NSR Query Results
Output year order : Descending NSR database version of April 26, 2024. Search: Author = S.Agarwal Found 12 matches. 2022SC17 J.Phys.(London) G49, 110502 (2022) H.Schatz, A.D.Becerril Reyes, A.Best, E.F.Brown, K.Chatziioannou, K.A.Chipps, C.M.Deibel, R.Ezzeddine, D.K.Galloway, C.J.Hansen, F.Herwig, A.P.Ji, M.Lugaro, Z.Meisel, D.Norman, J.S.Read, L.F.Roberts, A.Spyrou, I.Tews, F.X.Timmes, C.Travaglio, N.Vassh, C.Abia, P.Adsley, S.Agarwal, M.Aliotta, W.Aoki, A.Arcones, A.Aryan, A.Bandyopadhyay, A.Banu, D.W.Bardayan, J.Barnes, A.Bauswein, T.C.Beers, J.Bishop, T.Boztepe, B.Cote, M.E.Caplan, A.E.Champagne, J.A.Clark, M.Couder, A.Couture, S.E.de Mink, S.Debnath, R.J.deBoer, J.den Hartogh, P.Denissenkov, V.Dexheimer, I.Dillmann, J.E.Escher, M.A.Famiano, R.Farmer, R.Fisher, C.Frohlich, A.Frebel, C.Fryer, G.Fuller, A.K.Ganguly, S.Ghosh, B.K.Gibson, T.Gorda, K.N.Gourgouliatos, V.Graber, M.Gupta, W.C.Haxton, A.Heger, W.R.Hix, W.C.G.Ho, E.M.Holmbeck, A.A.Hood, S.Huth, G.Imbriani, R.G.Izzard, R.Jain, H.Jayatissa, Z.Johnston, T.Kajino, A.Kankainen, G.G.Kiss, A.Kwiatkowski, M.La Cognata, A.M.Laird, L.Lamia, P.Landry, E.Laplace, K.D.Launey, D.Leahy, G.Leckenby, A.Lennarz, B.Longfellow, A.E.Lovell, W.G.Lynch, S.M.Lyons, K.Maeda, E.Masha, C.Matei, J.Merc, B.Messer, F.Montes, A.Mukherjee, M.R.Mumpower, D.Neto, B.Nevins, W.G.Newton, L.Q.Nguyen, K.Nishikawa, N.Nishimura, F.M.Nunes, E.O'Connor, B.W.O'Shea, W.-J.Ong, S.D.Pain, M.A.Pajkos, M.Pignatari, R.G.Pizzone, V.M.Placco, T.Plewa, B.Pritychenko, A.Psaltis, D.Puentes, Y.-Z.Qian, D.Radice, D.Rapagnani, B.M.Rebeiro, R.Reifarth, A.L.Richard, N.Rijal, I.U.Roederer, J.S.Rojo, J.S K, Y.Saito, A.Schwenk, M.L.Sergi, R.S.Sidhu, A.Simon, T.Sivarani, A.Skuladottir, M.S.Smith, A.Spiridon, T.M.Sprouse, S.Starrfield, A.W.Steiner, F.Strieder, I.Sultana, R.Surman, T.Szucs, A.Tawfik, F.Thielemann, L.Trache, R.Trappitsch, M.B.Tsang, A.Tumino, S.Upadhyayula, J.O.Valle Martinez, M.Van der Swaelmen, C.Viscasillas Vazquez, A.Watts, B.Wehmeyer, M.Wiescher, C.Wrede, J.Yoon, R.G.T.Zegers, M.A.Zermane, M.Zingale, the Horizon 2020 Collaborations Horizons: nuclear astrophysics in the 2020s and beyond
doi: https://dx.doi.org/10.1088/1361-6471/ac8890
1993SI12 Can.J.Phys. 71, 115 (1993) N.L.Singh, S.Agarwal, J.Rama Rao Excitation Function for α-Particle-Induced Reactions in Light-Mass Nuclei NUCLEAR REACTIONS, ICPND 51V(α, xnypzα)54Mn/52Mn/51Cr/48V/47Sc/63Cu/57Co/58Co, E ≤ 50 MeV; measured residuals production σ(E). Stacked foil activation technique. Hybrid, exciton models.
doi: 10.1139/p93-017
1992SI07 J.Phys.(London) G18, 927 (1992) N.L.Singh, S.Agarwal, J.Rama Rao Pre-Equilibrium Neutron Emission in Alpha Particle Induced Reactions NUCLEAR REACTIONS, ICPND 165Ho(α, 2n), (α, 3n), (α, 4n), E=threshold-50 MeV; measured σ(E). Stacked foil activation technique, γ-spectroscopy. Improved exciton model analysis.
