matrix approach

Author

Samaddar, S. K. and De, J. N.

Subjects

Nuclear Theory

Abstract

Isotope thermometry, widely used to measure the temperature of a hot nuclear system formed in energetic nuclear collisions, is examined in the light of S-matrix approach to the nuclear equation of state of disassembled nuclear matter. Scattering between produced light fragment pairs, hitherto neglected, is seen to have an important bearing on the extraction of system temperature and volume at freeze-out from isotope thermometry. Taking due care of the scattering effects and decay of the primary fragments, a more reliable way to extract the nuclear thermodynamic parameters is suggested by exploiting least-squares fit to the observed fragment multiplicities., Comment: 4 pages, 2 figures

Published

2009

31. Symmetry coefficients and incompressibility of clusterized supernova matter

Author

Samaddar, S. K., De, J. N., Vinas, X., and Centelles, M.

Subjects

Nuclear Theory, Astrophysics - Solar and Stellar Astrophysics

Abstract

The symmetry energy coefficients, incompressibility, and single-particle and isovector potentials of clusterized dilute nuclear matter are calculated at different temperatures employing the $S$-matrix approach to the evaluation of the equation of state. Calculations have been extended to understand the aforesaid properties of homogeneous and clusterized supernova matter in the subnuclear density region. Comparison of the results in the $S$-matrix and mean-field approach reveals some subtle differences in the density and temperature region we explore., Comment: 9 pages + 12 figures

Published

2009

32. Scattering effects on nuclear thermodynamic observables

Author

Samaddar, S. K. and De, J. N.

Subjects

Nuclear Theory

Abstract

The nuclear thermodynamic observables like the temperature, volume and the specific heat as obtained from isotopic ratios in hot disassembled nuclear matter are examined in the light of the S-matrix approach to the nuclear equation of state. The values of the observables, as extracted without inclusion of scattering effects are found to be modified appreciably in some cases when scattering between the fragment species is taken care of., Comment: 5 pages, 5 figures, Minor modifications in text and figures. Phys. Rev. C (Rapid Communication, in press)

Published

2009

33. Fully differential cross sections for single ionization of helium by proton impact

Author

Jana, D., Samaddar, S., Purkait, K., and Purkait, M.

Published

2021

34. Nuclear condensation and symmetry energy of dilute nuclear matter: an S-matrix approach

Author

De, J. N. and Samaddar, S. K.

Subjects

Nuclear Theory

Abstract

Based on the general analysis of the grand canonical partition function in the S-matrix framework, the calculated results on symmetry energy, free energy and entropy of dilute warm nuclear matter are presented. At a given temperature and density, the symmetry energy or symmetry free energy of the clusterized nuclear matter in the S-matrix formulation deviates, particularly at low temperature and relatively higher density, in a subtle way, from the linear dependence on the square of the isospin asymmetry parameter $X=(\rho_n-\rho_p)/(\rho_n+\rho_p)$, contrary to those obtained for homogeneous nucleonic matter. The symmetry coefficients, in the conventional definition, can then be even negative. The symmetry entropy similarly shows a very different behavior., Comment: 8 pages, 6 figures. PRC (in press)

Published

2008

35. Density dependence of symmetry free energy of hot nuclei

Author

Samaddar, S. K., De, J. N., Vinas, X., and Centelles, M.

Subjects

Nuclear Theory

Abstract

The density and excitation energy dependence of symmetry energy and symmetry free energy for finite nuclei are calculated microscopically in a microcanonical framework taking into account thermal and expansion effects. A finite-range momentum and density dependent two-body effective interaction is employed for this purpose. The role of mass, isospin and equation of state (EoS) on these quantities is also investigated; our calculated results are in consonance with the available experimental data., Comment: 20 pages, 8 figures, revtex4; modifications in text and figures

