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NSR database version of April 11, 2024.

Search: Author = M.V.Zverev

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2012PA33      Phys.Rev. C 86, 045804 (2012)

S.S.Pankratov, M.Baldo, M.V.Zverev

Different scenarios of topological phase transitions in homogeneous neutron matter

doi: 10.1103/PhysRevC.86.045804
Citations: PlumX Metrics

2011PA21      Phys.Rev. C 84, 014321 (2011)

S.S.Pankratov, M.V.Zverev, M.Baldo, U.Lombardo, E.E.Saperstein

Semi-microscopic model of pairing in nuclei

NUCLEAR STRUCTURE ⁴⁴Ca, ^{106,108,110,112,114,116,118,120,122,124,126,128}Sn, ^{182,184,186,188,190,192,194,196,198,200,202,204}Pb; calculated neutron pairing gap, mass difference versus the average gap. ¹³⁶Xe, ¹³⁸Ba, ¹⁴⁰Ce, ¹⁴²Nd, ¹⁴⁴Sm, ¹⁴⁶Gd, ¹⁴⁸Dy, ¹⁵⁰Er, ¹⁵²Yb; calculated proton pairing gap. ^114,116Sn; calculated spectra. ^{110,112,114,116,118,120,122,124,126,128,130,132}Sn; calculated position of h_11/2 orbital. Comparison with experimental data. Semi-microscopic model with ab initio BCS gap equation, the Argonne v18 force and the self-consistent energy density functional method.

doi: 10.1103/PhysRevC.84.014321
Citations: PlumX Metrics

2011SA58      Phys.Atomic Nuclei 74, 1644 (2011)

E.E.Saperstein, M.Baldo, U.Lombardo, S.S.Pankratov, M.V.Zverev

On limits of ab initio calculations of pairing gap in nuclei

NUCLEAR STRUCTURE ^{182,184,186,188,190,192,194,196,198,200,202,204}Pb, ^{106,108,110,112,114,116,118,120,122,124,126,128}Sn, ⁴⁴Ca, ¹³⁶Xe, ¹³⁸Ba, ¹⁴⁰Ce, ¹⁴²Nd, ¹⁴⁴Sm, ¹⁴⁶Gd, ¹⁴⁸Dy, ¹⁵⁰Er, ¹⁵²Yb; calculated neutron and proton gaps. Semi-microscopic model.

doi: 10.1134/S1063778811110172
Citations: PlumX Metrics

2010PA22      JETP Lett. 92, 75 (2010); Pisma Zh.Eksp.Teor.Fiz. 92, 79 (2010)

S.S.Pankratov, M.Baldo, M.V.Zverev, U.Lombardo, E.E.Saperstein

Semi-microscopic model for the effective pairing interaction in atomic nuclei

NUCLEAR STRUCTURE ⁴⁴Ca, ^{106,108,110,112,114,116,118,120,122,124,126}Sn, ¹³⁶Xe, ¹³⁸Ba, ¹⁴⁰Ce, ¹⁴²Nd, ¹⁴⁴Sm, ¹⁴⁶Gd, ¹⁴⁸Dy, ¹⁵⁰Er, ¹⁵²Yb, ^{182,184,186,188,190,192,194,196,198,200,202,204}Pb; calculated neutron and proton gaps; deduced semi-microscopic model.

doi: 10.1134/S0021364010140018
Citations: PlumX Metrics

2009PA06      Phys.Rev. C 79, 024309 (2009)

S.S.Pankratov, E.E.Saperstein, M.V.Zverev, M.Baldo, U.Lombardo

Spatial correlation properties of the anomalous density matrix in a slab of nuclear matter with realistic NN forces

doi: 10.1103/PhysRevC.79.024309
Citations: PlumX Metrics

2009PA45      JETP Lett. 90, 560 (2009); Pisma Zh.Eksp.Teor.Fiz. 90, 612 (2009)