doi: 10.1088/0954-3899/18/5/019
1990SI17 J.Phys.Soc.Jpn. 59, 3916 (1990) N.L.Singh, S.Agarwal, J.Rama Rao Comparative Study of Pre-Equilibrium Models and Mechanism of Alpha Particle Induced Reactions NUCLEAR REACTIONS, ICPND 169Tm(α, n), (α, 2n), (α, 3n), (α, 4n), (α, nα), (α, 2nα), E=threshold-50 MeV; 93Nb(α, n), (α, 2n), (α, 3n), (α, nα), (α, 3np), E=threshold-50 MeV; measured σ(E); deduced reaction mechanism. Preequilibrium model analysis. Data from this article have been entered in the EXFOR database. For more information, access X4 datasetD0137. 1987RA05 J.Phys.(London) G13, 535 (1987) J.Rama Rao, A.V.Mohan Rao, S.Mukherjee, R.Upadhyay, N.L.Singh, S.Agarwal, L.Chaturvedi, P.P.Singh Non-Equilibrium Effects in Alpha-Particle-Induced Reactions in Light, Medium and Heavy Nuclei up to 120 MeV NUCLEAR REACTIONS, ICPND 51V, 93Nb(α, n), 93Nb, 165Ho(α, 2n), 51V(α, 3n), 165Ho(α, 4n), E=10-120 MeV; measured σ(E). Activation method. Pre-equilibrium hybrid model.
doi: 10.1088/0305-4616/13/4/017
1987RA08 Nucl.Instrum.Methods Phys.Res. B24/25, 484 (1987) J.Rama Rao, A.V.Mohan Rao, S.Mukherjee, R.Upadhyay, N.L.Singh, S.Agarwal, L.Chaturvedi, P.P.Singh Excitation Functions of Alpha Particle Induced Reactions in Cobalt in the Energy Range 10-120 MeV using Variable Energy Cyclotrons NUCLEAR REACTIONS, ICPND 59Co(α, 5np), (α, 6np), (α, n2p), (α, n3p), (α, nα), (α, 2nα), (α, 3nα), (α, n2α), (α, 3n2α), (α, 3np2α), E=10-120 MeV; measured residue production σ(E). Activation method, Ge(Li) detector.
doi: 10.1016/0168-583X(87)90689-6
1981BO15 Z.Phys. A299, 263 (1981) B.Borderie, M.Berlanger, D.Gardes, F.Hanappe, L.Nowicki, J.Peter, B.Tamain, S.Agarwal, J.Girard, C.Gregoire, J.Matuszek, C.Ngo A Possible Mechanism in Heavy Ion Induced Reactions: 'Fast fission process' NUCLEAR REACTIONS, Fission 165Ho(40Ar, F), E=180, 200, 230, 243, 280, 315, 340, 391 MeV; 181Ta(24Mg, F), E=270, 335, 340 MeV; Re(20Ne, F), E=124, 206 MeV; measured σ(fusion), L(critical), fragment mass vs compound nucleus excitation, angular momentum; deduced fast fission process.
doi: 10.1007/BF01443944
1980AG06 Z.Phys. A296, 287 (1980) S.Agarwal, J.Galin, B.Gatty, D.Guerreau, M.Lefort, X.Tarrago, R.Babinet, J.Girard The Influence of the Entrance Channel Mass Asymmetry on the Reaction Mechanism: Investigated on the 16O+92Mo and 52Cr+56Fe Systems NUCLEAR REACTIONS, Fission 92Mo(16O, X), (16O, F), E=187 MeV; 56Fe(52Cr, X), (52Cr, F), E=264 MeV; measured evaporation residue σ(θ), σ(fragment θ, Z); deduced reaction mechanism, entrance channel mass asymmetry effects on fission.
doi: 10.1007/BF01438522
1980AG07 Z.Phys. A297, 41 (1980) Life Time of the Intermediate Complex in a Deep Inelastic Collision Depends on the Mass Asymmetry of the Entrance Channel NUCLEAR REACTIONS 56Fe(52Cr, X), E=261 MeV; 64Ni(40Ca, X), E=182 MeV; 92Mo(16O, X), E=187 MeV; calculated σ(fragment θ), σ(fragment θ, Z); deduced composite system T1/2 vs entrance channel mass asymmetry. Diffusion model, statistical decay, deep inelastic collisions.
doi: 10.1007/BF01414244
1977AG04 Nucl.Phys. A293, 230 (1977) S.Agarwal, J.Galin, B.Gatty, D.Guerreau, M.Lefort, X.Tarrago, R.Babinet, B.Cauvin, J.Girard, H.Nifenecker Evidence for a Short Lifetime and a Long Lifetime Regime in the Deep Inelastic Collisions between 40Ca and 64Ni at 182 MeV NUCLEAR REACTIONS 64Ni(40Ca, X), E=182 MeV; measured σ(E, Z, θ), Z=6-27. Enriched target.
doi: 10.1016/0375-9474(77)90489-4
1977GA19 Z.Phys. A283, 173 (1977) J.Galin, B.Gatty, D.Guerreau, M.Lefort, X.Tarrago, S.Agarwal, R.Babinet, B.Cauvin, J.Girard, H.Nifenecker Fusion and Deep Inelastic Collisions Studied on the Ar + Au System II. Charge and Mass Analysis at 217 MeV Bombarding Energy NUCLEAR REACTIONS 197Au(40Ar, X), E=217 MeV; measured σ(A, Z, θ).
doi: 10.1007/BF01418709
1976AG01 Z.Phys. A278, 265 (1976) S.Agarwal, H.Gauvin, D.Guerreau, H.Jungclas, Y.Le Beyec, M.Lefort, X.Tarrago Evaporation Residue Cross Sections in Complete Fusion Reactions between 52Cr-56Fe, 63Cu-Ni and 63Cu-Ag NUCLEAR REACTIONS 107,109Ag, 58,60Ni(63Cu, X), E=347 MeV; 56Fe(52Cr, X), E=207, 264 MeV; measured evaporation residue σ.
doi: 10.1007/BF01409177
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