NSR Query Results
Output year order : Descending NSR database version of April 27, 2024. Search: Author = M.Lindner Found 38 matches. 2024AG03 Eur.Phys.J. C 84, 34 (2024) M.Agostini, A.Alexander, G.R.Araujo, A.M.Bakalyarov, M.Balata, I.Barabanov, L.Baudis, C.Bauer, S.Belogurov, A.Bettini, L.Bezrukov, V.Biancacci, E.Bossio, V.Bothe, V.Brudanin, R.Brugnera, A.Caldwell, C.Cattadori, A.Chernogorov, T.Comellato, V.D'Andrea, E.V.Demidova, N.D.Marco, E.Doroshkevich, F.Fischer, M.Fomina, A.Gangapshev, A.Garfagnini, C.Gooch, P.Grabmayr, V.Gurentsov, K.Gusev, J.Hakenmuller, S.Hemmer, W.Hofmann, J.Huang, M.Hult, L.V.Inzhechik, J.J.Csathy, J.Jochum, M.Junker, V.Kazalov, Y.Kermaidic, H.Khushbakht, T.Kihm, K.Kilgus, I.V.Kirpichnikov, A.Klimenko, R.Kneißl, K.T.Knopfle, O.Kochetov, V.N.Kornoukhov, M.Korosec, P.Krause, V.V.Kuzminov, M.Laubenstein, M.Lindner, I.Lippi, A.Lubashevskiy, B.Lubsandorzhiev, G.Lutter, C.Macolino, B.Majorovits, W.Maneschg, L.Manzanillas, G.Marshall, M.Misiaszek, M.Morella, Y.Muller, I.Nemchenok, L.Pandola, K.Pelczar, L.Pertoldi, P.Piseri, A.Pullia, C.Ransom, L.Rauscher, M.Redchuk, S.Riboldi, N.Rumyantseva, C.Sada, F.Salamida, S.Schonert, J.Schreiner, M.Schutt, A.-K.Schutz, O.Schulz, M.Schwarz, B.Schwingenheuer, O.Selivanenko, E.Shevchik, M.Shirchenko, L.Shtembari, H.Simgen, A.Smolnikov, D.Stukov, A.A.Vasenko, A.Veresnikova, C.Vignoli, K.v.Sturm, T.Wester, C.Wiesinger, M.Wojcik, E.Yanovich, B.Zatschler, I.Zhitnikov, S.V.Zhukov, D.Zinatulina, A.Zschocke, A.J.Zsigmond, K.Zuber, G.Zuzel, GERDA Collaboration An improved limit on the neutrinoless double-electron capture of 36Ar with GERDA RADIOACTIVITY 36Ar(2EC); measured decay products, Eγ, Iγ; deduced T1/2 limit. Comparison with available data. The GERmanium Detector Array (Gerda) experiment.
