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NSR database version of April 25, 2024.

Search: Author = S.Eliseev

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2024KR02      Phys.Rev. C 109, L021301 (2024)

K.Kromer, Ch.Lyu, J.Bieron, M.Door, L.Enzmann, P.Filianin, G.Gaigalas, Z.Harman, J.Herkenhoff, W.Huang, Ch.H.Keitel, S.Eliseev, K.Blaum

Atomic mass determination of uranium-238

doi: 10.1103/PhysRevC.109.L021301
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2023EL02      Eur.Phys.J. A 59, 34 (2023)

S.Eliseev, Y.Novikov

High-precision Penning-trap mass spectrometry for neutrino physics

doi: 10.1140/epja/s10050-023-00946-4
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2023HE18      Phys.Rev.Lett. 131, 253002 (2023)

F.Heisse, M.Door, T.Sailer, P.Filianin, J.Herkenhoff, C.M.Konig, K.Kromer, D.Lange, J.Morgner, A.Rischka, Ch.Schweiger, B.Tu, Y.N.Novikov, S.Eliseev, S.Sturm, K.Blaum

High-Precision Determination of g Factors and Masses of ²⁰Ne⁹⁺ and ²²Ne⁹⁺

ATOMIC MASSES ^20,22Ne; measured the cyclotron-frequency ratio; deduced individual bound electron g factors, atomic masses. Comparison with available data. The PENTATRAP and A LPHATRAP experiments are both cryogenic Penning-trap setups located at the Max Planck Institute for Nuclear Physics in Heidelberg.

doi: 10.1103/PhysRevLett.131.253002
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2022KA45      Phys.Rev. C 106, 054325 (2022)

O.Kaleja, B.Andjelic, O.Bezrodnova, K.Blaum, M.Block, S.Chenmarev, P.Chhetri, C.Droese, Ch.E.Dullmann, M.Eibach, S.Eliseev, J.Even, P.Filianin, F.Giacoppo, S.Gotz, Yu.Gusev, M.J.Gutierrez, F.P.Hessberger, N.Kalantar-Nayestanaki, J.J.W.van de Laar, M.Laatiaoui, S.Lohse, N.Martynova, E.Minaya Ramirez, A.K.Mistry, T.Murbock, Yu.Novikov, S.Raeder, D.Rodriguez, F.Schneider, L.Schweikhard, P.G.Thirolf, A.Yakushev

Direct high-precision mass spectrometry of superheavy elements with SHIPTRAP

ATOMIC MASSES ^251,254No, ^254,255,256Lr, ²⁵⁷Rf; measured cyclotron frequency; deduced mass excesses, two-neutron shell gap. Comparison to AME2020. Phase-imaging ion-cyclotron resonance mass spectrometry (PI-ICR MS) at SHIPTRAP setup. Isotopes produced in following reactions ²⁰⁶Pb(⁴⁸Ca, 3n)²⁵¹No, E=4.8 MeV/nucleon, ²⁰⁸Pb(⁴⁸Ca, 2n)²⁵⁴No, E=4.56 MeV/nucleon, ²⁰⁹Bi(⁴⁸Ca, 3n)²⁵⁴Lr, E=4.81 MeV/nucleon, ²⁰⁹Bi(⁴⁸Ca, 2n)²⁵⁵Lr, E=4.56 MeV/nucleon, ²⁰⁹Bi(⁴⁸Ca, n)²⁵⁶Lr, E=4.5 MeV/nucleon, ²⁰⁸Pb(⁵⁰Ti, n)²⁵⁷Rf, E=4.65 MeV/nucleon at GSI Darmstadt.

RADIOACTIVITY ²⁵⁸Db, ²⁵⁴Lr(α); deduced Q values. Comparison to other experimental data.

doi: 10.1103/PhysRevC.106.054325
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2022KR04      Eur.Phys.J. A 58, 202 (2022); Erratum Eur.Phys.J. A 60, (2024)

K.Kromer, C.Lyu, M.Door, P.Filianin, Z.Harman, J.Herkenhoff, W.Huang, C.H.Keitel, D.Lange, Y.N.Novikov, C.Schweiger, S.Eliseev, K.Blaum

High-precision mass measurement of doubly magic ²⁰⁸Pb

ATOMIC MASSES ²⁰⁸Pb, ¹³²Xe; measured the cyclotron-frequency ratio; deduced absolute atomic mass. The ab initio fully relativistic multi-configuration Dirac–Hartree–Fock (MCDHF) calculations. Comparison with AME 2020. The high-precision Penning-trap mass spectrometer Pentatrap.

doi: 10.1140/epja/s10050-022-00860-1
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2022NE10      Phys.Rev. C 106, 024310 (2022)

D.A.Nesterenko, K.Blaum, P.Delahaye, S.Eliseev, T.Eronen, P.Filianin, Z.Ge, M.Hukkanen, A.Kankainen, Yu.N.Novikov, A.V.Popov, A.Raggio, M.Stryjczyk, V.Virtanen

Direct determination of the excitation energy of the quasistable isomer ^180mTa

ATOMIC MASSES ^180,180mTa; measured cyclotron frequency with the phase-imaging ion-cyclotron-resonance (PI-ICR) technique using Penning-trap mass spectrometer (JYFLTRAP) at the Ion Guide Isotope Separator On-Line (IGISOL) facility of University of Jyvaskyla; deduced mass excesses, first direct precise determination of the excitation energy of naturally-occurring low-energy isomer of ¹⁸⁰Ta. ^180,180m produced in Ta(p, X), E=40 MeV reaction. Comparison with AME2020 evaluation. Relevance to search for dark matter, astrophysics, and development of a γ laser.

doi: 10.1103/PhysRevC.106.024310
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2021FI03      Phys.Rev.Lett. 127, 072502 (2021)

P.Filianin, C.Lyu, M.Door, K.Blaum, W.J.Huang, M.Haverkort, P.Indelicato, C.H.Keitel, K.Kromer, D.Lange, Y.N.Novikov, A.Rischka, R.X.Schussler, Ch.Schweiger, S.Sturm, S.Ulmer, Z.Harman, S.Eliseev

Direct Q-Value Determination of the β^- Decay of ¹⁸⁷Re

ATOMIC MASSES ¹⁸⁷Os, ¹⁸⁷Re; measured cyclotron frequency ratio; deduced mass difference, β-decay Q-value. Comparison with AME-2016 evaluation.

doi: 10.1103/PhysRevLett.127.072502
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2020BL06      Rev.Mod.Phys. 92, 045007 (2020)

K.Blaum, S.Eliseev, F.A.Danevich, V.I.Tretyak, S.Kovalenko, M.I.Krivoruchenko, Y.N.Novikov, J.Suhonen

Neutrinoless double-electron capture

RADIOACTIVITY ⁷⁴Se, ⁹⁶Ru, ¹⁰⁶Cd, ¹¹²Sn, ¹²⁴Xe, ¹³⁶Ce, ¹⁵²Gd, ¹⁵⁶Dy, ¹⁶⁴Er, ¹⁸⁰W, ¹⁸⁴Os, ¹⁹⁰Pt, ^148,150Gd, ¹⁵⁴Dy, ¹⁹⁴Hg, ²⁰²Pb(2EC); analyzed available data; calculated nuclear matrix elements, T_1/2 boundaries.

doi: 10.1103/RevModPhys.92.045007
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2020BL07      Rev.Mod.Phys. 92, 045007 (2020)

K.Blaum, S.Eliseev, F.A.Danevich, V.I.Tretyak, S.Kovalenko, M.I.Krivoruchenko, Y.N.Novikov, J.Suhonen

Neutrinoless double-electron capture

RADIOACTIVITY ⁷⁴Se, ⁹⁶Ru, ¹⁰⁶Cd, ¹¹²Sn, ¹²⁴Xe, ¹³⁶Ce, ¹⁵²Gd, ^154,156Dy, ¹⁶⁴Er, ¹⁸⁰W, ¹⁸⁴Os, ¹⁹⁰Pt, ^148,150Gd, ¹⁹⁴Hg, ²⁰²Pb(2EC); calculated nuclear matrix elements, T_1/2. Comparison with available data.

