NSR Query Results
Output year order : Descending NSR database version of April 11, 2024. Search: Author = G.Korschinek Found 40 matches. 2023KO04 Eur.Phys.J. A 59, 52 (2023) Recent nucleosynthesis in the solar neighbourhood, detected with live radionuclides
doi: 10.1140/epja/s10050-023-00956-2
2020KO20 Phys.Rev.Lett. 125, 031101 (2020) G.Korschinek, T.Faestermann, M.Poutivtsev, A.Arazi, K.Knie, G.Rugel, A.Wallner Supernova-Produced 53Mn on Earth ATOMIC MASSES 53Mn; measured 53Mn contents in four different crusts; deduced 53Mn/Mn ratio.
doi: 10.1103/PhysRevLett.125.031101
2020MA37 Phys.Rev.Lett. 125, 102502 (2020) N.Marginean, D.Little, Y.Tsunoda, S.Leoni, R.V.F.Janssens, B.Fornal, T.Otsuka, C.Michelagnoli, L.Stan, F.C.L.Crespi, C.Costache, R.Lica, M.Sferrazza, A.Turturica, A.D.Ayangeakaa, K.Auranen, M.Barani, P.C.Bender, S.Bottoni, M.Boromiza, A.Bracco, S.Calinescu, C.M.Campbell, M.P.Carpenter, P.Chowdhury, M.Ciemala, N.Cieplicka-Orynczak, D.Cline, C.Clisu, H.L.Crawford, I.E.Dinescu, J.Dudouet, D.Filipescu, N.Florea, A.M.Forney, S.Fracassetti, A.Gade, I.Gheorghe, A.B.Hayes, I.Harca, J.Henderson, A.Ionescu, L.W.Iskra, M.Jentschel, F.Kandzia, Y.H.Kim, F.G.Kondev, G.Korschinek, U.Koster, Krishichayan, M.Krzysiek, T.Lauritsen, J.Li, R.Marginean, E.A.Maugeri, C.Mihai, R.E.Mihai, A.Mitu, P.Mutti, A.Negret, C.R.Nita, A.Olacel, A.Oprea, S.Pascu, C.Petrone, C.Porzio, D.Rhodes, D.Seweryniak, D.Schumann, C.Sotty, S.M.Stolze, R.Suvaila, S.Toma, S.Ujeniuc, W.B.Walters, C.Y.Wu, J.Wu, S.Zhu, S.Ziliani Shape Coexistence at Zero Spin in 64Ni Driven by the Monopole Tensor Interaction NUCLEAR REACTIONS 62Ni(18O, 16O), E=39 MeV; 65Cu(11B, 12C), E=26 MeV; 63Ni(n, γ), E thermal; measured reaction products, Eγ, Iγ; analyzed available data from multiple experiments. 64Ni; deduced γ-ray energies, J, π, B(E2). Comparison with theoretical calculations.
doi: 10.1103/PhysRevLett.125.102502
2019KO13 Phys.Rev.Lett. 123, 072701 (2019) D.Koll, G.Korschinek, T.Faestermann, J.M.Gomez-Guzman, Se.Kipfstuhl, S.Merchel, J.M.Welch Interstellar 60Fe in Antarctica ATOMIC MASSES 53Mn, 60Fe; measured number of atoms in snow by accelerator mass spectrometry; deduced atomic ratio significantly above cosmogenic production.
doi: 10.1103/PhysRevLett.123.072701
2017LU03 Phys.Rev. C 95, 035803 (2017) P.Ludwig, G.Rugel, I.Dillmann, T.Faestermann, L.Fimiani, K.Hain, G.Korschinek, J.Lachner, M.Poutivtsev, K.Knie, M.Heil, F.Kappeler, A.Wallner Measurement of the stellar 58Ni(n, γ)59Ni cross section with accelerator mass spectrometry NUCLEAR REACTIONS 58Ni(n, γ)59Ni, kT=25 keV quasistellar neutron spectrum; measured E(n), I(n), neutron flux, 59Ni content by accelerator mass spectrometry (AMS) technique, experimental cross section using gas-filled analyzing magnet system (GAMS) at tandem accelerator of the MLL-Garching; deduced Maxwellian-averaged cross sections (MACS). Comparison with evaluated libraries ENDF/B-VII.1, JEFF-3.2 and JENDL-4.0.