doi: 10.1140/epjc/s10052-023-12280-6
2024AP01 Eur.Phys.J. C 84, 138 (2024) E.Aprile, K.Abe, S.Ahmed Maouloud, L.Althueser, B.Andrieu, E.Angelino, J.R.Angevaare, V.C.Antochi, D.Anton Martin, F.Arneodo, L.Baudis, A.L.Baxter, M.Bazyk, L.Bellagamba, R.Biondi, A.Bismark, E.J.Brookes, A.Brown, S.Bruenner, G.Bruno, R.Budnik, T.K.Bui, C.Cai, J.M.R.Cardoso, D.Cichon, A.P.Cimental Chavez, A.P.Colijn, J.Conrad, J.J.Cuenca-Garcia, J.P.Cussonneau, V.D'Andrea, M.P.Decowski, P.Di Gangi, S.Diglio, K.Eitel, A.Elykov, S.Farrell, A.D.Ferella, C.Ferrari, H.Fischer, M.Flierman, W.Fulgione, C.Fuselli, P.Gaemers, R.Gaior, A.Gallo Rosso, M.Galloway, F.Gao, R.Glade-Beucke, L.Grandi, J.Grigat, H.Guan, M.Guida, R.Hammann, A.Higuera, C.Hils, L.Hoetzsch, N.F.Hood, J.Howlett, M.Iacovacci, Y.Itow, J.Jakob, F.Joerg, A.Joy, M.Kara, P.Kavrigin, S.Kazama, M.Kobayashi, G.Koltman, A.Kopec, F.Kuger, H.Landsman, R.F.Lang, L.Levinson, I.Li, S.Li, S.Liang, S.Lindemann, M.Lindner, K.Liu, J.Loizeau, F.Lombardi, J.Long, J.A.M.Lopes, Y.Ma, C.Macolino, J.Mahlstedt, A.Mancuso, L.Manenti, F.Marignetti, T.Marrodan Undagoitia, K.Martens, J.Masbou, D.Masson, E.Masson, S.Mastroianni, M.Messina, K.Miuchi, A.Molinario, S.Moriyama, K.Mora, Y.Mosbacher, M.Murra, J.Muller, K.Ni, U.Oberlack, B.Paetsch, J.Palacio, Q.Pellegrini, R.Peres, C.Peters, J.Pienaar, M.Pierre, G.Plante, T.R.Pollmann, J.Qi, J.Qin, D.Ramirez Garcia, N.Sarcevic, J.Shi, R.Singh, L.Sanchez, J.M.F.dos Santos, I.Sarnoff, G.Sartorelli, J.Schreiner, D.Schulte, P.Schulte, H.Schulze Eissing, M.Schumann, L.Scotto Lavina, M.Selvi, F.Semeria, P.Shagin, S.Shi, E.Shockley, M.Silva, H.Simgen, A.Takeda, P.-L.Tan, A.Terliuk, D.Thers, F.Toschi, G.Trinchero, C.Tunnell, F.Tonnies, K.Valerius, G.Volta, C.Weinheimer, M.Weiss, D.Wenz, C.Wittweg, T.Wolf, V.H.S.Wu, Y.Xing, D.Xu, Z.Xu, M.Yamashita, L.Yang, J.Ye, L.Yuan, G.Zavattini, M.Zhong, T.Zhu, XENON collaboration Design and performance of the field cage for the XENONnT experiment
doi: 10.1140/epjc/s10052-023-12296-y
2023AG05 Phys.Rev.Lett. 131, 142501 (2023) M.Agostini, A.Alexander, G.R.Araujo, A.M.Bakalyarov, M.Balata, I.Barabanov, L.Baudis, C.Bauer, S.Belogurov, A.Bettini, L.Bezrukov, V.Biancacci, E.Bossio, V.Bothe, R.Brugnera, A.Caldwell, S.Calgaro, C.Cattadori, A.Chernogorov, P.