S.S.Pankratov, M.Baldo, M.V.Zverev, U.Lombardo, E.E.Saperstein, S.V.Tolokonnikov

On the ab initio calculation of a pairing gap in atomic nuclei

doi: 10.1134/S0021364009200028
Citations: PlumX Metrics

2008PA25      Nucl.Phys. A811, 127 (2008)

S.S.Pankratov, M.Baldo, U.Lombardo, E.E.Saperstein, M.V.Zverev

The microscopic pairing gap in a slab of nuclear matter for the Argonne v₁₈ NN-potential

doi: 10.1016/j.nuclphysa.2007.07.002
Citations: PlumX Metrics

2007PA23      Phys.Atomic Nuclei 70, 658 (2007); Yad.Fiz. 70, 688 (2007)

S.S.Pankratov, M.Baldo, U.Lombardo, E.E.Saperstein, M.V.Zverev

Effective Pairing Interaction for the Argonne Nucleon-Nucleon Potential v₁₈

doi: 10.1134/S1063778807040060
Citations: PlumX Metrics

2006PA02      Nucl.Phys. A765, 61 (2006)

S.S.Pankratov, M.Baldo, U.Lombardo, E.E.Saperstein, M.V.Zverev

Solution of the microscopic gap equation for a slab of nuclear matter with the Paris N N-potential

doi: 10.1016/j.nuclphysa.2005.10.010
Citations: PlumX Metrics

2006PA41      Phys.Atomic Nuclei 69, 2009 (2006); Yad.Fiz. 69, 2052 (2006)

S.S.Pankratov, E.E.Saperstein, M.V.Zverev

Chemical-Potential Dependence of the Pairing Gap in a Nuclear-Matter Slab

doi: 10.1134/S1063778806120040
Citations: PlumX Metrics

2004BA06      Phys.Rep. 391, 261 (2004)

M.Baldo, U.Lombardo, E.E.Saperstein, M.V.Zverev

On the surface nature of the nuclear pairing

doi: 10.1016/j.physrep.2003.10.007
Citations: PlumX Metrics

2004KH14      Phys.Rev.Lett. 93, 151101 (2004)

V.A.Khodel, J.W.Clark, M.Takano, M.V.Zverev

Phase Transitions in Nucleonic Matter and Neutron-Star Cooling

doi: 10.1103/PhysRevLett.93.151101
Citations: PlumX Metrics

2003BA16      Yad.Fiz. 66, 257 (2003); Phys.Atomic Nuclei 66, 233 (2003)

M.Baldo, U.Lombardo, E.E.Saperstein, M.V.Zverev

Energy Dependence of Effective Nucleon-Nucleon Interaction and Position of the Nucleon Drip Line

NUCLEAR STRUCTURE Sn; calculated two-neutron separation energy for even-mass isotopes. Semimicroscopic calculation.

doi: 10.1134/1.1553494
Citations: PlumX Metrics

2003BA88      Eur.Phys.J. A 18, 17 (2003)

M.Baldo, M.Farine, U.Lombardo, E.E.Saperstein, P.Schuck, M.V.Zverev

Surface behaviour of the pairing gap in slab of nuclear matter

doi: 10.1140/epja/i2003-10064-8
Citations: PlumX Metrics

2003KH08      Yad.Fiz. 66, 1919 (2003); Phys.Atomic Nuclei 66, 1871 (2003)

V.A.Khodel, P.Schuck, M.V.Zverev

Spin Degrees of Freedom and Flattening of the Spectra of Single-Particle Excitations in Strongly Correlated Fermi Systems

doi: 10.1134/1.1619498
Citations: PlumX Metrics

2003ZV01      Nucl.Phys. A720, 20 (2003)

M.V.Zverev, J.W.Clark, V.A.Khodel

³P₂-³F₂ pairing in dense neutron matter: the spectrum of solutions

doi: 10.1016/S0375-9474(03)00653-5
Citations: PlumX Metrics

2002BA36      Eur.Phys.J. A 13, 307 (2002)

M.Baldo, U.Lombardo, E.E.Saperstein, M.V.Zverev

The Local Potential Approximation for the Brueckner G-Matrix and a Simple Model of the Scalar-Isoscalar Landau-Migdal Amplitude

doi: 10.1007/s10050-002-8760-y
Citations: PlumX Metrics

2002BA40      Phys.Lett. 533B, 17 (2002)

M.Baldo, U.Lombardo, E.E.Saperstein, M.V.Zverev

Existence of Nuclei with Unusual Neutron Excess ?

