NSR Query Results
Output year order : Descending NSR database version of April 11, 2024. Search: Author = O.Forstner Found 26 matches. 2021HI11 Phys.Rev. A 104, 012809 (2021) P.-M.Hillenbrand, K.N.Lyashchenko, S.Hagmann, O.Yu.Andreev, D.Banas, E.P.Benis, A.I.Bondarev, C.Brandau, E.De Filippo, O.Forstner, J.Glorius, R.E.Grisenti, A.Gumberidze, D.L.Guo, M.O.Herdrich, M.Lestinsky, Yu.A.Litvinov, E.V.Pagano, N.Petridis, M.S.Sanjari, D.Schury, U.Spillmann, S.Trotsenko, M.Vockert, A.B.Voitkiv, G.Weber, Th.Stohlker Electron-loss-to-continuum cusp in collisions of U89+ with N2 and Xe NUCLEAR REACTIONS N, Xe(U, X), E=75.91 MeV/nucleon; measured reaction products, Eβ, Iβ; deduced ionization, electron-loss-to-continuum (ELC) cusp, σ(θ, E). Comparison with calculations.
doi: 10.1103/PhysRevA.104.012809
2021KU15 Phys.Rev. C 103, 064605 (2021) J.Kuhtreiber, P.Hille, O.Forstner, H.Friedmann, A.Pavlik, A.Priller 6, 7Li + 27Al reactions close to and below the Coulomb barrier NUCLEAR REACTIONS 27Al(6Li, X), (7Li, X)33S*/34S*, E=6.0, 7.0, 8.0, 9.0, 10.0, 11.0, 12.0, 13.0 MeV from the VERA accelerator of the University of Vienna; measured reaction products, σ(E) by γ-ray measurements, Eγ, Iγ, complete fusion (CF) σ(E), production σ(E); deduced ratio of the formation cross section for different reaction products versus the complete fusion cross section. 30,31,32,33P, 28,29Si, 25,26Mg, 28,29Al; deduced formation σ(E). Comparison with EMPIRE and coupled-channel calculation with the computer code CCFULL calculations, and with experimental data for 16O(17O, X), (18O, X), E*=32-36 MeV; deduced that experimental data for 16O+17O and 16O+18O agree with predictions of statistical model, but such calculations fail for reaction with weakly bound 6,7Li nuclei due to fusion as well as breakup processes, where better agreement found with coupled-channel calculations.
doi: 10.1103/PhysRevC.103.064605
2020HI04 Phys.Rev. A 101, 022708 (2020) P.-M.Hillenbrand, S.Hagmann, M.E.Groshev, D.Banas, E.P.Benis, C.Brandau, E.De Filippo, O.Forstner, J.Glorius, R.E.Grisenti, A.Gumberidze, D.L.Guo, B.Hai, M.O.Herdrich, M.Lestinsky, Yu.A.Litvinov, E.V.Pagano, N.Petridis, M.S.Sanjari, D.Schury, U.Spillmann, S.Trotsenko, M.Vockert, G.Weber, V.A.Yerokhin, Th.Stohlker Radiative electron capture to the continuum in U89+ + N2 collisions: Experiment and theory NUCLEAR REACTIONS N(U, X), E=75.91 MeV/nucleon; measured reaction products, Eβ, Iβ, X-rays; deduced electron σ(θ, E). Comparison with theoretical calculations.