doi: 10.1103/PhysRevC.95.035803
2015KO20 Nucl.Phys. A944, 190 (2015) Mass spectrometric searches for superheavy elements in terrestrial matter
doi: 10.1016/j.nuclphysa.2015.06.003
2015WE14 Phys.Rev. C 92, 045810 (2015) M.Weigand, T.A.Bredeweg, A.Couture, K.Gobel, T.Heftrich, M.Jandel, F.Kappeler, C.Lederer, N.Kivel, G.Korschinek, M.Krticka, J.M.O'Donnell, J.Ostermoller, R.Plag, R.Reifarth, D.Schumann, J.L.Ullmann, A.Wallner 63Ni(n, γ) cross sections measured with DANCE NUCLEAR REACTIONS 63Ni(n, γ), E=40 eV-500 keV; measured Eγ, Iγ, σ(E) using 4π BaF2 array DANCE at LANSCE-LANL, neutron flux; deduced resonances, Maxwellian averaged cross sections (MACS), relative production of isotopes in the vicinity of 63Ni and Ni to As elements for the s process. Comparison with KADoNiS database and experimental data from n_TOF collaboration.
doi: 10.1103/PhysRevC.92.045810
2012LA03 Phys.Rev. C 85, 015801 (2012) J.Lachner, I.Dillmann, T.Faestermann, G.Korschinek, M.Poutivtsev, G.Rugel, C.Lierse von Gostomski, A.Turler, U.Gerstmann Attempt to detect primordial 244Pu on Earth ATOMIC MASSES 244Pu; measured TOF-E(residuals) spectra using AMS technique at MLL, Garching facility. Attempt to detect primordial 244Pu in bastnasite mineral proved negative. Upper limit established, and compared with previous measurement.
doi: 10.1103/PhysRevC.85.015801
2012LU05 Phys.Rev. C 85, 024315 (2012) P.Ludwig, T.Faestermann, G.Korschinek, G.Rugel, I.Dillmann, L.Fimiani, S.Bishop, P.Kumar Search for superheavy elements with 292 ≤ A ≤ 310 in nature with accelerator mass spectrometry ATOMIC MASSES A=292-295, 297-302, 304, 306, 308, 310; measured abundance of SHE in natural platinum, osmium, lead fluoride, using energy loss, and time of flight information. Accelerator mass spectrometry (AMS) technique. No evidence found for the existence of superheavy elements (SHE), upper limits established.
doi: 10.1103/PhysRevC.85.024315
2011HE26 Meteorit.Planet.Sci. 46, 1427 (2011) G.F.Herzog, M.W.Caffee, T.Faestermann, R.Hertenberger, G.Korschinek, I.Leya, R.C.Reedy, J.M.Sisterson Cross sections from 5 to 35 MeV for the reactions natMg(3He, x)26Al, 27Al(3He, x)26Al, natCa(3He, x)41Ca, and natCa(3He, x)36Cl: Implications for early irradiation in the solar system NUCLEAR REACTIONS Mg(3He, X)26Al, 27Al(3He, X)26Al, Ca(3He, X)41Ca/36Cl, E=5-35 MeV; measured reaction products with AMS, chemical separation; deduced σ, solar system isotope ratios. TALYS nuclear model code calculations, comparison with available data.
doi: 10.1111/j.1945-5100.2011.01236.x
2011WA34 J.Korean Phys.Soc. 59, 1378s (2011) A.Wallner, K.Buczak, C.Lederer, H.Vonach, T.Faestermann, G.Korschinek, M.Poutivtsev, G.Rugel, A.Klix, K.Seidel, A.Plompen, V.Semkova Production of Long-lived Radionuclides 10Be, 14C, 53Mn, 55Fe, 59Ni and 202gPb in a Fusion Environment NUCLEAR REACTIONS 54Fe(n, np), (n, d), (n, 2n), E=13.4-14.8;56Fe(n, 2n), E=13-20 MeV; measured Eγ, Iγ; deduced σ using activation technique. Compared with other data and ENDF/B-VII.
doi: 10.3938/jkps.59.1378
2010DI15 Nucl.Instrum.Methods Phys.Res. B268, 1283 (2010) I.Dillmann, T.Faestermann, G.Korschinek, J.Lachner, M.Maiti, M.Poutivtsev, G.Rugel, S.Walter, F.Kappeler, M.Erhard, A.R.Junghans, C.Nair, R.Schwengner, A.Wagner Solving the stellar 62Ni problem with AMS NUCLEAR REACTIONS 62,64Ni(n, γ), E=30 keV; measured reaction products; deduced Maxwellian-averaged σ and their uncertainties. Comparison with NON-SMOKER calculations.
