References quoted in the ENSDF dataset: 208TL 212BI A DECAY (60.55 M)
44 references found.
Clicking on a keynumber will list datasets that reference the given article.
Mem.Coll.Sci.Univ.Kyoto 26A, 109 (1950)
S.Tokunaga
Measurement of the Branching Ratio of Thorium C by a Photographic Method
Proc.Phys.Soc.(London) 66A, 608 (1953)
P.Marin, G.R.Bishop, H.Halban
The Absolute Standardization of the 2.615 MeV γ-Rays of ThC'' and the Cross Section for the Photodisintegration of the Deuteron at This Energy
doi: 10.1088/0370-1298/66/7/305
Kgl.Danske Videnskab.Selskab, Mat.-fys.Medd. 30, No.11 (1955)
O.B.Nielsen
Multiple Order of the γ-Rays from Tl208
Proc.Phys.Soc.(London) 68A, 35 (1955)
J.W.Weale
Alpha-Gamma Angular Correlations and Internal Conversion Measurements in ThCC'' and ThC'D
Phys.Rev. 104, 1093 (1956); See Also 56Bu09
J.Burde, S.G.Cohen
Determination of the Lifetime of the 40-keV Excited State of Tl208 Following Alpha Decay Using Recoil Shifts of the Conversion Electrons
Izvest.Akad.Nauk SSSR, Ser.Fiz. 20, 1434 (1956); Columbia Tech.Transl. 20, 1311 (1957)
I.I.Filimonov, G.A.Petrov
Use of a Pulse Ionization Chamber for Investigating Alpha-Gamma Angular Correlation
Phys.Rev. 101, 717 (1956); See Also 53Ho06
J.W.Horton
Alpha-Gamma Angular Correlation in Bi212(ThC)
Izvest.Akad.Nauk SSSR, Ser.Fiz. 20, 1451 (1956); Columbia Tech.Transl. 20, 1327 (1957)
V.A.Korolev, L.A.Kulchitskii, A.I.Zhernovoi
Alpha-Gamma Directional Correlation in ThC'' (Tl208)
Phys.Rev. 104, 1629 (1956)
F.E.Senftle, T.A.Farley, N.Lazar
Half-Life of Th232 and the Branching Ratio of Bi212
Nuclear Phys. 1, 137 (1956)
K.Siegbahn, K.Edvarson
β-Ray Spectroscopy in the Precision Range of 1:105
doi: 10.1016/0029-5582(56)90015-3
Izvest.Akad.Nauk SSSR, Ser.Fiz. 21, 954 (1957); Columbia Tech.Transl. 21, 956 (1958)
V.D.Vorobev, K.I.Ilin, T.I.Kolchinskaia, G.D.Latyshev, A.G.Sergeev, Y.N.Trofimov, V.I.Fadeev
Internal Conversion Electron Spectrum of Radiothorium
Zhur.Eksptl.i Teoret.Fiz. 32, 682 (1957); Soviet Phys.JETP 5, 563 (1957)
A.I.Zhernovoi, E.M.Krisiuk, G.D.Latyshev, A.S.Remennyi, A.G.Sergeev, V.I.Fadeev
Internal Conversion Electron Spectrum of Radiothorium II
Nuovo Cimento 8, 369 (1958)
F.Demichelis, B.Chinaglia, G.Trivero
Nuclear Spectroscopic Investigations of the Nuclides 228Th, 224Ra, 212Pb, 212Bi, 208Tl
Proc.Phys.Soc.(London) 72, 300 (1958)
P.R.Evans, N.J.Freeman
The Branching Ratio of Thorium C
doi: 10.1088/0370-1328/72/2/425
Nuovo Cimento 9, 734 (1958)
D.Prosperi, S.Sciuti
Branching Ratio of ThC (212Bi)
Nuclear Phys. 8, 402 (1958)
J.G.Siekman, H.de Waard
Lifetime Measurements of the First Excited States of Tl208 and Ra224
doi: 10.1016/0029-5582(58)90172-X
Phys.Rev. 118, 755 (1960)
G.T.Emery, W.R.Kane
Gamma-Ray Intensities in the Thorium Active Deposit
NUCLEAR STRUCTURE 212Bi, 212Po, 212Pb, 224Ra, 208Tl; measured not abstracted; deduced nuclear properties.
Phys.Rev. 120, 189 (1960)
G.Schupp, H.Daniel, G.W.Eakins, E.N.Jensen
Transition Intensities in the Tl208 Beta Decay, the Bi212-Po212 Decay Scheme, and the Bi212 Branching Ratio
NUCLEAR STRUCTURE 212Po, 212Bi, 208Tl; measured not abstracted; deduced nuclear properties.