-J.Chiu, T.Comellato, V.D'Andrea, E.V.Demidova, A.Di Giacinto, N.Di Marco, E.Doroshkevich, F.Fischer, M.Fomina, A.Gangapshev, A.Garfagnini, C.Gooch, P.Grabmayr, V.Gurentsov, K.Gusev, S.Hackenmuller, S.Hemmer, W.Hofmann, J.Huang, M.Hult, L.V.Inzhechik, J.Janicsko Csathy, J.Jochum, M.Junker, V.Kazalov, Y.Kermaidic, H.Khushbakht, T.Kihm, K.Kilgus, I.V.Kirpichnikov, A.Klimenko, K.T.Knopfle, O.Kochetov, V.N.Kornoukhov, P.Krause, V.V.Kuzminov, M.Laubenstein, B.Lehnert, M.Lindner, I.Lippi, A.Lubashevskiy, B.Lubsandorzhiev, G.Lutter, C.Macolino, B.Majorovits, W.Maneschg, L.Manzanillas, G.Marshall, M.Miloradovic, R.Mingazheva, M.Misiaszek, M.Morella, Y.Muller, I.Nemchenok, M.Neuberger, L.Pandola, K.Pelczar, L.Pertoldi, P.Piseri, A.Pullia, C.Ransom, L.Rauscher, M.Redchuk, S.Riboldi, N.Rumyantseva, C.Sada, S.Sailer, F.Salamida, S.Schonert, J.Schreiner, M.Schutt, A.-K.Schutz, O.Schulz, M.Schwarz, B.Schwingenheuer, O.Selivanenko, E.Shevchik, M.Shirchenko, L.Shtembari, H.Simgen, A.Smolnikov, D.Stukov, S.Sullivan, A.A.Vasenko, A.Veresnikova, C.Vignoli, K.von Sturm, T.Wester, C.Wiesinger, M.Wojcik, E.Yanovich, B.Zatschler, I.Zhitnikov, S.V.Zhukov, D.Zinatulina, A.Zschocke, A.J.Zsigmond, K.Zuber, G.Zuzel Final Results of GERDA on the Two-Neutrino Double-β Decay Half-Life of 76Ge RADIOACTIVITY 76Ge(2β-); measured decay products, Eβ, Iβ; deduced two-neutrino mode T1/2, effective nuclear matrix elements. Comparison with available data. The GERDA experiment was located underground at the Laboratori Nazionali del Gran Sasso (LNGS) of INFN, in Italy.
doi: 10.1103/PhysRevLett.131.142501
2023AL08 Eur.Phys.J. A 59, 75 (2023) H.Almazan, L.Bernard, A.Blanchet, A.Bonhomme, C.Buck, A.Chalil, A.Chebboubi, P.del Amo Sanchez, I.El Atmani, L.Labit, J.Lamblin, A.Letourneau, D.Lhuillier, M.Licciardi, M.Lindner, O.Litaize, T.Materna, H.Pessard, J.-S.Real, J.-S.Ricol, C.Roca, R.Rogly, T.Salagnac, V.Savu, S.Schoppmann, T.Soldner, A.Stutz, L.Thulliez, M.Vialat Improved FIFRELIN de-excitation model for neutrino applications NUCLEAR STRUCTURE 156,158Gd; analyzed available data; deduced the de-excitation of Gd isotopes using the FIFRELIN Monte Carlo code built on the low-energy level scheme with extensive use of known evaluated nuclear levels from the RIPL-3 database within the purposes of the STEREO experiment.
doi: 10.1140/epja/s10050-023-00977-x