doi: 10.1016/j.nimb.2009.10.153
2010KO19 Nucl.Instrum.Methods Phys.Res. B268, 187 (2010) G.Korschinek, A.Bergmaier, T.Faestermann, U.C.Gerstmann, K.Knie, G.Rugel, A.Wallner, I.Dillmann, G.Dollinger, Ch.Lierse von Gostomski, K.Kossert, M.Maiti, M.Poutivtsev, A.Remmert A new value for the half-life of 10Be by Heavy-Ion Elastic Recoil Detection and liquid scintillation counting RADIOACTIVITY 10Be(β-); measured electron spectrum; deduced 10Be activity, T1/2. Liquid scintillation counting (LSC). ATOMIC MASSES 9,10Be; measured ion beam intensities; deduced 10Be/9Be isotopic ratio. Heavy-Ion Elastic Recoil Detection (HI-ERD).
doi: 10.1016/j.nimb.2009.09.020
2009RU08 Phys.Rev.Lett. 103, 072502 (2009) G.Rugel, T.Faestermann, K.Knie, G.Korschinek, M.Poutivtsev, D.Schumann, N.Kivel, I.Gunther-Leopold, R.Weinreich, M.Wohlmuther New Measurement of the 60Fe Half-Life RADIOACTIVITY 60Fe(β-); measured Eγ, γ; deduced T1/2.
doi: 10.1103/PhysRevLett.103.072502
2008LA14 Phys.Rev. C 78, 064313 (2008) J.Lachner, I.Dillmann, T.Faestermann, G.Korschinek, M.Poutivtsev, G.Rugel Search for long-lived isomeric states in neutron-deficient thorium isotopes ATOMIC MASSES 211,213,217,218Th; measured mass of Th sample to determine existence of long-lived isomers, upper limits of existence of isomers.
doi: 10.1103/PhysRevC.78.064313
2007RU09 Nucl.Instrum.Methods Phys.Res. B259, 683 (2007) G.Rugel, I.Dillmann, T.Faestermann, M.Heil, F.Kappeler, K.Knie, G.Korschinek, W.Kutschera, M.Poutivtsev, A.Wallner Measurement of (n, γ) reaction cross sections at stellar energies for 58Ni and 78Se NUCLEAR REACTIONS 58Ni(n, γ), 78Se(n, γ), E ≈ 0-100 keV; measured cross sections using accelerator mass spectrometry. Quasi-stellar neutron spectrum.
doi: 10.1016/j.nimb.2007.01.206
2006AR12 Phys.Rev. C 74, 025802 (2006) A.Arazi, T.Faestermann, J.O.Fernandez Niello, K.Knie, G.Korschinek, M.Poutivtsev, E.Richter, G.Rugel, A.Wallner Measurement of 25Mg(p, γ)26Alg resonance strengths via accelerator mass spectrometry NUCLEAR REACTIONS 25Mg(p, γ), E(cm)=189, 304, 374, 418 keV; measured yields; deduced resonance strengths. Accelerator mass spectrometry. Astrophysical implications discussed.
doi: 10.1103/PhysRevC.74.025802
2006SC16 Nucl.Instrum.Methods Phys.Res. A562, 1057 (2006) D.Schumann, R.Michel, G.Korschinek, K.Knie, J.-C.David Excitation functions for the production of 60Fe and 53Mn in the reaction natPb(p, xp/yn)Z NUCLEAR REACTIONS Pb(p, X)60Fe/53Mn, E ≈ 100-2600 MeV; measured excitation functions. Comparison with model predictions.