Nuclear Phys. 16, 246 (1960)
R.J.Walen, G.Bastin-Scoffier
Spectre α du 214Bi et Remarques sur Quelques Isotopes Emetteurs α du Bi
NUCLEAR STRUCTURE 212Bi, 213Bi, 214Bi, 211Bi, 210Bi; measured not abstracted; deduced nuclear properties.
Nuovo Cimento 20, 450 (1961)
S.Barkan
Branching Ratio of γ and β Emission from 212Bi (ThC)
NUCLEAR STRUCTURE 212Bi; measured not abstracted; deduced nuclear properties.
Compt.Rend. 253, 98 (1961)
J.G.Ferreira, M.T.Goncalves, L.Ferreira-Salgueiro
The Branching Ratio of Thorium C (Bismuth-212)
NUCLEAR STRUCTURE 212Bi; measured not abstracted; deduced nuclear properties.
Nuclear Phys. 30, 599 (1962)
G.Bertolini, F.Cappellani, G.Restelli, A.Rota
Excited States of Tl-208 and Po-212
NUCLEAR STRUCTURE 212Bi, 212Po, 208Tl; measured not abstracted; deduced nuclear properties.
doi: 10.1016/0029-5582(62)90080-9
Phys.Rev. 132, 1693 (1963)
W.C.Cobb
Spins of Excited States of Tl208 from the Alpha-Gamma Angular Correlations
NUCLEAR STRUCTURE 212Bi; measured not abstracted; deduced nuclear properties.
Z.Physik 176, 30 (1963)
H.Daniel, G.Luhrs
Aufbau eines automatische arbeitenden πsquare root2-Spektrometers und Untersuchung des Konversionslinienspectrums von In114m und ThB mit Folgeprodukten
NUCLEAR STRUCTURE 114In, 208Tl, 212Bi, 212Pb; measured not abstracted; deduced nuclear properties.
Arkiv Fysik 25, 87 (1963)
K.D.Sevier
The Conversion Lines of the 39.85 keV Transition in Thallium 208
NUCLEAR STRUCTURE 212Pb, 212Bi; measured not abstracted; deduced nuclear properties.
Nucl.Phys. 61, 601 (1965)
K.D.Sevier
A Determination of the psec Half Life of the 39.85 keV Level in Tl208
RADIOACTIVITY 212Bi[from Th(B+C)]; measured α ce-delay. 208Tl deduced T1/2 (39.85 keV level).
doi: 10.1016/0029-5582(65)90610-3
Proc.Phys.Soc.(London) 86, 423 (1965)
J.Walker, T.Salgir
The Branching Ratio of 212Bi(ThC)
NUCLEAR STRUCTURE 212Bi; measured not abstracted; deduced nuclear properties.
doi: 10.1088/0370-1328/86/2/123
Z.Physik 197, 328 (1966)
K.Ilgen
Verzweigungsverhaltnisse und Konversionskoeffizienten von Angeregten Zustanden des 208Tl
NUCLEAR STRUCTURE 212Bi; measured not abstracted; deduced nuclear properties.
Thesis, Univ.Amsterdam (1966); NP-16835 (1966)
S.S.Klein
An Alpha-Gamma Correlation Spectrometer Using Surface Barrier Alpha Detectors. Application to the Measurement of Angular Correlations in the Decay of 212Bi to 208Tl
RADIOACTIVITY 212Bi; measured αγ-coin, αγ(θ). 208Tl levels deduced γ-mixing, J, π.
Nuovo Cimento 49B, 125 (1967)
R.Benoit, G.Bertolini, F.Cappellani, G.Restelli
Decay of the Excited Levels of 208Tl
NUCLEAR STRUCTURE 212Bi; measured not abstracted; deduced nuclear properties.
Rev.Mod.Phys. 39, 125 (1967)
J.A.Bearden, A.F.Burr
Reevaluation of X-Ray Atomic Energy Levels
doi: 10.1103/RevModPhys.39.125
Nucl.Instr.Methods 61, 181 (1968)
T.Doke, M.Miyajima
A Method of Measuring Alpha-Gamma Angular Correlation Using Cathode Pulses in a Gridded Ionization Chamber
RADIOACTIVITY 212Bi; measured αγ(θ).