NUCLEAR STRUCTURE ¹²⁴Sn; calculated single-particle levels. A=100-200; calculated two-neutron separation energies. Self-consistent finite Fermi systems theory, possibility of nuclei with large neutron excess discussed.

doi: 10.1016/S0370-2693(02)01558-7
Citations: PlumX Metrics

2002BA78      Yad.Fiz. 65, 1276 (2002); Phys.Atomic Nuclei 65, 1243 (2002)

M.Baldo, U.Lombardo, E.E.Saperstein, M.V.Zverev

Local-Potential Approximation for the Brueckner G Matrix and Problem of Optimally Choosing Model Subspace

doi: 10.1134/1.1495024
Citations: PlumX Metrics

2002KA72      Bull.Rus.Acad.Sci.Phys. 66, 27 (2002)

S.V.Karyagin, S.V.Khristenko, S.O.Adamson, A.I.Dementiev, R.U.Khafizov, N.K.Kuzmenko, E.E.Sapershtein, M.V.Zverev

Solid Gamma-Laser: Isomeric Differences in Optical Hyperfine Structure for Three Main Groups of Candidate Nuclei

NUCLEAR STRUCTURE ⁵⁸Co, ¹⁵⁴Eu, ¹⁸¹Ta; analyzed levels J, π, μ, quadrupole moments, radii, isomer shifts, hfs. Application to γ laser discussed.

2002LU19      Part. and Nucl., Lett. 115, 86 (2002)

Yu.S.Lutostansky, S.M.Lukyanov, Yu.E.Penionzhkevich, M.V.Zverev

Neutron Drip Line in the Region of 0-Mg Isotopes

NUCLEAR REACTIONS Ta(⁴⁸Ca, X), E=59, 64 MeV; measured fragments isotopic yields; deduced no evidence for ⁴⁰Mg. ³⁴Ne, ³⁷Na deduced particle stability. ³³Ne, ³⁶Na, ³⁹Mg deduced particle instability.

NUCLEAR STRUCTURE ^24,26O, ^29,31F, ^32,34Ne, ^37,39Na, ^42,44Mg; calculated neutron separation energies.

2001BA34      Yad.Fiz. 64, No 2, 247 (2001); Phys.Atomic Nuclei 64, 203 (2001)

M.Baldo, U.Lombardo, E.E.Saperstein, M.V.Zverev

Brueckner G Matrix for a Planar Slab of Nuclear Matter

doi: 10.1134/1.1349442
Citations: PlumX Metrics

2001BA37      Yad.Fiz. 64, No 3, 509 (2001); Phys.Atomic Nuclei 64, 454 (2001)

M.Baldo, U.Lombardo, E.E.Saperstein, M.V.Zverev

Simple Microscopic Model for the Scalar-Isoscalar Component of the Landau-Migdal Amplitude

doi: 10.1134/1.1358469
Citations: PlumX Metrics

2001CL04      Yad.Fiz. 64, No 4, 677 (2001); Phys.Atomic Nuclei 64, 619 (2001)

J.W.Clark, V.A.Khodel, M.V.Zverev

Impact of Spin-Isospin Fluctuations on Single-Particle Degrees of Freedom in Dense Neutron Matter

doi: 10.1134/1.1368220
Citations: PlumX Metrics

2001ZV01      Pisma Zh.Eksp.Teor.Fiz. 73, 425 (2001); JRTP Lett. 73, 381 (2001)