doi: 10.1103/PhysRevA.101.022708
2020RI02 Eur.Phys.J. A 56, 100 (2020) K.Riisager, M.J.G.Borge, J.A.Briz, M.Carmona-Gallardo, O.Forstner, L.M.Fraile, H.O.U.Fynbo, A.Garzon-Camacho, J.G.Johansen, B.Jonson, M.V.Lund, J.Lachner, M.Madurga, S.Merchel, E.Nacher, T.Nilsson, P.Steier, O.Tengblad, V.Vedia Search for beta-delayed proton emission from 11Be
doi: 10.1140/epja/s10050-020-00110-2
2019OZ03 Phys.Lett. B 797, 134800 (2019) F.C.Ozturk, B.Akkus, D.Atanasov, H.Beyer, F.Bosch, D.Boutin, C.Brandau, P.Buhler, R.B.Cakirli, R.J.Chen, W.D.Chen, X.C.Chen, I.Dillmann, C.Dimopoulou, W.Enders, H.G.Essel, T.Faestermann, O.Forstner, B.S.Gao, H.Geissel, R.Gernhauser, R.E.Grisenti, A.Gumberidze, S.Hagmann, T.Heftrich, M.Heil, M.O.Herdrich, P.-M.Hillenbrand, T.Izumikawa, P.Kienle, C.Klaushofer, C.Kleffner, C.Kozhuharov, R.K.Knobel, O.Kovalenko, S.Kreim, T.Kuhl, C.Lederer-Woods, M.Lestinsky, S.A.Litvinov, Yu.A.Litvinov, Z.Liu, X.W.Ma, L.Maier, B.Mei, H.Miura, I.Mukha, A.Najafi, D.Nagae, T.Nishimura, C.Nociforo, F.Nolden, T.Ohtsubo, Y.Oktem, S.Omika, A.Ozawa, N.Petridis, J.Piotrowski, R.Reifarth, J.Rossbach, R.Sanchez, M.S.Sanjari, C.Scheidenberger, R.S.Sidhu, H.Simon, U.Spillmann, M.Steck, Th.Stohlker, B.H.Sun, L.A.Susam, F.Suzaki, T.Suzuki, S.Yu.Torilov, C.Trageser, M.Trassinelli, S.Trotsenko, X.L.Tu, P.M.Walker, M.Wang, G.Weber, H.Weick, N.Winckler, D.F.A.Winters, P.J.Woods, T.Yamaguchi, X.D.Xu, X.L.Yan, J.C.Yang, Y.J.Yuan, Y.H.Zhang, X.H.Zhou New test of modulated electron capture decay of hydrogen-like 142Pm ions: Precision measurement of purely exponential decay RADIOACTIVITY 142Pm(EC); measured decay products; deduced T1/2.
doi: 10.1016/j.physletb.2019.134800
2019WA02 Phys.Rev. C 99, 015804 (2019) A.Wallner, M.Bichler, L.Coquard, I.Dillmann, O.Forstner, R.Golser, M.Heil, F.Kappeler, W.Kutschera, C.Lederer-Woods, M.Martschini, A.Mengoni, S.Merchel, L.Michlmayr, A.Priller, P.Steier, M.Wiescher Stellar and thermal neutron capture cross section of 9Be NUCLEAR REACTIONS 9Be(n, γ), kT=thermal, 5-100 keV, [neutrons from 7Li(p, n), E=1912, 2284 keV]; measured Maxwellian averaged σ(E) (MACS) using neutron activation combined with accelerator mass spectrometry (AMS) technique; deduced 10Be/9Be ratio in irradiated sample; calculated astrophysical reaction rates for T9=0.001 to 10 for s process nucleosynthesis calculations. Activation technique at Karlsruhe Van de Graaff accelerator, and TRIGA Mark-II reactor for thermal neutrons in combination with accelerator mass spectrometry at the Vienna Environmental Research Accelerator. Comparison with previous experimental values, compiled KADoNiS database, and evaluated libraries ENDF-B/VIII.1, JEFF-3.3, JENDL-4.0, BROND-3.1, and CENDL-3.1.
doi: 10.1103/PhysRevC.99.015804
2017RO21 J.Phys.(London) G44, 104003 (2017) S.Rothe, J.Sundberg, J.Welander, K.Chrysalidis, T.D.Goodacre, V.Fedosseev, S.Fiotakis, O.Forstner, R.Heinke, K.Johnston, T.Kron, U.Koster, Y.Liu, B.Marsh, A.Ringvall-Moberg, R.E.Rossel, C.Seiffert, D.Studer, K.Wendt, D.Hanstorp Laser photodetachment of radioactive 128I1 NUCLEAR REACTIONS 128I(γ, X), E<3.1 eV; measured reaction products; deduced the electron affinity (EA) of a radioactive isotope.