doi: 10.1103/RevModPhys.92.045007
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2020MA09      Phys.Rev.Lett. 124, 092502 (2020)

V.Manea, J.Karthein, D.Atanasov, M.Bender, K.Blaum, T.E.Cocolios, S.Eliseev, A.Herlert, J.D.Holt, W.J.Huang, Y.A.Litvinov, D.Lunney, J.Menendez, M.Mougeot, D.Neidherr, L.Schweikhard, A.Schwenk, J.Simonis, A.Welker, F.Wienholtz, K.Zuber

First Glimpse of the N=82 Shell Closure below Z=50 from Masses of Neutron-Rich Cadmium Isotopes and Isomers

ATOMIC MASSES ^{124,126,127,127m,128,129,129m,131,132}Cd; measured mass excesses using phase-imaging ion cyclotron-resonance (PI-ICR) method with the ISOLTRAP spectrometer at ISOLDE-CERN. Cd isotopes were produced in U(p, F), E=1.4 GeV reaction followed by separation of fission fragments using ISOLDE High-resolution separator. Comparison with literature data in AME2016 evaluation, and with large-scale shell-model, mean-field, beyond-mean-field, and ab initio valence-space in-medium similarity renormalization group (VS-IMSRG) calculations. Systematics of S(n) for N=81, 83 and Z=48-68, and for two-neutron shell gaps for N=82, Z=42-70 nuclei.

doi: 10.1103/PhysRevLett.124.092502
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2020RI04      Phys.Rev.Lett. 124, 113001 (2020)

A.Rischka, H.Cakir, M.Door, P.Filianin, Z.Harman, W.J.Huang, P.Indelicato, C.H.Keitel, C.M.Konig, K.Kromer, M.Muller, Y.N.Novikov, R.X.Schussler, C.Schweiger, S.Eliseev, K.Blaum

Mass-Difference Measurements on Heavy Nuclides with an eV/c² Accuracy in the PENTATRAP Spectrometer

ATOMIC MASSES ^{126,128,129,131,132,134}Xe; measured frequencies; deduced mass differences of five pairs of stable xenon isotopes. The novel cryogenic multi-Penning-trap mass spectrometer PENTATRAP.

doi: 10.1103/PhysRevLett.124.113001
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2019KA48      Hyperfine Interactions 240, 61 (2019)

J.Karthein, D.Atanasov, K.Blaum, S.Eliseev, P.Filianin, D.Lunney, V.Manea, M.Mougeot, D.Neidherr, Y.Novikov, L.Schweikhard, A.Welker, F.Wienholtz, K.Zuber

Direct decay-energy measurement as a route to the neutrino mass

RADIOACTIVITY ¹³¹Cs(EC); measured decay products, frequencies; deduced Q-value, mass excess, excluded this transition for neutrino mass measurements.

doi: 10.1007/s10751-019-1601-z
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2019VE09      Eur.Phys.J. C 79, 1026 (2019)

C.Velte, F.Ahrens, A.Barth, K.Blaum, M.Brass, M.Door, H.Dorrer, Ch.E.Dullmann, S.Eliseev, C.Enss, P.Filianin, A.Fleischmann, L.Gastaldo, A.Goeggelmann, T.Day Goodacre, M.W.Haverkort, D.Hengstler, J.Jochum, K.Johnston, M.Keller, S.Kempf, T.Kieck, C.M.Konig, U.Koster, K.Kromer, F.Mantegazzini, B.Marsh, Yu.N.Novikov, F.Piquemal, C.Riccio, D.Richter, A.Rischka, S.Rothe, R.X.Schussler, Ch.Schweiger, T.Stora, M.Wegner, K.Wendt, M.Zampaolo, K.Zuber

High-resolution and low-background ¹⁶³Ho spectrum: interpretation of the resonance tails

RADIOACTIVITY ¹⁶³Ho(EC) [from ¹⁶²Er(n, γ), E thermal]; measured decay products, Eβ, Iβ; deduced energy spectrum, Q-value. Comparison with available data.

doi: 10.1140/epjc/s10052-019-7513-x
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2017GA14      Eur.Phys.J. Special Topics 226, 1623 (2017)

L.Gastaldo, K.Blaum, K.Chrysalidis, T.Day Goodacre, A.Domula, M.Door, H.Dorrer, Ch.E.Dullmann, K.Eberhardt, S.Eliseev, C.Enss, A.Faessler, P.Filianin, A.Fleischmann, D.Fonnesu, L.Gamer, R.Haas, C.Hassel, D.Hengstler, J.Jochum, K.Johnston, U.Kebschull, S.Kempf, T.Kieck, U.Koster, S.Lahiri, M.Maiti, F.Mantegazzini, B.Marsh, P.Neroutsos, Yu.N.Novikov, P.C.O.Ranitzsch, S.Rothe, A.Rischka, A.Saenz, O.Sander, F.Schneider, S.Scholl, R.X.Schussler, Ch.Schweiger, F.Simkovic, T.Stora, Z.Szucs, A.Turler, M.Veinhard, M.Weber, M.Wegner, K.Wendt and K.Zuber

The electron capture in ¹⁶³Ho experiment - ECHo

RADIOACTIVITY ¹⁶³Ho(EC); measured decay products, X-rays; calculated electron capture spectrum; deduced sensitivity towards neutrino mass measurements.

doi: 10.1140/epjst/e2017-70071-y
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2017GI07      Acta Phys.Pol. B48, 423 (2017)

F.Giacoppo, K.Blaum, M.Block, P.Chhetri, Ch.E.Dullmann, C.Droese, S.Eliseev, P.Filianin, S.Gotz, Y.Gusev, F.Herfurth, F.P.Hessberger, O.Kaleja, J.Khuyagbaatar, M.Laatiaoui, F.Lautenschlager, C.Lorenz, G.Marx, E.Minaya Ramirez, A.Mistry, Yu.N.Novikov, W.R.Plass, S.Raeder, D.Rodriguez, D.Rudolph, L.G.Sarmiento, C.Scheidenberger, L.Schweikhard, P.Thirolf, A.Yakushev

Recent Upgrades of the SHIPTRAP Setup: On the Finish Line Towards Direct Mass Spectroscopy of Superheavy Elements

doi: 10.5506/APhysPolB.48.423
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2017WE09      Eur.Phys.J. A 53, 153 (2017)

A.Welker, P.Filianin, N.A.S.Althubiti, D.Atanasov, K.Blaum, T.E.Cocolios, S.Eliseev, F.Herfurth, S.Kreim, D.Lunney, V.Manea, D.Neidherr, Yu.Novikov, M.Rosenbusch, L.Schweikhard, F.Wienholtz, R.N.Wolf, K.Zuber

Precision electron-capture energy in ²⁰²Pb and its relevance for neutrino mass determination

ATOMIC PHYSICS ²⁰²Tl, ²⁰²Pb; measured cyclotron frequency of ionized atoms relative to ¹³³Cs, ¹⁸¹Ta¹⁶O and ²⁰³Tl using Penning trap mass spectrometer ISOLTRAP at ISOLDE (CERN); deduced electron capture Q-value. Planned using EC capture to determine electron neutrino mass in few-eV level using cryogenic micro-calorimeter.

doi: 10.1140/epja/i2017-12345-y
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2016FI07      Phys.Lett. B 758, 407 (2016)

P.Filianin, S.Schmidt, K.Blaum, M.Block, S.Eliseev, F.Giacoppo, M.Goncharov, F.Lautenschlaeger, Yu.Novikov, K.Takahashi

The decay energy of the pure s-process nuclide ¹²³Te

ATOMIC MASSES ¹²³Te, ¹²³Sb; measured cyclotron resonance frequencies; deduced Q-values, s-process decay rate. Comparison with available data.

doi: 10.1016/j.physletb.2016.04.059
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2016KO45      Nat. Commun. 7, 10246 (2016)

F.Kohler, K.Blaum, M.Block, S.Chenmarev, S.Eliseev, D.A.Glazov, M.Goncharov, J.Hou, A.Kracke, D.A.Nesterenko, Y.N.Novikov, W.Quint, E.Minaya Ramirez, V.M.Shabaev, S.Sturm, A.V.Volotka, G.Werth