Published

2008

36. S-matrix approach to equation of state of nuclear matter

Author

Mallik, S., De, J. N., Samaddar, S. K., and Sarkar, Sourav

Subjects

Nuclear Theory

Abstract

We calculate the equation of state of nuclear matter based on the general analysis of the grand canonical partition function in the $S$-matrix framework. In addition to the low mass stable particles and their two-body scattering channels considered earlier, the calculation includes systematically all the higher mass particles and their exited states as well as the scattering channels formed by any number of these species. We estimate the latter contribution by resonances in all the channels. The resulting model-independent virial series for pressure gets substantial contribution from the heavy particles and the channels containing them. The series converges for larger values of baryon density than found earlier., Comment: Version to appear in PRC, Rapid Communications

Published

2008

37. List of contributors

Author

Alhallak, Kinan, primary, Allen, Sean David, additional, Amiji, Mansoor, additional, Atrian, Farzaneh, additional, Azab, Abdel Kareem, additional, Bae, You Han, additional, Barrios-Esteban, Sheila, additional, Barroso, Margarida, additional, Beringhs, André O’Reilly, additional, Bossmann, Stefan H., additional, Byun, Junho, additional, Corpstein, Clairissa D., additional, Cravo, Ana Santos, additional, Csaba, Noemi, additional, Du, Guangsheng, additional, Faulkner, Denzel E., additional, Gao, Wei, additional, Garcia-Fuentes, Marcos, additional, Garcia-Mazas, Carla, additional, Han, Bumsoo, additional, Hu, Jun, additional, Intes, Xavier, additional, Kim, Dongyoon, additional, Kim, In-San, additional, Kim, Kyoung Sub, additional, Kwon, Soonbum, additional, Le, Quoc-Viet, additional, Lee, Hong Jae, additional, Lee, Sang Cheon, additional, Lelièvre, Sophie A., additional, Li, Tonglei, additional, Libring, Sarah, additional, Lu, Xiuling, additional, Meng, Fanfei, additional, Min, Kyung Hyun, additional, Moon, Hye-ran, additional, Mrsny, Randall, additional, Muz, Barbara, additional, Nam, Gi-Hoon, additional, Needham, David, additional, Oh, Yu-Kyoung, additional, Park, Jinwon, additional, Rudkouskaya, Alena, additional, Sadabad, Raana Kashfi, additional, Samaddar, S., additional, Scott, Evan Alexander, additional, Shim, Gayong, additional, Singh, Amit, additional, Sinsuebphon, Nattawut, additional, Solorio, Luis, additional, Sun, Jennifer, additional, Sun, Xun, additional, Teusch, Nicole, additional, Thompson, D.H., additional, Wang, Jianping, additional, Xie, Bailu, additional, Yang, Yoosoo, additional, Yeo, Yoon, additional, and Zeineldin, R., additional

Published

2020

38. Nucleic acid anticancer agents

Author

Samaddar, S., primary and Thompson, D.H., additional

Published

2020

39. Nuclear condensation and the equation of state of nuclear matter

Author

De, J. N. and Samaddar, S. K.

Subjects

Nuclear Theory

Abstract

The isothermal compression of a dilute nucleonic gas invoking cluster degrees of freedom is studied in an equilibrium statistical model; this clusterized system is found to be more stable than the pure nucleonic system. The equation of state (EoS) of this matter shows features qualitatively very similar to the one obtained from pure nucleonic gas. In the isothermal compression process, there is a sudden enhancement of clusterization at a transition density rendering features analogous to the gas-liquid phase transition in normal dilute nucleonic matter. Different observables like the caloric curves, heat capacity, isospin distillation, etc. are studied in both the models. Possible changes in the observables due to recently indicated medium modifications in the symmetry energy are also investigated., Comment: 18 pages and 11 figures. Phys. Rev. C (in press)

Published

2007

40. Excitation energy dependence of symmetry energy of finite nuclei

Author

Samaddar, S. K., De, J. N., Vinas, X., and Centelles, M.