doi: 10.1088/1361-6471/aa80aa
2014RI01 Phys.Lett. B 732, 305 (2014) K.Riisager, O.Forstner, M.J.G.Borge, J.A.Briz, M.Carmona-Gallardo, L.M.Fraile, H.O.U.Fynbo, T.Giles, A.Gottberg, A.Heinz, J.G.Johansen, B.Jonson, J.Kurcewicz, M.V.Lund, T.Nilsson, G.Nyman, E.Rapisarda, P.Steier, O.Tengblad, R.Thies, S.R.Winkler 11Be(βp), a quasi-free neutron decay? RADIOACTIVITY 11Be(β-p) [from U(p, X)11Be, E=1.4 GeV]; measured decay products using AMS, Eγ, Iγ. 9,10Be; deduced branching ratio, Gamow-Teller resonance strength. Comparison with R-matrix calculations.
doi: 10.1016/j.physletb.2014.03.062
2013WA01 Nucl.Instrum.Methods Phys.Res. B294, 496 (2013) A.Wallner, K.Melber, S.Merchel, U.Ott, O.Forstner, R.Golser, W.Kutschera, A.Priller, P.Steier Stable platinum isotope measurements in presolar nanodiamonds by TEAMS
doi: 10.1016/j.nimb.2011.03.036
2011DE03 Phys.Rev. C 83, 015801 (2011) F.Dellinger, W.Kutschera, O.Forstner, R.Golser, A.Priller, P.Steier, A.Wallner, G.Winkler Upper limits for the existence of long-lived isotopes of roentgenium in natural gold ATOMIC MASSES 261,265,289,290,291,292,293,294,295,296Rg; measured abundance in natural gold using accelerator mass spectrometry (AMS). No events observed for 261Rg and 265Rg, not confirming a positive identification in another recent study. No events observed for 289,290,292,293,295,296Rg. Two and nine events recorded apparently for 291Rg and 294Rg, respectively could be explained otherwise, thus making positive identification for Rg unlikely. Upper limits established in the range of 1016.
doi: 10.1103/PhysRevC.83.015801
2011DE21 Phys.Rev. C 83, 065806 (2011) F.Dellinger, O.Forstner, R.Golser, A.Priller, P.Steier, A.Wallner, G.Winkler, W.Kutschera Ultrasensitive search for long-lived superheavy nuclides in the mass range A=288 to A=300 in natural Pt, Pb, and Bi ATOMIC MASSES 288,289,290,291,292,293,294,295Ds, 292,293,294,295,296,297,298,299Fl, 293,294,295,296,297,298,299,300Mc; measured abundance in natural platinum, lead, and bismuth samples using accelerator mass spectrometry (AMS) technique. Comparison with previous data. Ultrasensitive search for SHE in natural Pt, Pb and Bi samples proved negative with upper limits established.
doi: 10.1103/PhysRevC.83.065806
2011FO19 J.Phys.:Conf.Ser. 312, 082021 (2011) O.Forstner, P.Tornstrom, H.Friedmann, P.Hille, J.Kuhtreiber, A.Pavlik, A.Priller Light ion induced nuclear reactions close to the Coulomb barrier NUCLEAR REACTIONS 27Al(9Be, 2n), (9Be, pn), (9Be, 2nα), E≈8-13 MeV; measured reaction products; deduced σ; calculated σ using EMPIRE 2.19.
doi: 10.1088/1742-6596/312/4/082021
2010WA45 J.Phys.:Conf.Ser. 202, 012020 (2010) A.Wallner, K.Buczak, T.Belgya, M.Bichler, L.Coquard, I.Dillmann, O.Forstner, R.Golser, F.Kappeler, W.Kutschera, C.Lederer, A.Mengoni, A.Priller, R.Reifarth, P.Steier, L.Szentmiklosi Precise measurement of the neutron capture reaction 54Fe(n, γ)55Fe via AMS NUCLEAR REACTIONS 54Fe(n, γ), E=cold, thermal, 25 keV, 520 keV, 14 MeV; measured reaction products using activation and subsequent AMS (accelerator mass spectrometry); deduced σ. Compared with JEFF-3.1, ENDF-B-6.8, JENDL-3.3.