2023AP04 Phys.Rev. D 108, 072015 (2023) E.Aprile, K.Abe, S.Ahmed Maouloud, L.Althueser, B.Andrieu, E.Angelino, J.R.Angevaare, V.C.Antochi, D.Anton Martin, F.Arneodo, L.Baudis, A.L.Baxter, M.Bazyk, L.Bellagamba, R.Biondi, A.Bismark, E.J.Brookes, A.Brown, S.Bruenner, G.Bruno, R.Budnik, T.K.Bui, C.Cai, J.M.R.Cardoso, A.P.Cimental Chavez, A.P.Colijn, J.Conrad, J.J.Cuenca-Garcia, V.D'Andrea, M.P.Decowski, P.Di Gangi, S.Diglio, K.Eitel, A.Elykov, S.Farrell, A.D.Ferella, C.Ferrari, H.Fischer, M.Flierman, W.Fulgione, C.Fuselli, P.Gaemers, R.Gaior, A.Gallo Rosso, M.Galloway, F.Gao, R.Glade-Beucke, L.Grandi, J.Grigat, H.Guan, M.Guida, R.Hammann, A.Higuera, C.Hils, L.Hoetzsch, N.F.Hood, J.Howlett, M.Iacovacci, Y.Itow, J.Jakob, F.Joerg, A.Joy, M.Kara, P.Kavrigin, S.Kazama, M.Kobayashi, G.Koltman, A.Kopec, F.Kuger, H.Landsman, R.F.Lang, D.G.Layos Carlos, L.Levinson, I.Li, S.Li, S.Liang, S.Lindemann, M.Lindner, K.Liu, J.Loizeau, F.Lombardi, J.Long, J.A.M.Lopes, Y.Ma, C.Macolino, J.Mahlstedt, A.Mancuso, L.Manenti, F.Marignetti, T.Marrodan Undagoitia, K.Martens, J.Masbou, D.Masson, E.Masson, S.Mastroianni, M.Messina, K.Miuchi, A.Molinario, S.Moriyama, K.Moraa, Y.Mosbacher, M.Murra, J.Muller, K.Ni, U.Oberlack, B.Paetsch, J.Palacio, Q.Pellegrini, R.Peres, C.Peters, J.Pienaar, M.Pierre, G.Plante, T.R.Pollmann, J.Qi, J.Qin, D.Ramirez Garcia, J.Shi, R.Singh, L.Sanchez, J.M.F.dos Santos, I.Sarnoff, G.Sartorelli, J.Schreiner, D.Schulte, P.Schulte, H.Schulze Eissing, M.Schumann, L.Scotto Lavina, M.Selvi, F.Semeria, P.Shagin, S.Shi, E.Shockley, M.Silva, H.Simgen, A.Takeda, P.-L.Tan, A.Terliuk, D.Thers, F.Toschi, G.Trinchero, C.Tunnell, F.Tonnies, K.Valerius, G.Volta, C.Weinheimer, M.Weiss, D.Wenz, C.Wittweg, T.Wolf, V.H.S.Wu, Y.Xing, D.Xu, Z.Xu, M.Yamashita, L.Yang, J.Ye, L.Yuan, G.Zavattini, M.Zhong, T.Zhu Search for events in XENON1T associated with gravitational waves
doi: 10.1103/PhysRevD.108.072015
2022AP04 Phys.Rev.Lett. 129, 161805 (2022) E.Aprile, K.Abe, F.Agostini, S.Ahmed Maouloud, L.Althueser, B.Andrieu, E.Angelino, J.R.Angevaare, V.C.Antochi, D.Anton Martin, F.Arneodo, L.Baudis, A.L.Baxter, L.Bellagamba, R.Biondi, A.Bismark, A.Brown, S.Bruenner, G.Bruno, R.Budnik, T.K.Bui, C.Cai, C.Capelli, J.M.R.Cardoso, D.Cichon, M.Clark, A.P.Colijn, J.Conrad, J.J.Cuenca-Garcia, J.P.Cussonneau, V.D'Andrea, M.P.Decowski, P.Di Gangi, S.Di Pede, A.Di Giovanni, R.Di Stefano, S.Diglio, K.Eitel, A.Elykov, S.Farrell, A.D.Ferella, C.Ferrari, H.Fischer, W.Fulgione, P.Gaemers, R.Gaior, A.Gallo Rosso, M.Galloway, F.Gao, R.Gardner, R.Glade-Beucke, L.Grandi, J.Grigat, M.Guida, R.Hammann, A.Higuera, C.Hils, L.Hoetzsch, J.Howlett, M.Iacovacci, Y.Itow, J.Jakob, F.Joerg, A.Joy, N.Kato, M.Kara, P.Kavrigin, S.Kazama, M.Kobayashi, G.Koltman, A.Kopec, F.Kuger, H.Landsman, R.F.Lang, L.Levinson, I.Li, S.Li, S.Liang, S.Lindemann, M.Lindner, K.Liu, J.Loizeau, F.Lombardi, J.Long, J.A.M.Lopes, Y.Ma, C.Macolino, J.Mahlstedt, A.Mancuso, L.Manenti, F.Marignetti, T.Marrodan