Isotope dependence of the Zeeman effect in lithium-like calcium

ATOMIC MASSES ^40,48Ca; measured cyclotron frequency ratio. ⁴⁸Ca; deduced masses, g-factors. Comparison with theoretical calculations.

doi: 10.1038/ncomms10246
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2015EL03      Phys.Rev.Lett. 115, 062501 (2015)

S.Eliseev, K.Blaum, M.Block, S.Chenmarev, H.Dorrer, Ch.E.Dullmann, C.Enss, P.E.Filianin, L.Gastaldo, M.Goncharov, U.Koster, F.Lautenschlager, Yu.N.Novikov, A.Rischka, R.X.Schussler, L.Schweikhard, A.Turler

Direct Measurement of the Mass Difference of ¹⁶³Ho and ¹⁶³Dy Solves the Q-Value Puzzle for the Neutrino Mass Determination

ATOMIC MASSES ¹⁶³Ho, ¹⁶³Dy; measured period of the cyclotron frequencies; deduced Q-values, mass differences. Comparison with the Atomic Mass Evaluation 2012.

doi: 10.1103/PhysRevLett.115.062501
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2015SC13      Eur.Phys.J. A 51, 89 (2015)

F.Schneider, T.Beyer, K.Blaum, M.Block, S.Chenmarev, H.Dorrer, Ch.E.Dullmann, K.Eberhardt, M.Eibach, S.Eliseev, J.Grund, U.Koster, Sz.Nagy, Yu.N.Novikov, D.Renisch, A.Turler, K.Wendt

Preparatory studies for a high-precision Penning-trap measurement of the 163Ho electron capture Q-value

doi: 10.1140/epja/i2015-15089-8
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2014BO26      Phys.Rev. C 90, 044307 (2014)

Ch.Bohm, Ch.Borgmann, G.Audi, D.Beck, K.Blaum, M.Breitenfeldt, R.B.Cakirli, T.E.Cocolios, S.Eliseev, S.George, F.Herfurth, A.Herlert, M.Kowalska, S.Kreim, D.Lunney, V.Manea, E.Minaya Ramirez, S.Naimi, D.Neidherr, M.Rosenbusch, L.Schweikhard, J.Stanja, M.Wang, R.N.Wolf, K.Zuber

Evolution of nuclear ground-state properties of neutron-deficient isotopes around Z=82 from precision mass measurements

ATOMIC MASSES ^{184,186,190m,193m,194,194m,195,195m,198,198m}Tl, ^202,208Pb, ^207,208Fr, ²²⁴Ra; measured cyclotron frequencies high-precision mass excesses using Penning-trap ISOLTRAP at ISOLDE/CERN; deduced S(2n), S(2p), pairing gap parameter, odd-even effect. Isotopes produced by impinging a 1.4-GeV proton beam on a thick, high-temperature uranium carbide (UC_x) target. Comparison with other experimental results, AME-03, AME-12 evaluations, and microscopic calculations assuming spherical shape of the ground states. Systematics of pairing gaps, S(2p), S(2n), and excitation energy of the (9/2-) isomers for N=96-124 Au and Tl nuclei. Analyzed gradual development of collectivity with proton removal in Z=82.

doi: 10.1103/PhysRevC.90.044307
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2014GA33      J.Low Temp.Physics 176, 876 (2014)

L.Gastaldo, K.Blaum, A.Doerr, Ch.E.Dullmann, K.Eberhardt, S.Eliseev, C.Enss, A.Faessler, A.Fleischmann, S.Kempf, M.Krivoruchenko, S.Lahiri, M.Maiti, Yu.N.Novikov, P.C.-O.Ranitzsch, F.Simkovic, Z.Szucs, M.Wegner

The Electron Capture ¹⁶³Ho Experiment ECHo

RADIOACTIVITY ¹⁶³Ho(EC); measured decay products, X-rays; deduced β-decay spectra, Q-values. Neutrino mass, metallic magnetic calorimeters, SQUID.

doi: 10.1007/s10909-014-1187-4
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2014NE15      Phys.Rev. C 90, 042501 (2014)

D.A.Nesterenko, S.Eliseev, K.Blaum, M.Block, S.Chenmarev, A.Dorr, C.Droese, P.E.Filianin, M.Goncharov, E.Minaya Ramirez, Yu.N.Novikov, L.Schweikhard, V.V.Simon

Direct determination of the atomic mass difference of ¹⁸⁷Re and ¹⁸⁷Os for neutrino physics and cosmochronology

ATOMIC MASSES ¹⁸⁷Re, ¹⁸⁷Os; measured cyclotron-frequency ratio of ¹⁸⁷Re and ¹⁸⁷Os ions, mass difference using Penning-trap mass spectrometer SUIPTRAP at GSI facility; deduced Q value for ¹⁸⁷Re decay. Comparison with previous experimental results. Possibility of electron capture by ¹⁸⁷Os ions in hot stellar conditions.

RADIOACTIVITY ¹⁸⁷Re(β^-); measured precise Q value from mass difference of ¹⁸⁷Re and ¹⁸⁷Os ions using SHIPTRAP at GSI. Comparison with other results. Relevance to cosmochronology.

doi: 10.1103/PhysRevC.90.042501
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2013DR04      Eur.Phys.J. A 49, 13 (2013)

C.Droese, D.Ackermann, L.-L.Andersson, K.Blaum, M.Block, M.Dworschak, M.Eibach, S.Eliseev, U.Forsberg, E.Haettner, F.Herfurth, F.P.Hessberger, S.Hofmann, J.Ketelaer, G.Marx, E.Minaya Ramirez, D.Nesterenko, Yu.N.Novikov, W.R.Plass, D.Rodriguez, D.Rudolph, C.Scheidenberger, L.Schweikhard, S.Stolze, P.G.Thirolf, C.Weber

High-precision mass measurements of ^203-207Rn and ²¹³Ra with SHIPTRAP

NUCLEAR REACTIONS Dy(⁴⁸Ca, ²⁰⁴Rn), (⁴⁸Ca, ²⁰⁵Rn), (⁴⁸Ca, ²⁰⁶Rn), (⁴⁸Ca, ²⁰⁷Rn), E=4.4 MeV/nucleon;¹⁷⁰Er(⁴⁸Ca, ²¹³Ra), E=4.4 MeV;¹⁷⁰Er(⁴⁰Ar, ²⁰³Rn), (⁴⁰Ar, ²⁰⁴Rn), (⁴⁰Ar, ²⁰⁵Rn), E=4.7 MeV/nucleon;¹⁶⁰Gd(⁵⁰Ti, ²⁰⁴Rn), (⁴⁰Ar, ²⁰⁵Rn), (⁴⁰Ar, ²⁰⁶Rn), E=4.55 MeV/nucleon; measured evaporation residues, frequency ratio using tandem Penning trap spectrometer SHIPTRAP; deduced σ, mass excess, 2n separation energy; calculated σ using statistical model code HIVAP. Compared with AME; 2n separation energy compared with trends for Pb, Po, Rn, Ra.