doi: 10.1088/1742-6596/202/1/012020
2009DI04 Phys.Rev. C 79, 065805 (2009) I.Dillmann, C.Domingo-Pardo, M.Heil, F.Kappeler, A.Wallner, O.Forstner, R.Golser, W.Kutschera, A.Priller, P.Steier, A.Mengoni, R.Gallino, M.Paul, C.Vockenhuber Determination of the stellar (n, γ) cross section of 40Ca with accelerator mass spectrometry NUCLEAR REACTIONS 40Ca(n, γ), E<106 keV; measured σ, σ(E) using activation technique and accelerator mass spectrometry; deduced Maxwellian averaged cross sections. Neutrons from 7Li(p, n)7Be reaction at E(p)=1912 keV. 197Au(n, γ), E<106 keV; measured σ and used as a standard. Comparison with previous experimental data and theoretical predictions.
doi: 10.1103/PhysRevC.79.065805
2008WA06 J.Phys.(London) G35, 014018 (2008) A.Wallner, L.Coquard, I.Dillmann, O.Forstner, R.Golser, M.Heil, F.Kappeler, W.Kutschera, A.Mengoni, L.Michlmayr, A.Priller, P.Steier, M.Wiescher Measurement of the stellar cross sections for the reactions 9Be(n, γ)10Be and 13C(n, γ)14C via AMS NUCLEAR REACTIONS 9Be(n, γ), E= spectrum; 13C(n, γ), E=spectrum; measured capture cross sections using a combination of activation technique and AMS. Comparisons with existing data.
doi: 10.1088/0954-3899/35/1/014018
2006JE02 Phys.Lett. B 635, 17 (2006) H.B.Jeppesen, A.M.Moro, T.Nilsson, F.Ames, P.van den Bergh, U.C.Bergmann, G.Bollen, M.J.G.Borge, J.Cederkall, P.Van Duppen, S.Emhofer, O.Forstner, L.M.Fraile, H.O.U.Fynbo, J.Gomez-Camacho, D.Habs, R.von Hahn, G.Huber, M.Huyse, H.T.Johansson, B.Jonson, O.Kester, H.Lenske, L.Liljeby, M.Meister, G.Nyman, M.Oinonen, M.Pantea, H.Podlech, U.Ratzinger, K.Reisinger, K.G.Rensfelt, R.Repnow, K.Riisager, A.Richter, K.Rudolph, H.Scheit, A.Schempp, P.Schmidt, G.Schrieder, D.Schwalm, T.Sieber, H.Simon, O.Tengblad, E.Tengborn, M.Turrion, L.Weissman, F.Wenander, B.Wolf Investigation of the 9Li + 2H → 8Li + t reaction at REX-ISOLDE NUCLEAR REACTIONS 2H(9Li, 8Li), E=2.36 MeV/nucleon; measured particle spectra, σ(θ). 8Li levels deduced energies, spectroscopic factors. Comparison with optical model calculations, post-accelerated radioactive beam.
doi: 10.1016/j.physletb.2006.02.034
2005NI09 Nucl.Phys. A752, 273c (2005) O.Niedermaier, H.Scheit, V.Bildstein, H.Boie, J.Fitting, R.von Hahn, F.Kock, M.Lauer, U.K.Pal, H.Podlech, R.Repnow, D.Schwalm, C.Alvarez, F.Ames, G.Bollen, S.Emhofer, D.Habs, O.Kester, R.Lutter, K.Rudolph, M.Pasini, P.G.Thirolf, B.H.Wolf, J.Eberth, G.Gersch, H.Hess, P.Reiter, O.Thelen, N.Warr, D.Weisshaar, F.Aksouh, P.Van den Bergh, P.Van Duppen, M.Huyse, O.Ivanov, P.Mayet, J.Van de Walle, J.Aysto, P.A.Butler, J.Cederkall, P.Delahaye, H.O.U.Fynbo, L.M.Fraile, O.Forstner, S.Franchoo, U.Koster, T.Nilsson, M.Oinonen, T.Sieber, F.Wenander, M.Pantea, A.Richter, G.Schrieder, H.Simon, T.Behrens, R.Gernhauser, T.Kroll, R.Krucken, M.Munch, T.Davinson, J.Gerl, G.Huber, A.Hurst, J.Iwanicki, B.Jonson, P.Lieb, L.Liljeby, A.Schempp, A.Scherillo, P.Schmidt, G.Walter The neutron-rich Mg isotopes: first results from MINIBALL at REX-ISOLDE NUCLEAR REACTIONS Ni(30Mg, 30Mg'), E=2.25 MeV/nucleon; measured Eγ, Iγ, (particle)γ-coin following projectile Coulomb excitation. 30Mg deduced transition, B(E2).