M.V.Zverev, E.E.Saperstein

Dependence of Nuclear Z Factor on the Chemical Potential

doi: 10.1134/1.1381631
Citations: PlumX Metrics

2000BA13      Yad.Fiz. 63, No 1, 50 (2000); Phys.Atomic Nuclei 63, 43 (2000)

M.Baldo, U.Lombardo, E.E.Saperstein, M.V.Zverev

Microscopic Calculation of a Pairing Gap in Semi-Infinite Nuclear Matter

doi: 10.1134/1.855605
Citations: PlumX Metrics

2000BA74      Yad.Fiz. 63, No 8, 1454 (2000); Phys.Atomic Nuclei 63, 1377 (2000)

M.Baldo, U.Lombardo, E.E.Saperstein, M.V.Zverev

Approximation of the Microscopic Effective Pairing Interaction by the Off-Shell T Matrix for Free Nucleon-Nucleon Scattering

doi: 10.1134/1.1307460
Citations: PlumX Metrics

1999BA14      Yad.Fiz. 62, No 1, 71 (1999); Phys.Atomic Nuclei 62, 66 (1999)

M.Baldo, U.Lombardo, E.E.Saperstein, M.V.Zverev

Solving the Bogolyubov Equations for Semi-Infinite Nuclear Matter in the Case of a Nonlocal Gap

1998BA06      Yad.Fiz. 61, No 1, 21 (1998); Phys.Atomic Nuclei 61, 17 (1998)

M.Baldo, U.Lombardo, E.E.Saperstein, M.V.Zverev

Surface Nature of Pairing in Nuclei

1998BA26      Phys.Lett. 421B, 8 (1998)

M.Baldo, U.Lombardo, E.E.Saperstein, M.V.Zverev

On the Surface Parameters of the Landau-Migdal Amplitude

doi: 10.1016/S0370-2693(97)01603-1
Citations: PlumX Metrics

1997BA44      Yad.Fiz. 60, No 7, 1206 (1997); Phys.Atomic Nuclei 60, 1081 (1997)

M.Baldo, U.Lombardo, E.E.Saperstein, M.V.Zverev

Effective Pairing Interaction in Semi-Infinite Nuclear Matter within the Brueckner Approach: Realistic NN interaction

1997BB01      Yad.Fiz. 60, No 12, 2170 (1997); Phys.Atomic Nuclei 60, 1988 (1997)

M.Baldo, U.Lombardo, E.E.Saperstein, M.V.Zverev

Simple Estimate of the Parameters of Effective Nucleon-Nucleon Interaction Near the Nuclear Surface

NUCLEAR STRUCTURE ²⁰⁸Pb; calculated isoscalar central potential; deduced G matrix energy dependence related features.

1995BA62      Phys.Lett. 350B, 135 (1995)

M.Baldo, U.Lombardo, E.E.Saperstein, M.V.Zverev

On the Brueckner Theory of Pairing in Semi-Infinite Nuclear Matter Beyond the Local Density Approximation

doi: 10.1016/0370-2693(95)00340-Q
Citations: PlumX Metrics

1995BB04      Yad.Fiz. 58, No 9, 1572 (1995); Phys.Atomic Nuclei 58, 1483 (1995)

M.Baldo, U.Lombardo, E.E.Saperstein, M.V.Zverev

Effective Pairing Interaction in Semi-Infinite Nuclear Matter in the Brueckner Approach: Model δ-shaped NN Interaction

1995ZV01      Yad.Fiz. 58, No 9, 1584 (1995); Phys.Atomic Nuclei 58, 1494 (1995)

M.V.Zverev, R.U.Khafizov, V.A.Khodel, V.R.Shaginyan

Effective Spin-Spin Interaction in Neutron Matter

1995ZV02      Yad.Fiz. 58, No 12, 2172 (1995); Phys.Atomic Nuclei 58, 2058 (1995)

M.V.Zverev, N.V.Klochkova, Yu.S.Lutostanski, E.K.Yudina

Nucleosynthesis and the Properties of Nuclei from Oxygen to Nickel Near the Neutron-Stability Boundary