Subjects

Nuclear Theory

Abstract

A finite range density and momentum dependent effective interaction is used to calculate the density and temperature dependence of the symmetry energy coefficient Csym(rho,T) of infinite nuclear matter. This symmetry energy is then used in the local density approximation to evaluate the excitation energy dependence of the symmetry energy coefficient of finite nuclei in a microcanonical formulation that accounts for thermal and expansion effects. The results are in good harmony with the recently reported experimental data from energetic nucleus-nucleus collisions., Comment: 11 pages, 3 figures, revtex4; minor changes in text, axis label in figure 1 corrected

Published

2007

41. Density reorganization in hot nuclei

Author

Samaddar, S. K., De, J. N., Vinas, X., and Centelles, M.

Subjects

Nuclear Theory

Abstract

The density profile of a hot nuclear system produced in intermediate energy heavy ion collisions is studied in a microcanonical formulation with a momentum and density dependent finite range interaction. The caloric curve and the density evolution with excitation are calculated for a number of systems for the equilibrium mononuclear configuration; they compare favorably with the recent experimental data. The studied density fluctuations are seen to build up rapidly beyond an excitation energy of 8 MeV/u indicating the instability of the system towards nuclear disassembly. Explicit introduction of deformation in the expansion path of the heated nucleus, however, shows that the system might fragment even earlier. We also explore the effects of the nuclear equation of state and of the mass and isospin asymmetry on the nuclear equilibrium configuration and the relevant experimental observables., Comment: 20 pages, 12 figures, revtex4

Published

2007

42. Continuous phase transition and negative specific heat in finite nuclei

Author

De, J. N., Samaddar, S. K., Shlomo, S., and Natowitz, J. B.

Subjects

Nuclear Theory

Abstract

The liquid-gas phase transition in finite nuclei is studied in a heated liquid-drop model where the nuclear drop is assumed to be in thermodynamic equilibrium with its own evaporated nucleonic vapor conserving the total baryon number and isospin of the system. It is found that in the liquid-vapor coexistence region the pressure is not a constant on an isotherm indicating that the transition is continuous. At constant pressure, the caloric curve shows some anomalies, namely, the systems studied exhibit negative heat capacity in a small temperature domain. The dependence of this specific feature on the mass and isospin of the nucleus, Coulomb interaction and the chosen pressure is studied. The effects of the presence of clusters in the vapor phase on specific heat have also been explored., Comment: 18 pages, 13 figures; Phys. Rev. C (in press)

Published

2006

43. Nuclear expansion with excitation

Author

De, J. N., Samaddar, S. K., Vinas, X., and Centelles, M.

Subjects

Nuclear Theory

Abstract

The expansion of an isolated hot spherical nucleus with excitation energy and its caloric curve are studied in a thermodynamic model with the SkM* force as the nuclear effective two-body interaction. The calculated results are shown to compare well with the recent experimental data from energetic nuclear collisions. The fluctuations in temperature and density are also studied. They are seen to build up very rapidly beyond an excitation energy of 9 MeV/u. Volume-conserving quadrupole deformation in addition to expansion indicates, however, nuclear disassembly above an excitation energy of 4 MeV/u, Comment: 17 pages, 5 figures, revtex4; calculations with deformation added

Published

2005

44. Flow effects on multifragmentation in the canonical model

Author

Samaddar, S. K., De, J. N., and Shlomo, S.

Subjects

Nuclear Theory

Abstract

A prescription to incorporate the effects of nuclear flow on the process of multifragmentation of hot nuclei is proposed in an analytically solvable canonical model. Flow is simulated by the action of an effective negative external pressure. It favors sharpening the signatures of liquid-gas phase transition in finite nuclei with increased multiplicity and a lowered phase transition temperature., Comment: 13 pages, 5 Post Script figures (accepted for publication in PRC)

Published

2004

45. Ambiguities in statistical calculations of nuclear fragmentation

Author

Samaddar, S. K., De, J. N., and Bonasera, A.