doi: 10.1016/j.nuclphysa.2005.02.071
2005NI11 Phys.Rev.Lett. 94, 172501 (2005) O.Niedermaier, H.Scheit, V.Bildstein, H.Boie, J.Fitting, R.von Hahn, F.Kock, M.Lauer, U.K.Pal, H.Podlech, R.Repnow, D.Schwalm, C.Alvarez, F.Ames, G.Bollen, S.Emhofer, D.Habs, O.Kester, R.Lutter, K.Rudolph, M.Pasini, P.G.Thirolf, B.H.Wolf, J.Eberth, G.Gersch, H.Hess, P.Reiter, O.Thelen, N.Warr, D.Weisshaar, F.Aksouh, P.Van den Bergh, P.Van Duppen, M.Huyse, O.Ivanov, P.Mayet, J.Van de Walle, J.Aysto, P.A.Butler, J.Cederkall, P.Delahaye, H.O.U.Fynbo, L.M.Fraile, O.Forstner, S.Franchoo, U.Koster, T.Nilsson, M.Oinonen, T.Sieber, F.Wenander, M.Pantea, A.Richter, G.Schrieder, H.Simon, T.Behrens, R.Gernhauser, T.Kroll, R.Krucken, M.Munch, T.Davinson, J.Gerl, G.Huber, A.Hurst, J.Iwanicki, B.Jonson, P.Lieb, L.Liljeby, A.Schempp, A.Scherillo, P.Schmidt, G.Walter "Safe" Coulomb Excitation of 30Mg NUCLEAR REACTIONS Ni(30Mg, 30Mg'), E=2.25 MeV/nucleon; measured Eγ, Iγ, (particle)γ-coin following projectile Coulomb excitation. 30Mg transition deduced B(E2).
doi: 10.1103/PhysRevLett.94.172501
2005SC27 Eur.Phys.J. A 25, Supplement 1, 397 (2005) H.Scheit, O.Niedermaier, V.Bildstein, H.Boie, J.Fitting, R.von Hahn, F.Kock, M.Lauer, U.K.Pal, H.Podlech, R.Repnow, D.Schwalm, C.Alvarez, F.Ames, G.Bollen, S.Emhofer, D.Habs, O.Kester, R.Lutter, K.Rudolph, M.Pasini, P.G.Thirolf, B.H.Wolf, J.Eberth, G.Gersch, H.Hess, P.Reiter, O.Thelen, N.Warr, D.Weisshaar, F.Aksouh, P.Van den Bergh, P.Van Duppen, M.Huyse, O.Ivanov, P.Mayet, J.Van de Walle, J.Aysto, P.A.Butler, J.Cederkall, P.Delahaye, H.O.U.Fynbo, L.M.Fraile, O.Forstner, S.Franchoo, U.Koster, T.Nilsson, M.Oinonen, T.Sieber, F.Wenander, M.Pantea, A.Richter, G.Schrieder, H.Simon, T.Behrens, R.Gernhauser, T.Kroll, R.Krucken, M.Munch, T.Davinson, J.Gerl, G.Huber, A.Hurst, J.Iwanicki, B.Jonson, P.Lieb, L.Liljeby, A.Schempp, A.Scherillo, P.Schmidt, G.Walter Coulomb excitation of neutron-rich beams at REX-ISOLDE NUCLEAR REACTIONS Ni(30Mg, 30Mg'), E=2.2 MeV/nucleon; measured Eγ, Iγ, (particle)γ-coin following projectile Coulomb excitation.2Hmeasured Eγ, Iγ, γγ-, (particle)γ-coin. 30Mg deduced transitions B(E2). 31Mg deduced transitions. Miniball array.