Undagoitia, K.Martens, J.Masbou, D.Masson, E.Masson, S.Mastroianni, M.Messina, K.Miuchi, K.Mizukoshi, A.Molinario, S.Moriyama, K.Mora, Y.Mosbacher, M.Murra, J.Muller, K.Ni, U.Oberlack, B.Paetsch, J.Palacio, P.Paschos, R.Peres, C.Peters, J.Pienaar, M.Pierre, V.Pizzella, G.Plante, J.Qi, J.Qin, D.Ramirez Garcia, S.Reichard, A.Rocchetti, N.Rupp, L.Sanchez, J.M.F.dos Santos, I.Sarnoff, G.Sartorelli, J.Schreiner, D.Schulte, P.Schulte, H.Schulze Eissing, M.Schumann, L.Scotto Lavina, M.Selvi, F.Semeria, P.Shagin, S.Shi, E.Shockley, M.Silva, H.Simgen, J.Stephen, A.Takeda, P.-L.Tan, A.Terliuk, D.Thers, F.Toschi, G.Trinchero, C.Tunnell, F.Tonnies, K.Valerius, G.Volta, Y.Wei, C.Weinheimer, M.Weiss, D.Wenz, C.Wittweg, T.Wolf, D.Xu, Z.Xu, M.Yamashita, L.Yang, J.Ye, L.Yuan, G.Zavattini, M.Zhong, T.Zhu Search for New Physics in Electronic Recoil Data from XENONnT RADIOACTIVITY 124Xe(2EC); measured decay products, X-rays; deduced T1/2. Comparison with available data. The XENONnT experiment, located at the INFN Laboratori Nazionali del Gran Sasso (LNGS) in Italy, was designed as a fast upgrade of XENON1T and inherits many of its systems such as cooling, gas storage, purification, and Kr removal.
doi: 10.1103/PhysRevLett.129.161805
2022SA21 Prog.Part.Nucl.Phys. 124, 103947 (2022) M.Sajjad Athar, St.W.Barwick, T.Brunner, J.Cao, M.Danilov, K.Inoue, T.Kajita, M.Kowalski, M.Lindner, K.R.Long, N.Palanque-Delabrouille, W.Rodejohann, H.Schellman, K.Scholberg, S.-H.Seo, N.J.T.Smith, W.Winter, G.P.Zeller, R.Zukanovich-Funchal Status and perspectives of neutrino physics
doi: 10.1016/j.ppnp.2022.103947
2021AL19 J.Phys.(London) G48, 075107 (2021) H.Almazan, L.Bernard, A.Blanchet, A.Bonhomme, C.Buck, P.del Amo Sanchez, I.El Atmani, L.Labit, J.Lamblin, A.Letourneau, D.Lhuillier, M.Licciardi, M.Lindner, T.Materna, H.Pessard, J.-S.Real, J.-S.Ricol, C.Roca, R.Rogly, T.Salagnac, V.Savu, S.Schoppmann, V.Sergeyeva, T.Soldner, A.Stutz, M.Vialat First antineutrino energy spectrum from 235U fissions with the STEREO detector at ILL NUCLEAR REACTIONS 1H(ν-bar, e+)1NN, E<7 MeV; measured reaction products, Eβ, Iβ, En, In. 235U; deduced inverse beta decay (IBD) yield spectrum, the total antineutrino rate. Comparison with available data.