doi: 10.1016/j.nima.2006.02.094
2003BA42 Phys.Lett. B 563, 23 (2003) H.O.Back, M.Balata, A.de Bari, T.Beau, A.de Bellefon, G.Bellini, J.Benziger, S.Bonetti, C.Buck, B.Caccianiga, L.Cadonati, F.Calaprice, G.Cecchet, M.Chen, A.Di Credico, O.Dadoun, D.D'Angelo, V.Yu.Denisov, A.Derbin, M.Deutsch, F.Elisei, A.Etenko, F.von Feilitzsch, R.Fernholz, R.Ford, D.Franco, B.Freudiger, C.Galbiati, F.Gatti, S.Gazzana, M.G.Giammarchi, D.Giugni, M.Goeger-Neff, A.Goretti, C.Grieb, C.Hagner, G.Heusser, A.Ianni, A.M.Ianni, H.de Kerret, J.Kiko, T.Kirsten, V.Kobychev, G.Korga, G.Korschinek, Y.Kozlov, D.Kryn, M.Laubenstein, E.Litvinovich, C.Lendvai, P.Lombardi, I.Machulin, S.Malvezzi, J.Maneira, I.Manno, D.Manuzio, G.Manuzio, F.Masetti, A.Martemianov, U.Mazzucato, K.McCarty, E.Meroni, L.Miramonti, M.E.Monzani, P.Musico, L.Niedermeier, L.Oberauer, M.Obolensky, F.Ortica, M.Pallavicini, L.Papp, L.Perasso, A.Pocar, O.A.Ponkratenko, R.S.Raghavan, G.Ranucci, A.Razeto, A.Sabelnikov, C.Salvo, R.Scardaoni, D.Schimizzi, S.Schoenert, H.Simgen, T.Shutt, M.Skorokhvatov, O.Smirnov, A.Sonnenschein, A.Sotnikov, S.Sukhotin, V.Tarasenkov, R.Tartaglia, G.Testera, V.I.Tretyak, D.Vignaud, R.B.Vogelaar, V.Vyrodov, M.Wojcik, O.Zaimidoroga, Yu.G.Zdesenko, G.Zuzel New limits on nucleon decays into invisible channels with the BOREXINO counting test facility RADIOACTIVITY 12C(n); 13C(p); measured T1/2 lower limits for bound nucleon decay to invisible channels.
doi: 10.1016/S0370-2693(03)00636-1
2003BA91 Pisma Zh.Eksp.Teor.Fiz. 78, 707 (2003); JETP Lett. 78, 261 (2003) H.O.Back, M.Belata, A.de Bari, T.Beau, A.de Bellefon, G.Bellini, J.Benziger, S.Bonetti, C.Buck, B.Caccianiga, L.Cadonati, F.Calaprice, G.Cecchet, M.Chen, A.Di Credico, O.Dadoun, D.D'Angelo, A.Derbin, M.Deutsch, F.Elisei, A.Etenko, F.von Feilitzsch, R.Fernholz, R.Ford, D.Franco, B.Freudiger, C.Galbiati, F.Gatti, S.Gazzana, M.G.Giammarchi, D.Giugni, M.Goeger-Neff, A.Goretti, C.Grieb, C.Hagner, E.Harding, F.X.Hartmann, G.Heusser, A.Ianni, A.M.Ianni, H.De Kerret, J.Kiko, T.Kirsten, V.Kobychev, G.Korga, G.Korschinek, Y.Kozlov, D.Kryn, J.Lamblin, M.Laubenstein, C.Lendvai, E.Litvinovich, P.Lombardi, I.Machulin, S.Malvezzi, J.Maneira, I.Manno, D.Manuzio, G.Manuzio, F.Masetti, A.Martemianov, U.Mazzucato, K.McCarty, E.Meroni, L.Miramonti, M.E.Monzani, V.Muratova, P.Musico, L.Niedermeier, L.Oberauer, M.Obolensky, F.Ortica, M.Pallavicini, L.Papp, L.Perasso, A.Pocar, R.S.Raghavan, G.Ranucci, A.Razeto, A.Sabelnikov, C.Salvo, R.Scardaoni, D.Schimizzi, S.Schoenert, H.Simgen, T.Shutt, M.Skorokhvatov, O.Smirnov, A.Sonnenschein, A.Sotnikov, S.Sukhotin, V.Tarasenkov, R.Tartaglia, G.Testera, D.Vignaud, R.B.Vogelaar, V.Vyrodov, M.Wojcik, O.Zaimidoroga, G.Zuzel New Experimental Limits on Heavy Neutrino Mixing in 8B-Decay Obtained with the Borexino Counting Test Facility RADIOACTIVITY 8B(β+); analyzed solar neutrino counting rates; deduced limits on heavy neutrino mixing parameter.