NUCLEAR STRUCTURE ²⁴O, ²⁹F, ³²Ne, ³⁷Na, ⁴²Mg, ⁴⁷Al, ⁴⁸Si, ⁴⁹P, ⁵⁰S, ⁵³Cl, ⁵⁶Ar, ⁵⁹K, ⁶²Ca, ⁶⁹Sc, ⁷²Ti, ⁷⁵V, ⁸⁰Cr, ⁸¹Mn, ⁸⁴Fe, ⁸⁵Co, ⁸⁸Ni; calculated one-, two-neutron separation energies. ⁴²Mg, ⁴⁶Si, ⁸⁰Cr, ⁸⁸Ni; calculated nucleon densities. ⁴⁰Mg, ⁴¹Al, ⁴²Si, ⁴³P, ⁴⁴S, ⁴⁵Cl, ⁴⁶Ar, ⁴⁷K, ⁴⁸Ca; calculated Fermi surface characteristics. Self-consistent finite Fermi systems theory.

1994ZV01      Yad.Fiz. 57, No 4, 587 (1994); Phys.Atomic Nuclei 57, 623 (1994)

M.V.Zverev, R.U.Khafizov, V.A.Khodel, V.R.Shaginyan

Accuracy of the Local Approximation in the Microscopic Theory of Fermi Systems

1994ZV02      Yad.Fiz. 57, No 12, 2196 (1994); Phys.Atomic Nuclei 57, 2113 (1994)

M.V.Zverev, E.E.Saperstein

Self-Consistent Theory of Temperature Effects in Superfluid Nuclei

NUCLEAR STRUCTURE ^112,118Sn; calculated neutron, proton radii, density distributions, gap operator matrix element vs temperature. Self-consistent finite Fermi systems theory. Other Sn isotopes discussed.

1992ST01      Phys.Lett. 276B, 269 (1992)

V.E.Starodubsky, M.V.Zverev

Pairing in Nuclei Near the Proton-Drip Line

NUCLEAR STRUCTURE ¹²⁴Sn, ²⁰²Pb; A=142-168; ^151,153Eu, ^167,165Re; calculated odd-even mass differences; deduced effective pairing force density dependence role in increased proton pairing near drip line. Quasiparticle lagrangian method.

doi: 10.1016/0370-2693(92)90316-V
Citations: PlumX Metrics

1991ZV01      Yad.Fiz. 54, 676 (1991); Sov.J.Nucl.Phys. 54, 410 (1991)

M.V.Zverev, V.E.Starodubsky

Features of the Pairing Properties of Nuclei Near the Boundary of Proton Stability

NUCLEAR STRUCTURE Z=62-76; N=88-92; calculated neutron, proton chemical potentials, quadrupole moments, rms radii, total binding energies. ^{152,154,156,158,160,162,164,166,168,170}Er; calculated neutron, proton chemical potentials, quadrupole moments, gap parameters. Generalized quasi-classical Lagrangian method.

1990GU02      Phys.Rev. C41, 937 (1990)

D.Guillemaud-Mueller, J.C.Jacmart, E.Kashy, A.Latimier, A.C.Mueller, F.Pougheon, A.Richard, Yu.E.Penionzhkevich, A.G.Artukh, A.V.Belozyorov, S.M.Lukyanov, R.Anne, P.Bricault, C.Detraz, M.Lewitowicz, Y.Zhang, Yu.S.Lyutostansky, M.V.Zverev, D.Bazin, W.D.Schmidt-Ott

Particle Stability of the Isotopes ²⁶O and ³²Ne in the Reaction 44 MeV/Nucleon ⁴⁸Ca + Ta

NUCLEAR REACTIONS Ta(⁴⁸Ca, X), E=2112 MeV; measured fragment total energy, fragment production rate vs mass, Z, tof; deduced evidence for ³²Ne. ³¹Ne, ²⁶O deduced particle decay instability.