doi: 10.1088/1361-6471/abd37a
2019AL30 Eur.Phys.J. A 55, 183 (2019) H.Almazan, L.Bernard, A.Blanchet, A.Bonhomme, C.Buck, A.Chebboubi, P.del Amo Sanchez, I.El Atmani, J.Haser, F.Kandzia, S.Kox, L.Labit, J.Lamblin, A.Letourneau, D.Lhuillier, M.Lindner, O.Litaize, T.Materna, A.Minotti, H.Pessard, J.-S.Real, C.Roca, T.Salagnac, V.Savu, S.Schoppmann, V.Sergeyeva, T.Soldner, A.Stutz, L.Thulliez, M.Vialat Improved STEREO simulation with a new gamma ray spectrum of excited gadolinium isotopes using FIFRELIN
doi: 10.1140/epja/i2019-12886-y
2017BU02 Phys.Lett. B 765, 159 (2017) C.Buck, A.P.Collin, J.Haser, M.Lindner Investigating the spectral anomaly with different reactor antineutrino experiments NUCLEAR REACTIONS 235U(n, F), E thermal; analyzed available data; deduced a need for a new measurement of the spectral shape of reactor antineutrinos.
doi: 10.1016/j.physletb.2016.11.062
2017GE01 Phys.Rev. D 95, 033003 (2017) Extracting Majorana properties from strong bounds on neutrinoless double beta decay
doi: 10.1103/PhysRevD.95.033003
2006LI14 Phys.Rev. D 73, 053005 (2006) M.Lindner, A.Merle, W.Rodejohann Improved limit on θ13 and implications for neutrino masses in neutrinoless double beta decay and cosmology
doi: 10.1103/PhysRevD.73.053005
1990LI09 Radiochim.Acta 49, 1 (1990) Reactor Neutron Fission Characteristics of the Long-Lived Isomer of Neptunium 236 NUCLEAR REACTIONS 236Np(n, F), E=thermal; measured fission product mass yields, σ. Target from 235U+d reaction.
doi: 10.1524/ract.1990.49.1.1
1989LI30 Geochim.Cosmochim.Act. 53, 1597 (1989) M.Lindner, D.A.Leich, G.P.Russ, J.M.Bazan, R.J.Borg Direct Determination of the Half-Life of 187Re RADIOACTIVITY 187Re(β-); measured T1/2. Isotope dilution method, inductively coupled plasma mass spectrometry. Astrophysical implications discussed.
doi: 10.1016/0016-7037(89)90241-X
1987LI16 Phys.Rev. C36, 1132 (1987) M.Lindner, R.Gunnink, R.J.Nagle Determination of the Absolute K through O Conversion Coefficients of the 80-keV M4 Transition in 193mIr RADIOACTIVITY 193mIr(IT) [from 192Os(n, γ)193Os(β-)-decay]; measured I(ce). 193Ir deduced M4 transition subshell ICC.
doi: 10.1103/PhysRevC.36.1132
1986LI11 Nature(London) 320, 246 (1986) M.Lindner, D.A.Leich, R.J.Borg, G.P.Russ, J.M.Bazan, D.S.Simons, A.R.Date Direct Laboratory Determination of the 187Re Half-Life RADIOACTIVITY 187Re(β-); measured T1/2. Laser microprobe mass analyzer, inductively coupled plasma spectrometer.
doi: 10.1038/320246a0
1986LI18 Radiochim.Acta 39, 159 (1986) M.Lindner, E.S.Delucchi, D.A.Leich Separation of Carrier-Free 185Os, 183Re and 184Re from Irradiated Tungsten Targets NUCLEAR REACTIONS, ICPND 180,182,183,184,186W(α, xn), (α, xp)185Os/183Re/184Re, E=65 MeV; measured γ-spectra; deduced residual chemical fractions, production σ. Chemical separation.
1981LI30 J.Inorg.Nucl.Chem. 43, 3071 (1981) M.Lindner, R.J.Dupzyk, R.W.Hoff, R.J.Nagle Lifetime of the Long-Lived Isomer of 236Np from α-, β- and Electron-Capture Decay Measurements RADIOACTIVITY 236Np(EC), (α), (β-); measured Eγ, Iγ, Eα, Iα, γγ-coin, I(ce), T1/2; deduced relative β-, EC-, α-branching, log ft, Qβ, Q(EC). 236Pu levels deduced γ-branching, transition energy. 236U levels deduced γ-branching. Compton suppression, mass spectrometric isotope ratio measurements, 232Pa decay input.