ATOMIC MASSES ^{203,204,205,206,207}Rn, ²¹³Ra; measured frequency ratio, number of resonances; deduced mass. Compared with AME 2003.

doi: 10.1140/epja/i2013-13013-0
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2013EL01      Phys.Rev.Lett. 110, 082501 (2013)

S.Eliseev, K.Blaum, M.Block, C.Droese, M.Goncharov, E.Minaya Ramirez, D.A.Nesterenko, Yu.N.Novikov, L.Schweikhard

Phase-Imaging Ion-Cyclotron-Resonance Measurements for Short-Lived Nuclides

ATOMIC MASSES ^129,130Xe; measured cyclotron frequency via the projection of the ion motion; deduced mass difference for xenon nuclei. Phase-imaging ion-cyclotron-resonance technique.

doi: 10.1103/PhysRevLett.110.082501
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2013RO19      Eur.Phys.J. D 67, 146 (2013)

C.Roux, K.Blaum, M.Block, C.Droese, S.Eliseev, M.Goncharov, F.Herfurth, E.Minaya Ramirez, D.A.Nesterenko, Y.N.Novikov, L.Schweikhard

Data analysis of Q-value measurements for double-electron capture with SHIPTRAP

RADIOACTIVITY ¹⁵²Gd(2EC); measured cyclotron frequency ratio; deduced Q-value. Comparison with available data.

doi: 10.1140/epjd/e2013-40110-x
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2012BL12      J.Phys.:Conf.Ser. 381, 012013 (2012)

K.Blaum, S.Eliseev, T.Eronen, Y.Litvinov

Precision mass measurements for nuclear astro- and neutrino physics

doi: 10.1088/1742-6596/381/1/012013
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2012DR01      Nucl.Phys. A875, 1 (2012)

C.Droese, K.Blaum, M.Block, S.Eliseev, F.Herfurth, E.Minaya-Ramirez, Yu.N.Novikov, L.Schweikhard, V.M.Shabaev, I.I.Tupitsyn, S.Wycech, K.Zuber, N.A.Zubova

Probing the nuclide ¹⁸⁰W for neutrinoless double-electron capture exploration

RADIOACTIVITY ¹⁸⁰W(2EC); measured cyclotron frequency using Penning trap mass ratios using SHIPTRAP; deduced Q value, T_1/2.

ATOMIC MASSES ¹⁸⁰Hf, ¹⁸⁰W; measured cyclotron frequency ratios using SHIPTRAP Penning trap; deduced Q.

doi: 10.1016/j.nuclphysa.2011.11.008
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2012EL03      J.Phys.(London) G39, 124003 (2012)

S.A.Eliseev, Yu.N.Novikov, K.Blaum

Search for resonant enhancement of neutrinoless double-electron capture by high-precision Penning-trap mass spectrometry

RADIOACTIVITY ⁹⁶Ru, ⁷⁴Se, ¹⁰⁶Cd, ¹¹²Sn, ¹²⁴Xe, ¹³⁰Ba, ¹³⁶Ce, ¹⁵²Gd, ¹⁵⁶Dy, ^162,164Er, ¹⁶⁸Yb, ¹⁸⁰W, ¹⁸⁴Os(2EC); analyzed available data; deduced possible resonance enhancement. Penning trap mass measurements.

doi: 10.1088/0954-3899/39/12/124003
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2012FA02      Phys.Rev. C 85, 035503 (2012)

D.-L.Fang, K.Blaum, S.Eliseev, A.Faessler, M.I.Krivoruchenko, V.Rodin, F.Simkovic

Evaluation of the resonance enhancement effect in neutrinoless double-electron capture in ¹⁵²Gd, ¹⁶⁴Er, and ¹⁸⁰W atoms

RADIOACTIVITY ¹⁵²Gd, ¹⁶⁴Er, ¹⁸⁰W(2EC); calculated matrix elements and half-lives for neutrinoless double-electron capture. Deformed quasiparticle random-phase approximation using the realistic charge-dependent Bonn (CD-Bonn) nucleon-nucleon interaction. Comparison of half-life with that for neutrinoless 2β decay of ⁷⁶Ge.

doi: 10.1103/PhysRevC.85.035503
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2012MI27      Science 337, 1207 (2012)

E.Minaya-Ramirez, D.Ackermann, K.Blaum, M.Block, C.Droese, C.E.Dullmann, M.Dworschak, M.Eibach, S.Eliseev, E.Haettner, F.Herfurth, F.P.Hessberger, S.Hofmann, J.Ketelaer, G.Marx, M.Mazzocco, D.Nesterenko, Y.N.Novikov, W.R.Plass, D.Rodriguez, C.Scheidenberger, L.Schweikhard, P.G.Thirolf, C.Weber

Direct Mapping of Nuclear Shell Effects in the Heaviest Elements

ATOMIC MASSES ^{252,253,254,255}No, ^255,256Lr; measured time-of-flight ion-cyclotron-resonance; deduced frequency ratios, mass excess. Comparison with theoretical calculations, SHIPTRAP results.

doi: 10.1126/science.1225636
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2012NE10      Phys.Rev. C 86, 044313 (2012)

D.A.Nesterenko, K.Blaum, M.Block, C.Droese, S.Eliseev, F.Herfurth, E.Minaya Ramirez, Yu.N.Novikov, L.Schweikhard, V.M.Shabaev, M.V.Smirnov, I.I.Tupitsyn, K.Zuber, N.A.Zubova

Double-β transformations in isobaric triplets with mass numbers A=124, 130, and 136

ATOMIC MASSES ¹²⁴Sn, ¹²⁴Xe, ¹²⁴Te, ¹³⁰Te, ¹³⁰Xe, ¹³⁰Ba, ¹³⁶Ce; measured time-of-flight ion cyclotron resonances, cyclotron frequencies ratios of ¹³⁰Xe to ¹³⁰Ba and ¹³⁰Te, ¹²⁴Te to ¹²⁴Xe and ¹²⁴Sn, ¹³⁶Ba to ¹³⁶Ce using Penning-trap mass spectrometer SHIPTRAP. Isobaric mass triplets.

RADIOACTIVITY ¹²⁴Xe, ¹³⁰Ba, ¹³⁶Ce(2EC); measured masses, deduced Q values.

doi: 10.1103/PhysRevC.86.044313
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2012SM01      Phys.Rev. C 85, 027601 (2012)

C.Smorra, T.Beyer, K.Blaum, M.Block, Ch.E.Dullmann, K.Eberhardt, M.Eibach, S.Eliseev, Sz.Nagy, W.Nortershauser, D.Renisch

Direct mass measurements of cadmium and palladium isotopes and their double-β transition Q values

ATOMIC MASSES ^106,108,110Cd, ^106,108,110Pd; measured cyclotron frequency ratios, masses and mass excesses by Penning-trap mass spectrometers SHIPTRAP and ISOLTRAP. Comparison with AME-2003 evaluation.

RADIOACTIVITY ^106,108Cd(2β⁺), (2EC); ¹¹⁰Pd(2β^-); measured Q values by Penning-trap mass spectrometers. Comparison with AME-2003 evaluation.

doi: 10.1103/PhysRevC.85.027601
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2012SM07      Phys.Rev. C 86, 044604 (2012)

C.Smorra, T.R.Rodriguez, T.Beyer, K.Blaum, M.Block, Ch.E.Dullmann, K.Eberhardt, M.Eibach, S.Eliseev, K.Langanke, G.Martinez-Pinedo, Sz.Nagy, W.Nortershauser, D.Renisch, V.M.Shabaev, I.I.Tupitsyn, N.A.Zubova

Q value and half-life of double-electron capture in ¹⁸⁴Os

ATOMIC MASSES ¹⁸⁴Os, ¹⁸⁴W; measured time-of-flight and cyclotron frequency ratios using Penning-trap mass spectrometer TRIGA-TRAP; deduced mass excess, Q value for 2β decay.

RADIOACTIVITY ¹⁸⁴Os(2EC); measured Q-value using Penning-trap; calculated nuclear matrix element, T_1/2. Energy density functional (EDF) calculations.

doi: 10.1103/PhysRevC.86.044604
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2011BL09      J.Phys.:Conf.Ser. 312, 092001 (2011)

K.Blaum, M.Block, R.B.Cakirli, S.Eliseev, M.Kowalska, S.Kreim, Y.A.Litvinov, Sz.Nagy, W.Nortershauser, D.T.Yordanov

Measurements of ground-state properties for nuclear structure studies by precision mass and laser spectroscopy

NUCLEAR STRUCTURE ^7,8,9,10,11Be; calculated charge radius using FMD (fermionic molecular dynamics); compared with data obtained from isotope shift.

doi: 10.1088/1742-6596/312/9/092001
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2011EL02      Phys.Rev.Lett. 106, 052504 (2011)

S.Eliseev, C.Roux, K.Blaum, M.Block, C.Droese, F.Herfurth, H.-J.Kluge, M.I.Krivoruchenko, Yu.N.Novikov, E.Minaya-Ramirez, L.Schweikhard, V.M.Shabaev, F.Simkovic, I.I.Tupitsyn, K.Zuber, N.A.Zubova

Resonant Enhancement of Neutrinoless Double-Electron Capture in ¹⁵²Gd

ATOMIC MASSES ¹⁵²Gd, ¹⁵²Sm; measured cyclotron frequency ratio, TOF; deduced Q-value for double beta decay. Penning-trap mass ratio.

doi: 10.1103/PhysRevLett.106.052504
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2011EL04      Phys.Rev. C 83, 038501 (2011)

S.Eliseev, D.Nesterenko, K.Blaum, M.Block, C.Droese, F.Herfurth, E.Minaya-Ramirez, Yu.N.Novikov, L.Schweikhard, K.Zuber

Q values for neutrinoless double-electron capture in ⁹⁶Ru, ¹⁶²Er, and ¹⁶⁸Yb

RADIOACTIVITY ⁹⁶Ru, ¹⁶²Er, ¹⁶⁸Yb(2EC); measured Q values from Penning-trap mass ratios using SHIPTRAP. Absence of resonant enhancement of the capture rates, thus excluded as suitable candidates for search of neutrinoless double-electron capture.