NUCLEAR STRUCTURE ^18,20,22,24O, ^31,32,33,34Ne; calculated one-, two-neutron separation energies. Quasiparticle Lagrange method.

doi: 10.1103/PhysRevC.41.937
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1989LY01      Izv.Akad.Nauk SSSR, Ser.Fiz. 53, 849 (1989); Bull.Acad.Sci.USSR, Phys.Ser. 53, No.5, 29 (1989)

Yu.S.Lyutostansky, M.V.Zverev, I.V.Panov

New Region of Deformation of Neutron-Rich Nuclei and β-Delayed Neutron Emission

NUCLEAR STRUCTURE A ≤ 35; calculated two-neutron separation energies. ^34,35Na; calculated deformation effect on T_1/2. Self-congruent quasiparticle model.

1989ZV01      Yad.Fiz. 49, 952 (1989)

M.V.Zverev, A.P.Platonov, E.E.Saperstein

Surface Density Fluctuations in Spherical Nuclei

NUCLEAR STRUCTURE ^50,52,54Cr, ^58,60,62,64Ni, ^{74,76,78,80,82}Se, ^{92,94,96,98,100}Mo; calculated B(E2), transition charge density, radii, diffuseness parameter. Collective model.

1987KH02      Nucl.Phys. A465, 397 (1987)

V.A.Khodel, E.E.Saperstein, M.V.Zverev

Effects of Mass Operator Energy Dependence in Atomic Nuclei: Quasiparticle lagrangian versus quasiparticle hamiltonian

NUCLEAR STRUCTURE ²⁰⁶Pb, ²⁰⁵Tl; calculated charge density differences. Quasiparticle Lagrange method.

NUCLEAR REACTIONS ²⁰⁸Pb(e, e), E=502 MeV; calculated σ(θ). Quasiparticle Lagrange method.

doi: 10.1016/0375-9474(87)90355-1
Citations: PlumX Metrics

1987ZV01      Yad.Fiz. 46, 466 (1987)

M.V.Zverev, V.I.Kuprikov, E.E.Saperstein, N.G.Shevchenko, A.A.Khomich

Electron Elastic Scattering from Nuclei as a Probe of Self-Consistent Methods in Nuclear Theory

NUCLEAR REACTIONS ^40,48Ca, ⁵⁸Ni, ^116,124Sn, ²⁰⁸Pb(e, e), E=250, 400, 450, 500 MeV; analyzed σ(θ). Quasiparticle Lagrangian, Hartree-Fock methods.

1986ZV01      Yad.Fiz. 43, 304 (1986)

M.V.Zverev, E.E.Saperstein

On Momentum Distribution of Nucleons Inside Nucleus

NUCLEAR STRUCTURE ²⁰⁸Pb; calculated nucleon momentum distribution. Quasiparticle Lagrange method.

1985ZV01      Yad.Fiz. 42, 1082 (1985)

M.V.Zverev, E.E.Sapershtein

Some Questions of the Self-Consistent Theory of Pairing in Atomic Nuclei. The Lead Region and the ' Magic ± 2 Particles ' Nuclei

NUCLEAR STRUCTURE ^208,204,207Pb, ²⁰⁹Bi; calculated charge radii differences. ^{201,197,193,211,205}Pb; calculated single particle level energies. ^{188,190,192,194,196,198,200,202,204,206,208,210,212,214}Pb; calculated neutron separation energies; deduced nucleon stability boundaries. Self-consistent theory of pairing.

1984ZV01      Yad.Fiz. 39, 1390 (1984)

M.V.Zverev, E.E.Sapershtein

Description of Superfluid Atomic Nuclei in Quasiparticle Lagrange Approach

NUCLEAR STRUCTURE ^{116,118,120,122,124,126,128,132}Sn; calculated levels, binding energy, charge radius. ^{100,102,104,106,108,110,112,114}Sn; calculated binding energy, charge radius. ^116,124Sn; calculated transition charge density distribution. Quasiparticle Lagrange approach.