Phys.Letters 30A, 312 (1969)
L.Varga, S.Koicki
Perturbed α-γ Angular Correlation Study of Internal Fields Acting on Recoil Implanted 208Tl in Iron
RADIOACTIVITY 212Bi; measured αγ(θ, H, t) in Fe; deduced no transient internal field.
doi: 10.1016/0375-9601(69)91014-7
C.R.Acad.Sci., Ser.B 277, 467 (1973)
J.Dalmasso, H.Maria, C.Ythier
Etude du Rayonnement γ du Thorium 228 et de Ses Derives, et Plus Particulierement du Thallium 208(ThC'')
RADIOACTIVITY 208Tl; measured Eγ, Iγ. Deduced log ft. 208Pb deduced levels, J, π, γ-multipolarities.
Res.Inst.Phys., Stockholm, 1973, Ann.Rept., p.130 (1973)
H.Slatis, S.-O.Hilding
The New, Striated, Photographic Plate Method Introduced in 1972 and 1973 has Revealed Further Lines in the 86-396 keV Region of the Beta-Ray Spectrum of Thoron
RADIOACTIVITY 212Pb, 212Bi, 208Tl; measured E(ce). 212Bi, 208Tl, 208Pb deduced transitions.
Phys.Rev. C17, 380 (1978)
F.T.Avignone III, A.G.Schmidt
γ-Ray and Internal-Conversion Intensity Studies of Transitions in the Decay of 228Th
RADIOACTIVITY 228Th + products; measured Eγ, Iγ, I(ce). 212Bi, 208Pb, 212Po, 208Tl transitions deduced ICC, λ, δ.
Nucl.Instrum.Methods 196, 561 (1982)
S.Sadasivan, V.M.Raghunath
Intensities of Gamma Rays in the 232Th Decay Chain
RADIOACTIVITY 232Th(α); 228Ra(β-); 228Ac(β-); 228Th(α); 224Ra(α); 212Pb(β-) [from 224Ra decay chain]; 212Bi(α); 208Tl(β-); measured Eγ, Iγ.
Int.J.Appl.Radiat.Isotop. 34, 533 (1983)
U.Schotzig, K.Debertin
Photon Emission Probabilities per Decay of 226Ra and 232Th in Equilibrium with their Daughter Products
RADIOACTIVITY 226Ra(α); 214Pb(β-) [from 226Ra decay chain]; 214Bi(α) [from 214Pb decay]; measured Eγ, Iγ, E(X-ray), I(X-ray), X-ray, γ-emission probabilities. 232Th(α); 228Ac(β-) [from 228Ra β-decay]; 212Pb(β-) [from 216Po α-decay]; 212Bi(α) [from 212Pb β-decay]; 208Tl (β-) [from 212Bi α-decay]; measured γ-emission probabilities.
doi: 10.1016/0020-708X(83)90275-2
Int.J.Appl.Radiat.Isotop. 35, 581 (1984)
R.J.Gehrke, V.J.Novick, J.D.Baker
γ-Ray Emission Probabilities for the 232U Decay Chain
RADIOACTIVITY 232U(α); 228Th(α) [from 232U decay]; 224Ra(α) [from 228Th decay]; 220Rn(α) [from 224Ra decay]; 216Po(α) [from 220Rn decay]; 212Pb(β-) [from 216Po decay]; 212Bi(α), (β-) [from 212Pb decay]; 212Po(α) [from 212Bi decay]; 208Tl(β-) [from 212Bi decay]; measured γ-emission probabilities. 4π αγ-coincidence counting, γ-spectroscopic methods.
doi: 10.1016/0020-708X(84)90100-5
Rev.Mod.Phys. 59, 1121 (1987)
E.R.Cohen, B.N.Taylor
The 1986 Adjustment of the Fundamental Physical Constants
doi: 10.1103/RevModPhys.59.1121
At.Data Nucl.Data Tables 47, 205 (1991)
A.Rytz
Recommended Energy and Intensity Values of Alpha Particles from Radioactive Decay
RADIOACTIVITY A=146-257; compiled Eα, Iα; deduced recommended values.
doi: 10.1016/0092-640X(91)90002-L
Nucl.Data Sheets 66, 171 (1992)
A.Artna-Cohen
Nuclear Data Sheets for A = 212
COMPILATION 212Pb, 212Bi, 212Po, 212At, 212Rn, 212Fr, 212Ra, 212Ac, 212Th; compiled, evaluated structure data.
Nucl.Phys. A729, 337 (2003)
G.Audi, A.H.Wapstra, C.Thibault
The AME2003 atomic mass Evaluation (II). Tables, graphs, and references
COMPILATION A=1-293; compiled, evaluated atomic mass data.
doi: 10.1016/j.nuclphysa.2003.11.003
ANU-P/1684 (2005)
T.Kibedi, T.W.Burrows, M.B.Trzhaskovskaya, C.W.Nestor, Jr.
BRICC Program Package V 2.0