doi: 10.1134/1.1625721
2003FE11 Braz.J.Phys. 33, 218 (2003) J.O.Fernandez Niello, A.Arazi, T.Faestermann, K.Knie, G.Korschinek, E.Richter, G.Rugel, A.Wallner An Alternative Method for the Measurement of Stellar Nuclear-Reaction Rates NUCLEAR REACTIONS 25Mg(p, γ), E ≈ 316, 389, 434 keV; measured yields; deduced resonance strength. Accelerator mass spectrometry.
doi: 10.1590/s0103-97332003000200009
2003KN01 Nucl.Phys. A723, 343 (2003) K.Knie, A.Elhardt, T.Faestermann, G.Korschinek, C.Lierse, G.Rugel, A.Stippschild Search for A = 60 fragments from neutron-induced fission with accelerator mass spectrometry NUCLEAR REACTIONS 235U(n, F)60Fe, E=reactor; measured fission yield upper limit. 59Fe(n, γ), E=reactor; measured σ. Chemical extraction, accelerator mass spectrometry. Comparison with previous results.
doi: 10.1016/S0375-9474(03)01435-0
2003RU05 Eur.Phys.J. A 17, 633 (2003) W.Ruhm, G.Rugel, T.Faestermann, K.Knie, A.Wallner, B.Heisinger, E.Nolte, A.A.Marchetti, R.E.Martinelli, K.L.Carroll, G.Korschinek Cosmic-ray-induced 63Ni - A potential confounder of fast-neutron-induced 63Ni in copper samples from Hiroshima
doi: 10.1140/epja/i2003-10034-2
2000ME31 Nucl.Instrum.Methods Phys.Res. B 172, 806 (2000) S.Merchel, T.Faestermann, U.Herpers, K.Knie, G.Korschinek, I.Leya, R.Michel, G.Rugel, C.Wallner Thin- and thick-target cross sections for the production of 53Mn and 60Fe NUCLEAR REACTIONS Fe(p, x), Ni(p, x), E=17.2 MeV-2.6 GeV; measured products, 53Mn, 60Fe; deduced σ, σ(E). Data were imported from EXFOR entry O1229.
doi: 10.1016/S0168-583X(00)00105-1
2000ME32 Nucl.Instrum.Methods Phys.Res. B 172, 806 (2000) S.Merchel, T.Faestermann, U.Herpers, K.Knie, G.Korschinek, I.Leya, R.Michel, G.Rugel, C.Wallner Thin- and thick-target cross sections for the production of Mn-53 and Fe-60
doi: 10.1016/S0168-583X(00)00105-1
1996FE16 Nucl.Instrum.Methods Phys.Res. B117, 156 (1996) J.O.Fernandez Niello, D.Abriola, D.E.Alvarez, O.A.Capurro, M.di Tada, A.Etchegoyen, A.M.J.Ferrero, G.V.Marti, A.J.Pacheco, J.E.Testoni, G.Korschinek Developments of AMS at the TANDAR Accelerator
doi: 10.1016/0168-583X(96)00223-6
1994RU19 Planet.Space Sci. 42, 227 (1994) W.Ruhm, B.Schneck, K.Knie, G.Korschinek, L.Zerle, E.Nolte, D.Weselka, H.Vonach A New Half-Life Determination of 59Ni RADIOACTIVITY 55Fe, 59Ni(EC) [from 54Fe, 58Ni(n, γ)]; measured X-ray spectra, T1/2. NUCLEAR REACTIONS 60Ni(n, 2n), E=14.8 MeV; measured σ. Accelerator mass spectrometry. Comparison with model predictions. Data from this article have been entered in the EXFOR database. For more information, access X4 dataset22583. 1991NO05 Z.Phys. A340, 411 (1991) E.Nolte, T.Faestermann, A.Gillitzer, G.Korschinek, D.Muller, V.M.Novikov, A.A.Pomansky, A.Ljubicic, D.Miljanic Test of the Pauli Exclusion Principle for Nucleons and Atomic Electrons by Accelerator Mass Spectrometry
doi: 10.1007/BF01290329
1991NO08 J.Phys.(London) G17, S355 (1991) E.Nolte, T.Brunner, T.Faestermann, A.Gillitzer, G.Korschinek, D.Muller, B.Schneck, D.Weselka, V.N.Novikov, A.A.Pomansky, A.Ljubicic, D.Miljanic, H.Vonach Accelerator Mass Spectrometry for Tests of the Pauli Exclusion Principle and for Detection of ββ Decay Products NUCLEAR REACTIONS 60Ni(n, 2n), E=14.8 MeV; measured σ. Accelerator mass spectrometry technique. RADIOACTIVITY 59Ni(EC), (β+) [from 60Ni(n, 2n), E=14.8 MeV]; measured T1/2. Accelerator mass spectrometry technique.