Subjects

Nuclear Theory

Abstract

The concept of freeze out volume used in many statistical approaches for disassembly of hot nuclei leads to ambiguities. The fragmentation pattern and the momentum distribution (temperature) of the emanated fragments are determined by the phase space at the freeze-out volume where the interaction among the fragments is supposedly frozen out. However, to get coherence with the experimental momentum distribution of the charged particles, one introduces Coulomb acceleration beyond this freeze-out. To be consistent, we investigate the effect of the attractive nuclear force beyond this volume and find that the possible recombination of the fragments alters the physical observables significantly casting doubt on the consistency of the statistical model., Comment: 11 pages+3 figures

Published

2004

46. Single-Capture Cross Sections from Biological Molecules and Noble Gases by Bare Ion Impact

Author

Purkait, K., Samaddar, S., Halder, S., Mandal, C. R., and Purkait, M.

Published

2019

47. Liquid-gas phase transition and its order in finite nuclei

Author

Sil, Tapas, Samaddar, S. K., De, J. N., and Shlomo, S.

Subjects

Nuclear Theory

Abstract

The liquid-gas phase transition in finite nuclei is studied in a heated liquid-drop model where the drop is assumed to be in thermodynamic equilibrium with the vapour emanated from it. Changing pressure along the liquid-gas coexistence line of the systems, symmetric or asymmetric, suggests that the phase transition is a continuous one. This is further corroborated from the study of the thermal evolution of the entropy at constant pressure., Comment: 11 pages (ReVTeX), 4 figures (PS); Submitted to Phys. Rev. C

Published

2002

48. Isospin-rich nuclei in neutron star matter

Author

Sil, Tapas, De, J. N., Samaddar, S. K., Vinas, X., Centelles, M., Agrawal, B. K., and Patra, S. K.

Subjects

Nuclear Theory

Abstract

Stability of nuclei beyond the drip lines in the presence of an enveloping gas of nucleons and electrons, as prevailing in the inner crust of a neutron star, is studied in the temperature-dependent Thomas-Fermi framework. A limiting asymmetry in the isospin space beyond which nuclei cannot exist emerges from the calculations. The ambient conditions like temperature, baryon density and neutrino concentration under which these exotic nuclear systems can be formed are studied in some detail., Comment: Submitted to Phy. Rev. C: Revtex version of manuscript 22 pages and 10 PS-files for figures

Published

2002

49. Relativistic mean-field study of light nuclei near drip line

Author

Agrawal, B. K., Sil, Tapas, Samaddar, S. K., and De, J. N.

Subjects

Nuclear Theory

Abstract

The relativistic mean field theory is applied to study some exotic properties of neutron rich nuclei as recently observed, namely, extension of the drip-line for $F$ nuclei from $^{29}F$ to $^{31}F$ and the appearence of a new shell closure at neutron number N=16. We find $^{31}F$ to be bound against one-neutron dripping but unbound only marginally for two neutron separation. The calculated functional dependence of one-neutron separation energy with neutron number for different values of $T_Z = (N-Z)/2$ signals a new shell closure at N=16 for neutron rich nuclei with $T_Z\ge 3$. This is further corroborated from the study of the deformation and the gap across the Fermi surface in these light nuclei., Comment: 15 pages of text and 11 figures

Published

2001

50. Temperature induced shell effects in deformed nuclei

Author

Agrawal, B. K., Sil, Tapas, Samaddar, S. K., and De, J. N.

Subjects

Nuclear Theory

Abstract

The thermal evolution of the shell correction energy is investigated for deformed nuclei using Strutinsky prescription in a self-consistent relativistic mean-field framework. For temperature independent single-particle states corresponding to either spherical or deformed nuclear shapes, the shell correction energy $\Delta_{sc}$ steadily washes out with temperature. However, for states pertaining to the self-consistent thermally evolving shapes of deformed nuclei, the dual role played by the single-particle occupancies in diluting the fluctuation effects from the single-particle spectra and in driving the system towards a smaller deformation is crucial in determining $\Delta_{sc}$ at moderate temperatures. In rare earth nuclei, it is found that $\Delta_{sc}$ builds up strongly around the shape transition temperature; for lighter deformed nuclei like $^{64}Zn$ and $^{66}Zn$, this is relatively less prominent., Comment: 6 pages revtex file + 4 ps files for figures, Phys. Rev. C (in press)

Published

2001