doi: 10.1016/0022-1902(81)80064-4
1977BR22 Phys.Rev. C16, 747 (1977) D.S.Brenner, M.Lindner, R.A.Meyer Unique First Forbidden Beta Decay of 183Re and 185Os RADIOACTIVITY 183Re, 185Os; measured Eγ, Iγ, T1/2; deduced log ft. 183W, 185Re deduced levels, J, π. Ge(Li) detectors.
doi: 10.1103/PhysRevC.16.747
1975MY01 J.Inorg.Nucl.Chem. 37, 637 (1975) W.A.Myers, M.Lindner, R.S.Newbury The Isomer Ratio 236Np(l)/236Np(s) in the Reaction 237Np(n, 2n)236Np From Neutrons Produced in Thermonuclear Devices NUCLEAR REACTIONS 237Np(n, 2n), E=thermonuclear spectrum; measured yield ratio for 236mNp/236Np.
doi: 10.1016/0022-1902(75)80512-4
1973LA28 Phys.Rev. C8, 1938 (1973) J.H.Landrum, R.J.Nagle, M.Lindner (n, 2n) Cross Sections for 238U and 237Np in the Region of 14 MeV NUCLEAR REACTIONS 237Np, 238U(n, 2n), E=13.7-14.9 MeV; measured σ, production σ for 237U, 236Pu.
doi: 10.1103/PhysRevC.8.1938
1972SE06 Nucl.Phys. A185, 94 (1972) D.W.Seegmiller, M.Lindner, R.A.Meyer 186Re: Nuclear Structure and an Isomer of Half-Life 2 X 105 y RADIOACTIVITY 186mRe; measured T1/2, Eγ, Iγ, E(X-ray), I(X-ray), I(ce); deduced levels, J, π, ICC, γ-multipolarity. Nilsson assignment.
doi: 10.1016/0375-9474(72)90553-2
1962MI16 Phys.Rev. 128, 2717 (1962) J.A.Miskel, K.V.Marsh, M.Lindner, R.J.Nagle Neutron Activation Cross Sections NUCLEAR REACTIONS 180Hf(n, γ), 181Ta(n, γ), 186W(n, γ), 197Au(n, γ), 232Th(n, γ), E=-1.0 eV-3.9 MeV; measured products, 181Hf, Eγ, Iγ; deduced σ, σ(E). Data were imported from EXFOR entry 12115.
doi: 10.1103/PhysRev.128.2717
1961HU01 J.Inorg.Nuclear Chem. 16, 369 (1961) The Nuclide Hf182 NUCLEAR STRUCTURE 182Hf; measured not abstracted; deduced nuclear properties.
doi: 10.1016/0022-1902(61)80520-4
1960LI14 J.Inorg.Nuclear Chem. 15, 194 (1960) M.Lindner, K.V.Marsh, J.A.Miskel, R.J.Nagle The Half-Life of 181Hf NUCLEAR STRUCTURE 181Hf; measured not abstracted; deduced nuclear properties.
doi: 10.1016/0022-1902(60)80034-6
1957OL05 Phys.Rev. 106, 985 (1957) J.L.Olsen, L.G.Mann, M.Lindner Internal Bremsstrahlung and Decay Scheme of Sb119
doi: 10.1103/PhysRev.106.985
1956LI47 Phys.Rev. 103, 378 (1956) Nonfission Inelastic Events In Uranium And Thorium Induced By High-Energy Protons NUCLEAR REACTIONS U(p, x), E=100-340 MeV; measured products, 228Ra, 224Ac, 228Ac, 226Th, 228Pa, 232Pa, 232U, 236Np, 238Np, 224Th, 224Ra, 225Ac, 226Ac, 227Th, 228Th, 231Th, 234Th, 230Pa, 235Pa, 228U, 229U, 230U, 225Ra, 223Ra; deduced σ, σ(E). Data were imported from EXFOR entry C0367.