ATOMIC MASSES ⁹⁶Ru, ⁹⁶Mo, ¹⁶²Er, ¹⁶²Dy, ¹⁶⁸Yb, ¹⁶⁸Er; measured cyclotron frequency ratios using SHIPTRAP Penning-trap; deduced Q(2EC) values.

doi: 10.1103/PhysRevC.83.038501
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2011EL05      Phys.Rev. C 84, 012501 (2011)

S.Eliseev, M.Goncharov, K.Blaum, M.Block, C.Droese, F.Herfurth, E.Minaya-Ramirez, Yu.N.Novikov, L.Schweikhard, V.M.Shabaev, I.I.Tupitsyn, K.Zuber, N.A.Zubova

Multiple-resonance phenomenon in neutrinoless double-electron capture

ATOMIC MASSES ¹⁵⁶Dy, ¹⁵⁶Gd; measured cyclotron frequency ratio, TOF; deduced Q-value for double electron capture. SHIPTRAP Penning-trap mass spectrometer. Comparison with AME-2003.

RADIOACTIVITY ¹⁵⁶Dy(2EC); calculated electron wave functions, double-electron-hole binding energy; deduced resonant enhancement factor for the probability of neutrinoless double-electron capture. Estimated partial half-life. Dirac-Fock method, Fermi model.

doi: 10.1103/PhysRevC.84.012501
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2011EL08      Phys.Rev.Lett. 107, 152501 (2011)

S.Eliseev, C.Roux, K.Blaum, M.Block, C.Droese, F.Herfurth, M.Kretzschmar, M.I.Krivoruchenko, E.Minaya-Ramirez, Yu.N.Novikov, L.Schweikhard, V.M.Shabaev, F.Simkovic, I.I.Tupitsyn, K.Zuber, N.A.Zubova

Octupolar-Excitation Penning-Trap Mass Spectrometry for Q-Value Measurement of Double-Electron Capture in 164Er

ATOMIC MASSES ¹⁶⁴Er, ¹⁶⁴Dy; measured relative frequency deviations; deduced doublet mass ratio, Q-value. Penning trap.

doi: 10.1103/PhysRevLett.107.152501
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2011GO23      Phys.Rev. C 84, 028501 (2011)

M.Goncharov, K.Blaum, M.Block, C.Droese, S.Eliseev, F.Herfurth, E.Minaya-Ramirez, Yu.N.Novikov, L.Schweikhard, K.Zuber

Probing the nuclides ¹⁰²Pd, ¹⁰⁶Cd, and ¹⁴⁴Sm for resonant neutrinoless double-electron capture

ATOMIC MASSES ¹⁰²Pd, ¹⁰²Ru, ¹⁰⁶Cd, ¹⁰⁶Pd, ¹⁴⁴Sm, ¹⁴⁴Nd; measured cyclotron-frequency-ratios of singly-charged ion pairs using the Penning-trap mass spectrometer SHIPTRAP at GSI. Deduced Q values for double ϵ capture decay. Comparison with AME-2003.

RADIOACTIVITY ¹⁰²Pd, ¹⁰⁶Cd, ¹⁴⁴Sm(2EC); measured Q values from mass measurement of parent-daughter pairs by Penning-trap method. Deduced parameters for neutrinoless double-electron capture measurements.

doi: 10.1103/PhysRevC.84.028501
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2011HA08      Phys.Rev.Lett. 106, 122501 (2011)

E.Haettner, D.Ackermann, G.Audi, K.Blaum, M.Block, S.Eliseev, T.Fleckenstein, F.Herfurth, F.P.Hessberger, S.Hofmann, J.Ketelaer, J.Ketter, H.-J.Kluge, G.Marx, M.Mazzocco, Yu.N.Novikov, W.R.Plass, S.Rahaman, T.Rauscher, D.Rodriguez, H.Schatz, C.Scheidenberger, L.Schweikhard, B.Sun, P.G.Thirolf, G.Vorobjev, M.Wang, C.Weber

Mass Measurements of Very Neutron-Deficient Mo and Tc Isotopes and Their Impact on rp Process Nucleosynthesis

ATOMIC MASSES ⁸¹Rb, ^80,81,84Sr, ⁸⁶Zr, ⁸⁵Nb, ^85,86,87Mo, ⁸⁷Tc; measured frequency ratios; deduced masses, proton separation energies, possible limitations for rp astrophysical process. Comparison with AME03, Penning trap mass measurement.

doi: 10.1103/PhysRevLett.106.122501
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2010BL03      Hyperfine Interactions 196, 225 (2010)

M.Block, D.Ackermann, K.Blaum, C.Droese, M.Dworschak, M.Eibach, S.Eliseev, T.Fleckenstein, E.Haettner, F.Herfurth, F.P.Hessberger, S.Hofmann, J.Ketelaer, J.Ketter, H.-J.Kluge, G.Marx, M.Mazzocco, Yu.N.Novikov, W.R.Plass, A.Popeko, S.Rahaman, D.Rodriguez, C.Scheidenberger, L.Schweikhard, P.G.Thirolf, G.K.Vorobyev, C.Weber

Penning trap mass measurements of transfermium elements with SHIPTRAP

ATOMIC MASSES ^252,253,254No; measured cyclotron resonance curves; deduced masses.

doi: 10.1007/s10751-010-0161-z
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2010BL04      Nature(London) 463, 785 (2010)

M.Block, D.Ackermann, K.Blaum, C.Droese, M.Dworschak, S.Eliseev, T.Fleckenstein, E.Haettner, F.Herfurth, F.P.Hessberger, S.Hofmann, J.Ketelaer, J.Ketter, H.-J.Kluge, G.Marx, M.Mazzocco, Yu.N.Novikov, W.R.Plass, A.Popeko, S.Rahaman, D.Rodriguez, C.Scheidenberger, L.Schweikhard, P.G.Thirolf, G.K.Vorobyev, C.Weber

Direct mass measurements above uranium bridge the gap to the island of stability

ATOMIC MASSES ^252,253,254No; measured masses by Penning-trap method at GSI, using ¹³³Cs as standard.

doi: 10.1038/nature08774
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2010DW01      Phys.Rev. C 81, 064312 (2010)

M.Dworschak, M.Block, D.Ackermann, G.Audi, K.Blaum, C.Droese, S.Eliseev, T.Fleckenstein, E.Haettner, F.Herfurth, F.P.Hessberger, S.Hofmann, J.Ketelaer, J.Ketter, H.-J.Kluge, G.Marx, M.Mazzocco, Yu.N.Novikov, W.R.Plass, A.Popeko, S.Rahaman, D.Rodriguez, C.Scheidenberger, L.Schweikhard, P.G.Thirolf, G.K.Vorobyev, M.Wang, C.Weber

Penning trap mass measurements on nobelium isotopes

ATOMIC MASSES ^252,253,254No; measured cyclotron frequencies using SHIPTRAP Penning-trap system; deduced mean frequency ratios and mass excesses. Comparison with AME2003 and re-evaluation.