doi: 10.1088/0954-3899/17/S/037
1990RU11 Nucl.Instrum.Methods Phys.Res. B52, 557 (1990) W.Ruhm, K.Kato, G.Korschinek, H.Morinaga, A.Urban, L.Zerle, E.Nolte The Neutron Spectrum of the Hiroshima A-Bomb and the Dosimetry System 1986 NUCLEAR REACTIONS 40Ca(n, γ), E ≤ 3 keV; measured resonance integral. AMS, γ-spectroscopy techniques.
doi: 10.1016/0168-583X(90)90476-B
1984MA49 Z.Phys. A319, 287 (1984) W.A.Mayer, W.Henning, R.Holzwarth, H.J.Korner, G.Korschinek, W.U.Mayer, G.Rosner, H.J.Scheerer Mass Excess and Excited States of Neutron-Rich Silicon, Phosphorus and Sulphur Isotopes NUCLEAR REACTIONS 36S(14C, 17O), (14C, 16O), (14C, 15O), (14C, 15N), (14C, 14N), (14C, 13C), (14C, 12C), E=71 MeV; measured ejectile spectra. 36S(18O, 17O), (18O, 16O), E=80 MeV; measured γ(ejectile)-coin; deduced Q. 33,34Si, 35,36P deduced mass excess, levels. 35Si deduced mass. 37,38S deduced mass excess, levels, γ-decay. Ge(Li) detector, Q3D magnetic spectrograph.
doi: 10.1007/BF01412542
1982CH08 Lett.Nuovo Cim. 33, 159 (1982) I.Chiodi, S.Lunardi, M.Morando, C.Signorini, G.Fortuna, W.Starzecki, A.M.Stefanini, G.Korschinek, H.Morinaga, E.Nolte, W.Schollmeier Multinucleon Transfer in the Interaction of 58Ni with 124Sn around the Coulomb Barrier NUCLEAR REACTIONS 124Sn(58Ni, X), E=249 MeV; measured σ(fragment E, mass); deduced multi-nucleon transfer, kinematic effects.
doi: 10.1007/BF02725528
1982MA30 Phys.Rev. C26, 500 (1982) W.Mayer, D.Pereira, K.E.Rehm, H.J.Scheerer, H.J.Korner, G.Korschinek, W.Mayer, P.Sperr, S.C.Pieper, R.D.Lawson Strong Population of Excited 0+ States in Even Zr Isotopes Observed with the (14C, 16O) Reaction NUCLEAR REACTIONS 92,100Mo(14C, 14C), (14C, 14C'), (14C, 16O), 94,96,98Mo(14C, 16O), E=71 MeV; measured σ(θ), σ(E(16O)); deduced optical model parameters. 90,92,94,96,98Zr levels deduced spectroscopic amplitudes. DWBA analysis.
doi: 10.1103/PhysRevC.26.500
1982NO07 Z.Phys. A306, 211 (1982) E.Nolte, G.Colombo, S.Z.Gui, G.Korschinek, W.Schollmeier, P.Kubik, S.Gustavsson, R.Geier, H.Morinaga Very Proton Rich Nuclei with N ≈ 82 I. In-Beam γ Spectroscopy: Seniority isomerism in 150 Er NUCLEAR REACTIONS 92,94Mo, 93Nb(58Ni, xnypzα)/148Tm/150Tm/147Er/148Er/149Er/150Er/145Ho/149Ho/148Ho/146Ho/147Ho/144Dy/146Dy/148Dy, E=233-250 MeV; 92Mo(60Ni, xnypzα), E=240-259 MeV; measured σ(Eγ), γγ-coin, Eγ, Iγ, γ(t), relative yields for residuals; deduced two proton evaporation dominance. 148,150Er, 147Ho deduced levels, J, π, T1/2. Bunched, pulsed beam techniques.