doi: 10.1103/PhysRev.103.378
1954LI49 Phys.Rev. 94, 1323 (1954) Some Studies of the Products of the High-Energy Fission Process NUCLEAR REACTIONS 232Th(α, f), 232Th(d, f), 232Th(p, f), 238U(α, f), 238U(d, f), 238U(p, f), E=29.8-383 MeV; measured products, 139Ba, 97Zr, 111Ag, 131Ba, 66Ni; deduced σ, σ(E). Data were imported from EXFOR entry P0046.
doi: 10.1103/PhysRev.94.1323
1953LI21 Phys.Rev. 91, 642 (1953) New Nuclides Produced in Chlorine Spallation
doi: 10.1103/PhysRev.91.642
1953LI28 Phys.Rev. 91, 1501 (1953) Energy Dependence of the Cross Section for the Reaction C12(α, αn)C11 NUCLEAR REACTIONS 12C(α, nα), E=22-380 MeV; measured products, 11C, 4He, Eν, Iν; deduced σ, σ(E). Data were imported from EXFOR entry C0702.
doi: 10.1103/PhysRev.91.1501
1953LI29 Phys.Rev. 91, 342 (1953) The Cross Section For The Reaction Al27(α, α2pn)Na24 From Threshold To 380 Mev NUCLEAR REACTIONS 27Al(α, n2pα), E=32-380 MeV; measured products, 24Na, Eπ, Iπ; deduced σ, σ(E). Data were imported from EXFOR entry C0381.
doi: 10.1103/PhysRev.91.342
1953LI31 Phys.Rev. 89, 1150 2 (1953) Heavy Isotopes of Magnesium and Silicon RADIOACTIVITY 28Al, 31Si(β-) [from Cl(p, X), E=340 MeV]; measured decay products, Eβ, Iβ, Eγ, Iγ. 32Si; deduced new isotopes β- and g-ray energies, T1/2.
doi: 10.1103/physrev.89.1150.2
1952LI23 Phys.Rev. 88, 1422 (1952) The Nuclides Ba127, Ba128, and Cs128
doi: 10.1103/PhysRev.88.1422
1951LI07 J.Am.Chem.Soc. 73, 1610 (1951) The Identification of W188 Formed in Neutron-Activated Tungsten by a Chemical Separation of Re188
doi: 10.1021/ja01148a058
1951LI19 Phys.Rev. 84, 240 (1951) Characteristics of Some Radionuclides of Tungsten, Rhenium, and Osmium Formed by Second-Order Thermal Neutron Capture
doi: 10.1103/PhysRev.84.240
1950LI08 Phys.Rev. 78, 499 (1950) The Spallation Products Of Antimony Irradiated With High Energy Particles NUCLEAR REACTIONS Sb(α, x), Sb(d, x), E=50-380 MeV; measured products, 103Pd, 100Pd, 106Ru, 105Ru, 103Ru, 97Ru, 99Mo, 91Y, 87Y, 108Sn, 109Cd, 107Cd, 110Ag, 106Ag, 105Ag, 112Pd, 111In, 121Te, 119Te, 118Te, 124Sb, 122Sb, 119Sb, 118Sb, 121Sn, 117Sn, 113Sn, 114In, 115Cd, 112Ag, 111Ag, 101Pd, 109Pd, 111Pd; deduced σ, σ(E). Data were imported from EXFOR entry C0386.
doi: 10.1103/PhysRev.78.499
1948LI02 Phys.Rev. 73, 1124 (1948) Neutron Deficient Isotopes of Tellurium and Antimony
doi: 10.1103/PhysRev.73.1124
1948LI03 Phys.Rev. 73, 1202 (1948) Neutron-Deficient Isotopes of Rhodium and Palladium
doi: 10.1103/PhysRev.73.1202
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