ATOMIC MASSES ²³²U, ^236,238Pu, ^240,241,242Cm, ^244,245,246Cf, ^248,249,250Fm, ^252,253,254No, ^256,257,258Rf, ^260,261,262Sg, ^264,265,266Hs, ^268,269,270Ds; compiled and evaluated mass excesses.

NUCLEAR REACTIONS ^206,207,208Pb(⁴⁸Ca, 2n)²⁵²No/²⁵³No/²⁵⁴No, E=4.55 MeV/nucleon; measured production σ.

doi: 10.1103/PhysRevC.81.064312
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2010EL11      Phys.Lett. B 693, 426 (2010)

S.Eliseev, Ch.Bohm, D.Beck, K.Blaum, M.Breitenfeldt, V.N.Fedosseev, S.George, F.Herfurth, A.Herlert, H.-J.Kluge, M.Kowalska, D.Lunney, S.Naimi, D.Neidherr, Yu.N.Novikov, M.Rosenbusch, L.Schweikhard, S.Schwarz, M.Seliverstov, K.Zuber

Direct mass measurements of ¹⁹⁴Hg and ¹⁹⁴Au: A new route to the neutrino mass determination?

ATOMIC MASSES ¹⁹⁴Au, ¹⁹⁴Hg; measured cyclotron frequency ratio; deduced mass excesses, Q-value of the orbital electron capture. Implications for β-decay anti-neutrino mass measurements.

doi: 10.1016/j.physletb.2010.08.071
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2009EL07      Phys.Rev.Lett. 102, 252501 (2009)

V.-V.Elomaa, G.K.Vorobjev, A.Kankainen, L.Batist, S.Eliseev, T.Eronen, J.Hakala, A.Jokinen, I.D.Moore, Yu.N.Novikov, H.Penttila, A.Popov, S.Rahaman, J.Rissanen, A.Saastamoinen, H.Schatz, D.M.Seliverstov, C.Weber, J.Aysto

Quenching of the SnSbTe Cycle in the rp Process

ATOMIC MASSES ^{104,105,106,107,108}Sn, ^{106,107,108,109,110}Sb, ^108,109Te, ¹¹¹I; Measured atomic masses using JYFLTRAP Penning-trap spectrometer;deduced single-proton separation energy. Comparison with AME2003 evaluation.

doi: 10.1103/PhysRevLett.102.252501
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2008KA30      Phys.Rev.Lett. 101, 142503 (2008)

A.Kankainen, V.-V.Elomaa, L.Batist, S.Eliseev, T.Eronen, U.Hager, J.Hakala, A.Jokinen, I.D.Moore, Yu.N.Novikov, H.Penttila, A.Popov, S.Rahaman, S.Rinta-Antila, J.Rissanen, A.Saastamoinen, D.M.Seliverstov, T.Sonoda, G.Vorobjev, C.Weber, J.Aysto

Mass Measurements and Implications for the Energy of the High-Spin Isomer in ⁹⁴Ag

ATOMIC MASSES ⁹²Rh, ⁹⁴Pd; measured masses using the JYFLTRAP mass spectrometer. ⁹³Pd, ⁹⁴Ag; deduced masses.

doi: 10.1103/PhysRevLett.101.142503
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2008RA03      Phys.Rev.Lett. 100, 012501 (2008)

C.Rauth, D.Ackermann, K.Blaum, M.Block, A.Chaudhuri, Z.Di, S.Eliseev, R.Ferrer, D.Habs, F.Herfurth, F.P.Hessberger, S.Hofmann, H.-J.Kluge, G.Maero, A.Martin, G.Marx, M.Mukherjee, J.B.Neumayr, W.R.Plass, S.Rahaman, D.Rodriguez, C.Scheidenberger, L.Schweikhard, P.G.Thirolf, G.Vorobjev, C.Weber

First Penning Trap Mass Measurements beyond the Proton Drip Line

ATOMIC MASSES ^{144,145,146,147}Ho, ^147,148Tm; measured masses using the SHIPTRAP penning trap mass spectrometer.

doi: 10.1103/PhysRevLett.100.012501
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2008WE10      Phys.Rev. C 78, 054310 (2008)

C.Weber, V.-V.Elomaa, R.Ferrer, C.Frohlich, D.Ackermann, J.Aysto, G.Audi, L.Batist, K.Blaum, M.Block, A.Chaudhuri, M.Dworschak, S.Eliseev, T.Eronen, U.Hager, J.Hakala, F.Herfurth, F.P.Hessberger, S.Hofmann, A.Jokinen, A.Kankainen, H.-J.Kluge, K.Langanke, A.Martin, G.Martinez-Pinedo, M.Mazzocco, I.D.Moore, J.B.Neumayr, Yu.N.Novikov, H.Penttila, W.R.Plass, A.V.Popov, S.Rahaman, T.Rauscher, C.Rauth, J.Rissanen, D.Rodriguez, A.Saastamoinen, C.Scheidenberger, L.Schweikhard, D.M.Seliverstov, T.Sonoda, F.-K.Thielemann, P.G.Thirolf, G.K.Vorobjev

Mass measurements in the vicinity of the r p-process and the ν p-process paths with the Penning trap facilities JYFLTRAP and SHIPTRAP

ATOMIC MASSES ⁸⁴Y, ⁸⁷Zr, ^88,89Mo, ^{88,89,90,91,92}Tc, ^90,91,92,93Ru, ^92,93,94,95Rh, ^94,95,95m,96Pd; measured masses. Comparison with evaluated data.

doi: 10.1103/PhysRevC.78.054310
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2007BL16      Eur.Phys.J. D 45, 39 (2007)

M.Block, D.Ackermann, K.Blaum, A.Chaudhuri, Z.Di, S.Eliseev, R.Ferrer, D.Habs, F.Herfurth, F.P.Hessberger, S.Hofmann, H.-J.Kluge, G.Maero, A.Martin, G.Marx, M.Mazzocco, M.Mukherjee, J.B.Neumayr, W.R.Plass, W.Quint, S.Rahaman, C.Rauth, D.Rodriguez, C.Scheidenberger, L.Schweikhard, P.G.Thirolf, G.Vorobjev, C.Weber

Towards direct mass measurements of nobelium at SHIPTRAP

doi: 10.1140/epjd/e2007-00189-2
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2007CH65      Eur.Phys.J. D 45, 47 (2007)

A.Chaudhuri, M.Block, S.Eliseev, R.Ferrer, F.Herfurth, A.Martin, G.Marx, M.Mukherjee, C.Rauth, L.Schweikhard, G.Vorobjev

Carbon-cluster mass calibration at SHIPTRAP

doi: 10.1140/epjd/e2007-00001-5
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2007MA92      Eur.Phys.J. A 34, 341 (2007)

A.Martin, D.Ackermann, G.Audi, K.Blaum, M.Block, A.Chaudhuri, Z.Di, S.Eliseev, R.Ferrer, D.Habs, F.Herfurth, F.P.Hessberger, S.Hofmann, H.-J.Kluge, M.Mazzocco, M.Mukherjee, J.B.Neumayr, Yu.Novikov, W.Plass, S.Rahaman, C.Rauth, D.Rodriguez, C.Scheidenberger, L.Schweikhard, P.G.Thirolf, G.Vorobjev, C.Weber

Mass measurements of neutron-deficient radionuclides near the end-point of the rp-process with SHIPTRAP

ATOMIC MASSES ^99,101,103Ag, ^{101,102,103,104}Cd, ^{102,103,104,105}In, ^105,106Sn, ^107,109,111Sb, ^{109,110,111,112}Te, ^111,112,113I, ¹¹³Xe; measured and evaluated masses using the SHIPTRAP Penning trap mass spectrometer. ¹⁰⁴Sn, ¹⁰⁵Sb, ¹⁰⁸Te, ¹⁰⁹I, ¹¹²Xe, ¹¹³Cs; evaluated masses.