doi: 10.1140/epjad/i2005-06-165-2
2002BE54 Nucl.Phys. A701, 369c (2002) D.Beck, F.Ames, M.Beck, G.Bollen, B.Delaure, J.Deutsch, J.Dilling, O.Forstner, T.Phalet, R.Prieels, W.Quint, P.Schmidt, P.Schuurmans, N.Severijns, B.Vereecke, S.Versyck, and the EUROTRAPS Collaboration Search for New Physics in Beta-Neutrino Correlations with the WITCH Spectrometer
doi: 10.1016/S0375-9474(01)01612-8
2002SC25 Nucl.Phys. A701, 550c (2002) P.Schmidt, F.Ames, G.Bollen, O.Forstner, G.Huber, M.Oinonen, J.Zimmer, and the REX-ISOLDE Collaboration Bunching and Cooling of Radioactive Ions with REXTRAP
doi: 10.1016/S0375-9474(01)01642-6
2001AM12 Hyperfine Interactions 132, 469 (2001) F.Ames, P.Schmidt, O.Forstner, G.Bollen, O.Engels, D.Habs, G.Huber, and the REX ISOLDE Collaboration Space-Charge Effects with REXTRAP
doi: 10.1023/A:1011922811309
2001BE74 Hyperfine Interactions 132, 473 (2001) D.Beck, F.Ames, M.Beck, G.Bollen, B.Delaure, P.Schuurmans, S.Schwarz, P.Schmidt, N.Severijns, O.Forstner Space Charge Effects in a Gas Filled Penning Trap
doi: 10.1023/A:1011974828147
2001FO07 Phys.Rev. C64, 045801 (2001) O.Forstner, H.Herndl, H.Oberhummer, H.Schatz, B.A.Brown Thermonuclear Reaction Rate of 56Ni(p, γ)57Cu and 57Cu(p, γ)58Zn NUCLEAR REACTIONS 56Ni, 57Cu(p, γ), E=stellar; calculated reaction rates. Astrophysical implications discussed. NUCLEAR STRUCTURE 57,58Ni, 57Cu, 58Zn; calculated energy levels, level shifts. 57Cu, 58Zn; calculated shell model spectroscopic factors.
doi: 10.1103/PhysRevC.64.045801
2001WE19 Hyperfine Interactions 132, 535 (2001) L.Weissman, F.Ames, J.Aysto, O.Forstner, S.Rinta-Antila, P.Schmidt, and the ISOLDE Collaboration Feasibilty of In-Trap Conversion Electron Spectroscopy RADIOACTIVITY 116mIn(β-); 131Ba(EC); measured E(ce), I(ce). Trapped ions.
doi: 10.1023/A:1011964020395
2000HA68 Hyperfine Interactions 129, 43 (2000) D.Habs, O.Kester, T.Sieber, H.Bongers, S.Emhofer, P.Reiter, P.G.Thirolf, G.Bollen, J.Aysto, O.Forstner, H.Ravn, T.Nilsson, M.Oinonen, H.Simon, J.Cederkall, F.Ames, P.Schmidt, G.Huber, L.Liljeby, O.Skeppstedt, K.G.Rensfelt, F.Wenander, B.Jonson, G.Nyman, R.von Hahn, H.Podlech, R.Repnow, C.Gund, D.Schwalm, A.Schempp, K.-U.Kuhnel, C.Welsch, U.Ratzinger, G.Walter, A.Huck, K.Kruglov, M.Huyse, P.Van den Bergh, P.Van Duppen, L.Weissman, A.C.Shotter, A.N.Ostrowski, T.Davinson, P.J.Woods, J.Cub, A.Richter, G.Schrieder, and the REX-ISOLDE Collaboration The REX-ISOLDE project
doi: 10.1023/A:1012603025802
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