doi: 10.1007/BF01415123
1982NO08 Z.Phys. A306, 223 (1982) E.Nolte, S.Z.Gui, G.Colombo, G.Korschinek, K.Eskola Very Proton Rich Nuclei with N ≈ 82 II. Beta Decay Studies RADIOACTIVITY 144,145,146Tb, 145,146Dy, 147,148,150Ho, 148,150Er, 148,150Tm [from 90,91,92Zr, 93Nb, 92,94Mo(58Ni, xnyp), E=233-250 MeV]; measured γγ-coin, EC/β+, Eγ, Iγ, β-decay T1/2; deduced log ft, Iβ. 150Er deduced Q(EC). 144,145,146Gd, 147,148,150Dy, 146Tb, 148,150Ho deduced levels, γ-branching.
doi: 10.1007/BF01415124
1982NO13 Z.Phys. A309, 33 (1982) E.Nolte, G.Korschinek, Ch.Setzensack Seniority Isomerism in the N = 82 Isotone 152Yb; Favoured β transitions πh11/2 → νh9/2 RADIOACTIVITY 152Yb(β+) [from 96Ru(58Ni, 2p), E=238, 250 MeV]; 151Tm(β+) [from 96Ru(58Ni, 3p), E=250 MeV]; 152mTm [from 152Yb decay]; measured Eγ, Iγ, γγ-coin, γγ(t). 152Yb deduced isomer T1/2, Q(EC), log ft. 151,152Tm deduced Q(EC), log ft. 152Tm, 152,151Er levels deduced γ-branching. NUCLEAR REACTIONS 96Ru(58Ni, 2p), (58Ni, n2p), (58Ni, 3p), (58Ni, n3p), (58Ni, 4p), (58Ni, 2pα), E=238, 250 MeV; measured Eγ, Iγ, γγ-coin, γγ(t); deduced residuals relative yield. 151Tm deduced levels, isomer T1/2, γ-branching. 152Yb deduced levels, isomer T1/2, B(E2), γ-branching. Thick target.
doi: 10.1007/BF01420148
1982PE13 Z.Phys. A308, 361 (1982) D.Pereira, H.-J.Korner, G.Korschinek, W.Mayer, H.-J.Scheerer Analogies between the (p, t) and the (14C, 16O) Reaction on Semi-Magic Nuclei NUCLEAR REACTIONS 140Ce, 142Nd, 144Sm(14C, 16O), E=71 MeV; measured σ(E(16O)), σ(θ). 138Ba, 140Ce, 142Nd level deduced collective characteristics, proton orbital coherence effect. Cluster transfer DWBA analysis.
doi: 10.1007/BF01415885
1980FR03 Phys.Lett. 90B, 229 (1980) R.M.Freeman, F.Haas, G.Korschinek Strong Resonant Behaviour of the 12C + 14C Reaction NUCLEAR REACTIONS 12C(14C, 14C'γ), (14C, 13C), (14C, 11B), (14C, 15N), E(cm)=18-26 MeV; measured σ(Eγ). 26Mg deduced strongly correlated resonances.
doi: 10.1016/0370-2693(80)90729-7
1980NO06 Z.Phys. A298, 191 (1980) Investigation of Very Neutron Deficient Ru and Rh Nuclei with the Help of (40Ca; yp + zαγ) Reactions RADIOACTIVITY 94Rh [from 58Ni(40Ca, ypzα), E=135, 160 MeV]; measured Eγ, Iγ; deduced log ft. 94Ru deduced levels, J, π, γ-branching. NUCLEAR REACTIONS 58Ni(40Ca, ypzα), E=135, 160 MeV; measured Eγ, Iγ, γ(θ), γγ-coin, DSA, recoil, γγ(t), σ(Eγ). 92,94Ru, 95Rh deduced levels, J, π, T1/2, γ-branching, B(λ), δ.
doi: 10.1007/BF01418657
1977KO05 Z.Phys. A281, 409 (1977) G.Korschinek, E.Nolte, H.Hick, K.Miyano, W.Kutschera, H.Morinaga Investigation of Neutron Deficient Zr and Nb Nuclei with Heavy Ion Induced Compound Reactions RADIOACTIVITY 87,84,86Nb, 87Mo; measured T1/2. NUCLEAR REACTIONS Fe, Ni, Se(32S, X), (12C, X); measured in-beam γ, γγ-coin, γ(θ). 84,86Zr deduced levels, J, π. 87Nb, 87Zr deduced transitions.
doi: 10.1007/BF01408190
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