NUCLEAR STRUCTURE ^{102,103,104,105}In, ^104,105,106Sn, ^105,106,107Sb, ¹⁰⁹I; deduced proton separation energies from mass measurements using the SHIPTRAP facility.

doi: 10.1140/epja/i2007-10520-5
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2007RA37      Eur.Phys.J. Special Topics 150, 329 (2007)

C.Rauth, D.Ackermann, G.Audi, M.Block, A.Chaudhuri, S.Eliseev, F.Herfurth, F.P.Hessberger, S.Hofmann, H.-J.Kluge, A.Martin, G.Marx, M.Mukherjee, J.B.Neumayr, W.R.Plass, S.Rahaman, D.Rodriguez, L.Schweikhard, P.G.Thirolf, G.Vorobjev, C.Weber

Direct mass measurements around A=146 at SHIPTRAP

ATOMIC MASSES ^143,147Tb, ^{143,144,145,146,147,148}Dy, ^{144,145,146,147,148}Ho, ^146,147,148Er, ^147,148Tm; measured masses using the SHIPTRAP penning trap mass spectrometer. Compared results to previous results.

doi: 10.1140/epjst/e2007-00339-8
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2006HE30      Int.J. Mass Spectrom. 251, 266 (2006)

F.Herfurth, Th.Beier, L.Dahl, S.Eliseev, S.Heinz, O.Kester, C.Kozhuharov, G.Maero, W.Quint, and The HITRAP collaboration

Precision measurements with highly charged ions at rest: The HITRAP project at GSI

doi: 10.1016/j.ijms.2006.02.012
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2006KA48      Eur.Phys.J. A 29, 271 (2006)

A.Kankainen, L.Batist, S.A.Eliseev, V.-V.Elomaa, T.Eronen, U.Hager, J.Hakala, A.Jokinen, I.Moore, Yu.N.Novikov, H.Penttila, K.Perajarvi, A.V.Popov, S.Rahaman, S.Rinta-Antila, P.Ronkanen, A.Saastamoinen, D.M.Seliverstov, T.Sonoda, G.K.Vorobjev, J.Aysto

Mass measurements of neutron-deficient nuclides close to A = 80 with a Penning trap

ATOMIC MASSES ^80,81,82,83Y, ^{83,84,85,86,88}Zr, ^85,86,87,88Nb; measured masses. Penning trap.

doi: 10.1140/epja/i2006-10088-6
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2006RA38      Int.J. Mass Spectrom. 251, 146 (2006)

S.Rahaman, M.Block, D.Ackermann, D.Beck, A.Chaudhuri, S.Eliseev, H.Geissel, D.Habs, F.Herfurth, F.P.Hessberger, S.Hofmann, G.Marx, M.Mukherjee, J.B.Neumayr, M.Petrick, W.R.Plass, W.Quint, C.Rauth, D.Rodriguez, C.Scheidenberger, L.Schweikhard, P.G.Thirolf, C.Weber

On-line commissioning of SHIPTRAP

ATOMIC MASSES ^147,148Er, ¹⁴⁷Ho; measured masses and time of flight using the Penning-trap mass spectrometer SHIPTRAP. Nuclides produced at SHIP facility.

doi: 10.1016/j.ijms.2006.01.049
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2005BL30      Eur.Phys.J. A 25, Supplement 1, 49 (2005)

M.Block, D.Ackermann, D.Beck, K.Blaum, M.Breitenfeldt, A.Chauduri, A.Doemer, S.Eliseev, D.Habs, S.Heinz, F.Herfurth, F.P.Hessberger, S.Hofmann, H.Geissel, H.-J.Kluge, V.Kolhinen, G.Marx, J.B.Neumayr, M.Mukherjee, M.Petrick, W.Plass, W.Quint, S.Rahaman, C.Rauth, D.Rodriguez, C.Scheidenberger, L.Schweikhard, M.Suhonen, P.G.Thirolf, Z.Wang, C.Weber, and the SHIPTRAP Collaboration

The ion-trap facility SHIPTRAP: Status and perspectives

doi: 10.1140/epjad/i2005-06-013-5
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2005KA39      Eur.Phys.J. A 25, 355 (2005)

A.Kankainen, G.K.Vorobjev, S.A.Eliseev, W.Huang, J.Huikari, A.Jokinen, A.Nieminen, Yu.N.Novikov, H.Penttila, A.V.Popov, S.Rinta-Antila, H.Schatz, D.M.Seliverstov, Yu.P.Suslov, J.Aysto

Isomers of astrophysical interest in neutron-deficient nuclei at masses A = 81, 85 and 86

RADIOACTIVITY ^81mKr(EC), (IT); ⁸¹Y, ⁸¹Sr, ⁸⁵Nb, ⁸⁵Zr, ⁸⁶Mo, ⁸⁶Nb(EC) [from Ni, ⁵⁴Fe(³²S, X)]; measured Eγ, Iγ, E(ce), I(ce), T_1/2. ⁸¹Kr, ⁸⁵Zr, ⁸⁵Nb deduced isomeric transitions T_1/2, ICC. ⁸⁵Zr, ⁸⁶Nb deduced levels, J, π, ICC. ⁸¹Br deduced neutrino capture rate. Astrophysical implications discussed.

NUCLEAR REACTIONS ⁵⁴Fe(³²S, X)⁸¹Zr/⁸¹Y/⁸¹Sr/^81mKr, E=150-170 MeV; Ni(³²S, X)⁸⁵Nb/^85mNb/^85Zr/^85mZr/⁸⁶Mo/⁸⁶Nb, E=150-170 MeV; measured yields.

doi: 10.1140/epja/i2005-10141-0
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2005KA46      Eur.Phys.J. A 25, Supplement 1, 129 (2005)

A.Kankainen, S.A.Eliseev, T.Eronen, S.P.Fox, U.Hager, J.Hakala, W.Huang, J.Huikari, D.Jenkins, A.Jokinen, S.Kopecky, I.Moore, A.Nieminen, Yu.N.Novikov, H.Penttila, A.V.Popov, S.Rinta-Antila, H.Schatz, D.M.Seliverstov, G.K.Vorobjev, Y.Wang, J.Aysto, and the IS403 Collaboration

Beta-delayed gamma and proton spectroscopy near the Z = N line

RADIOACTIVITY ³¹Cl(β⁺p) [from S(p, X), E=40 MeV]; measured β-delayed Eγ, Ep. ⁵⁸Zn(β⁺) [from Nb(p, X), E=1.4 GeV]; measured Eγ, Iγ, βγ-coin, T_1/2. ⁵⁸Cu deduced levels, β-feeding intensities. ^81mKr(EC), (IT); ⁸¹Y, ⁸¹Sr, ⁸⁵Nb, ⁸⁵Zr, ⁸⁶Mo, ⁸⁶Nb(EC) [from Ni, ⁵⁴Fe(³²S, X)]; measured Eγ, Iγ, E(ce), I(ce), T_1/2. ⁸¹Kr, ⁸⁵Zr, ⁸⁵Nb deduced isomeric transitions T_1/2, ICC. ⁸⁵Zr, ⁸⁶Nb deduced levels, J, π, ICC. ⁸¹Br deduced neutrino capture rate. Mass-separated sources.

doi: 10.1140/epjad/i2005-06-036-x
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2003EL09      Eur.Phys.J. A 18, 433 (2003)

S.M.Eliseev

Deep inelastic scattering of leptons on nuclei: Hadron formation, cumulative particles production

NUCLEAR REACTIONS Ag, Br(ν, X), E ≈ 10-200 GeV; calculated particle multiplicity and invariant momentum distributions. Emulsion target.

doi: 10.1140/epja/i2002-10253-y
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2001EL01      Nucl.Phys. A680, 258c (2001)

S.M.Eliseev

K±-Mesons as Probes for Observing Some ' EMC ' -Like Effect

NUCLEAR REACTIONS ¹²C, ⁴⁰Ca(K⁺, X), E at 0.4-0.8 GeV; ¹²C(K^-, X), E at 0.5-2.0 GeV/c; calculated total σ; deduced reaction mechanism features. Comparisons with data.

doi: 10.1016/S0375-9474(00)00424-3
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2001SC55      Hyperfine Interactions 132, 531 (2001)

C.Scheidenberger, F.Attallah, A.Casares, U.Czok, A.Dodonov, S.A.Eliseev, H.Geissel, M.Hausmann, A.Kholomeev, V.Kozlovski, Yu.A.Litvinov, M.Maier, G.Munzenberg, N.Nankov, Yu.N.Novikov, T.Radon, J.Stadlmann, H.Weick, M.Weidenmuller, H.Wollnik, Z.Zhou

A New Concept for Time-of-Flight Mass Spectrometry with Slowed-Down Short-Lived Isotopes

doi: 10.1023/A:1011959903557
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1999EL10      Nuovo Cim. 112A, 783 (1999)

S.M.Eliseev, K.M.Hanna

Nuclear Transparency in α-Particle Scattering Beyond the Eikonal Approach

NUCLEAR REACTIONS ⁵⁸Ni(α, X), E=172.5, 288 MeV; ⁴⁸Ti(α, X), E=140 MeV; calculated tranparency functions; deduced non-eikonal corrections.

1998EL18      Bull.Rus.Acad.Sci.Phys. 62, 802 (1998)

S.M.Eliseev, K.M.Hanna, T.H.Rihan

Joint Analysis of K⁺- and K^--Nucleus Scattering as a Tool for Investigation of New Nuclear Properties

NUCLEAR REACTIONS ¹²C, ⁴⁰Ca(K⁺, X), E at 0.488-0.714 GeV/c; ¹²C(K^-, X), E at 800 MeV/c; calculated interaction σ. Various corrections discussed. Comparison with data.

1997EL08      Phys.Rev. C56, 554 (1997)

S.M.Eliseev, K.M.Hanna

Bright Interior of Nuclei Viewed by α Particles: High order eikonal expansion

NUCLEAR REACTIONS ⁵⁸Ni(α, X), E=172.5 MeV; calculated optical model potential; deduced effect of first-, second-, third-order eikonal corrections, Coulomb term.

doi: 10.1103/PhysRevC.56.554
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1997EL11      Yad.Fiz. 60, No 6, 1025 (1997); Phys.Atomic Nuclei 60, 918 (1997)

S.M.Eliseev, T.H.Rihan

Kaons as Probes for Observing Some Unusual Properties of Nuclei

NUCLEAR REACTIONS ⁴⁰Ca, ¹²C(K⁺, X), E at 0.4-1 GeV/c; analyzed total σ(E). Glauber multipole scattering approach.

1997EL18      Bull.Rus.Acad.Sci.Phys. 61, 1963 (1997)

S.M.Eliseev, T.Kh.Rikhan

Quasi-Relativistic Approach to Scattering of K⁺ Mesons from Carbon Nuclei

NUCLEAR REACTIONS ¹²C(K⁺, X), E at 0.4-1 GeV/c; calculated total σ; deduced optical potential. Quasi-relativistic approach. Comparison with data.

1995BU17      Bull.Rus.Acad.Sci.Phys. 59, 5 (1995)

Yu.S.Butabaev, I.Adam, K.Ya.Gromov, S.S.Eliseev, R.A.Niyazov, Yu.V.Norseev, V.I.Fominykh, A.Kh.Kholmatov, V.V.Tsupko-Sitnikov, V.G.Chumin, M.B.Yuldashev

αγ Coincidences in Decay of ²²¹Fr

RADIOACTIVITY ²²¹Fr(α) [from ²²⁵Ac(α-decay) following ²²⁹Th decay chain]; measured αγ-coin, Eα, Iα. ²¹⁷At deduced levels, transitions Iγ.

1995CH74      Bull.Rus.Acad.Sci.Phys. 59, 1854 (1995)

V.G.Chumin, S.S.Eliseev, K.Ya.Gromov, Yu.V.Norseev, V.I.Fominykh, V.V.Tsupko-Sitnikov

β-Decay of ²²¹Fr and ²¹⁷At Nuclei

RADIOACTIVITY ²²¹Fr(β^-), (α); ²¹⁷At(α), (β^-) [from ²²¹Fr(α-decay)]; measured αγ-coin; deduced log ft. ²²¹Ra, ²¹⁷Rn deduced Iβ upper limits.

1991AB08      Phys.Lett. 264B, 264 (1991)

V.G.Ableev, S.M.Eliseev, V.I.Inozemtsev, A.A.Nomofilov, N.M.Piskunov, V.I.Sharov, I.M.Sitnik, E.A.Strokovsky, L.N.Strunov, S.A.Zaporozhets, B.Naumann, L.Naumann

Nonquasifree Production of Δ Isobars in the C(³He, t) Reaction at 4.4-18.3 GeV/c

NUCLEAR REACTIONS ¹H, C(³He, t), E at 4.4-18.3 GeV/c; measured σ(Et) vs energy transfer; deduced Δ-isobar excitation features, production mechanism.

doi: 10.1016/0370-2693(91)90346-R
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1988AB08      Yad.Fiz. 48, 27 (1988)

V.G.Ableev, H.Dimitrov, S.M.Eliseev, S.A.Zaporozhets, V.I.Inozemtsev, A.G.Malinin, B.Naumann, L.Naumann, W.Neubert, A.A.Nomofilov, L.Penchev, N.M.Piskunov, I.M.Sitnik, E.A.Strokovsky, L.N.Strunov, V.I.Sharov

Charge Exchange of ³He Relativistic Nuclei to Tritons on Carbon with Δ-Isobar Excitation in the Target Nucleus

NUCLEAR REACTIONS ¹²C(³He, t), E at 4.4-10.8 GeV/c; measured invariant σ(θ); deduced reaction mechanism.

1987AB16      Yad.Fiz. 46, 549 (1987)

V.G.Ableev, G.G.Vorobiev, Kh.Dimitrov, V.F.Dmitriev, S.M.Eliseev, S.A.Zaporozhets, V.I.Ionzemtsev, A.P.Kobushkin, A.G.Malinin, B.Naumann, L.Naumann, W.Neubert, A.A.Nomofilov, L.Penchev, N.M.Piskunov, I.M.Sitnik, E.A.Strokovsky, L.N.Strunov, V.I.Sharov

Charge Exchange p(³He, t) at Momenta 4.4-18.3 GeV/c with Δ-Isobar Production

NUCLEAR REACTIONS ¹H(³He, t), E at 4.4, 6.81, 10.79, 18.3 GeV/c; measured σ(Et, θt). Glauber-Sitenko model calculations.

1984AB06      Pisma Zh.Eksp.Teor.Fiz. 40, 35 (1984); JETP Lett.(USSR) 40, 763 (1984)

V.G.Ableev, G.G.Vorobev, S.M.Eliseev, S.A.Zaporozhets, V.I.Inozemtsev, A.P.Kobushkin, A.B.Kurepin, D.K.Nikitin, A.A.Nomofilov, N.M.Piskunov, I.M.Sitnik, E.A.Strokovsky, L.N.Strunov, V.I.Sharov

Excitation of Δ Isobars in Carbon Nuclei in the (³He, t) Charge Exchange at 4.37, 6.78, and 10.78 GeV/c

NUCLEAR REACTIONS ¹²C(³He, t), E at 4.37-10.78 GeV/c; measured σ(θ) vs energy transfer; deduced target Δ isobar excitation role.

1977AF03      Yad.Fiz. 25, 301 (1977); Sov.J.Nucl.Phys. 25, 164 (1977)

G.N.Afanasev, V.M.Shilov, S.M.Eliseev

Effect of Nucleon Electromagnetic Structure on the Differential Cross Sections for the Scattering of Electrons by Nuclei

NUCLEAR REACTIONS ^54,58Fe, ^58,60,62Ni, ^62,64,66,68Zn(e, e); calculated σ(θ); deduced effect of nucleon electromagnetic structure.

1974AF02      Acta Phys.Pol. B5, 731 (1974)

G.N.Afanasyev, S.M.Eliseev

On the Possibility of the Unified Description of Nuclear Levels and Experiments on the Alpha-Particle and Electron Scattering

NUCLEAR REACTIONS ²⁰⁸Pb(α, α), E=40 MeV; calculated σ(θ).

Note: The following list of authors and aliases matches the search parameter S.Eliseev: , S.A.ELISEEV, S.M.ELISEEV, S.S.ELISEEV