1 Decay Scheme. 2 Nuclear Data. 2.1 α Transitions
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1 1 Decay Scheme Am decays by emission of alpha particles to Np239, with a minute branch of 3.8 (7) 10 9 % by spontaneous fission. L américium se désintègre par émission alpha vers le neptunium 239. Un faible branchement (3,8 (7) 10 9 %) par fission spontanée existe. 2 Nuclear Data T 1/2 ( Am ) : 7367 (23) a T 1/2 ( 239 Np ) : 2,356 (3) d Q α ( Am ) : 5438,8 (10) 2.1 α Transitions Probability F 100 α 0, (3) 0,0017 (5) 7,2 α 0, (3) 0, α 0, (3) 0, α 0, (3) 0, α 0, (3) 0,0009 (4) 900 α 0, (3) 0,0009 (4) α 0, (3) 0,0020 (6) 700 α 0, (3) 0,0020 (6) α 0, (5) 0,0055 (6) 1100 α 0, (1) 0,010 (1) 900 α 0, (1) 1,383 (7) 17,7 α 0,4 5320,9 (10) 11,46 (5) 4,71 α 0,3 5363,6 (10) 86,74 (5) 1,14 α 0, (1) 0,192 (3) 95 α 0,0 5438,9 (23) 0,240 (3) 1120 LBNL,LNHB,INEEL /E.Browne,M.M. Bé, R.G.Helmer 1 22/09/ /2/2010
2 2.2 Gamma Transitions and Internal Conversion Coefficients P γce Multipolarity α K α L α M α T 100 γ 1,0(Np) 31,130 (21) 12,7 (30) M13,08%E2 195 (10) 50 (3) 263 (13) γ 4,3(Np) 43,2 10,1 M112,6%E2 114 (13) 30 (4) 154 (18) γ 3,1(Np) 43,53 (2) 12,62 (23) E1 0,856 (12) 0,215 (3) 1,143 (16) γ 6,5(Np) 50,6 (10) 0,011 (2) (E1) 0,58 (4) 0,144 (9) 0,77 (5) γ 6,4(Np) 55,18 (5) 1,81 (26) M126,4%E2 78 (10) 21 (3) 107 (14) γ 3,0(Np) 74,66 (2) 85,7 (16) E1 0,207 (3) 0,0512 (8) 0,276 (4) γ 4,1(Np) 86,71 (2) 0,41 (1) E1 0,1401 (20) 0,0345 (5) 0,186 (3) γ 6,3(Np) 98,360 (44) 0,25 (4) (E2) 11,31 (20) 3,15 (6) 15,6 (3) γ 4,0(Np) 117,84 (15) 0,62 (5) E1 0,0634 (10) 0,01551 (23) 0,0842 (13) γ 6,1(Np) 141,90 (6) 0,141 (10) E1 0,1723 (25) 0,0391 (6) 0,00955 (14) 0,224 (4) γ 7,2(Np) 169 0,0014 (E1) 0,1156 (23) 0,0251 (6) 0,00612 (13) 0,149 (3) γ 9,5(Np) 195,0 (18) 0,001 (E1) 0,0833 (22) 0,0176 (5) 0,00428 (12) 0,107 (3) 3 Atomic Data 3.1 Np ω K : 0,971 (4) ω L : 0,511 (20) n KL : 0,791 (5) X Radiations Relative probability K Kα 2 97,069 62,82 Kα 1 101, Kβ 3 113,303 } Kβ 1 114,234 } Kβ 5 114,912 } 36,21 Kβ 2 117,463 } Kβ 4 117,876 } 12,47 KO 2,3 118,429 } L Ll 11,871 Lα 13,671 13,946 Lη 15,861 Lβ 16,109 17,992 Lγ 20,784 21,491 LBNL,LNHB,INEEL /E.Browne,M.M. Bé, R.G.Helmer 2 22/09/ /2/2010
3 3.1.2 Auger Electrons Relative probability Auger K KLL 73,501 83, KLX 90, ,054 60,2 KXY 107,19 118,66 9,06 Auger L 6,04 13,52 4 α Emissions Probability 100 α 0, (3) 0,0017 (5) α 0, (3) 0, α 0, (3) 0,00018 α 0, (3) 0,00034 α 0, (3) 0,0009 (4) α 0, (3) 0,0009 (4) α 0, (3) 0,0020 (6) α 0, (3) 0,0020 (6) α 0, (5) 0,0055 (6) α 0, (1) 0,010 (1) α 0, (1) 1,383 (7) α 0,4 5233,3 (10) 11,46 (5) α 0,3 5275,3 (10) 86,74 (5) α 0, (1) 0,192 (3) α 0,0 5349,4 (23) 0,240 (3) 5 Electron Emissions Electrons per 100 disint. e AL (Np) 6,04 13,52 18,4 (11) e AK (Np) 0,00058 (9) KLL 73,501 83,134 } KLX 90, ,054 } KXY 107,19 118,66 } LBNL,LNHB,INEEL /E.Browne,M.M. Bé, R.G.Helmer 3 22/09/ /2/2010
4 Electrons per 100 disint. ec 1,0 L (Np) 8,70 13,52 9,4 (22) ec 4,3 L (Np) 20,8 25,6 7,4 (8) ec 3,1 L (Np) 21,10 25,92 5,04 (11) ec 1,0 M (Np) 25,39 27,47 2,4 (6) ec 1,0 N (Np) 29,63 30,73 0,65 (15) ec 6,4 L (Np) 32,753 37,570 1,10 (33) ec 4,3 M (Np) 37,5 39,5 1,95 (26) ec 3,1 M (Np) 37,79 39,87 1,266 (28) ec 4,3 N (Np) 41,7 42,8 0,53 (6) ec 3,1 N (Np) 42,03 43,13 0,336 (7) ec 6,4 M (Np) 49,441 51,516 0,30 (9) ec 3,0 L (Np) 52,23 57,05 13,91 (32) ec 6,4 N (Np) 53,679 54,777 0,08 (2) ec 3,0 M (Np) 68,92 71,00 3,44 (8) ec 3,0 N (Np) 73,16 74,26 0,917 (21) ec 6,3 L (Np) 76,073 80,890 0,17 (2) ec 6,3 M (Np) 92,761 94,836 0,05 (1) 6 Photon Emissions 6.1 XRay Emissions Photons per 100 disint. XL (Np) 11,871 21,491 18,9 (7) XKα 2 (Np) 97,069 0,0058 (4) } Kα XKα 1 (Np) 101,059 0,0092 (7) } XKβ 3 (Np) 113,303 } XKβ 1 (Np) 114,234 } 0,00335 (25) K β 1 XKβ 5 (Np) 114,912 } XKβ 2 (Np) 117,463 } XKβ 4 (Np) 117,876 } 0,00115 (9) K β 2 XKO 2,3 (Np) 118,429 } LBNL,LNHB,INEEL /E.Browne,M.M. Bé, R.G.Helmer 4 22/09/ /2/2010
5 6.2 Gamma Emissions Photons per 100 disint. γ 1,0 (Np) 31,14 (3) 0,048 (11) γ 4,3 (Np) 43,1 0,065 γ 3,1 (Np) 43,53 (2) 5,89 (10) γ 6,5 (Np) 50,6 (10) 0,0062 (10) γ 6,4 (Np) 55,18 (5) 0,0168 (11) γ 3,0 (Np) 74,66 (2) 67,2 (12) γ 4,1 (Np) 86,71 (2) 0,346 (9) γ 6,3 (Np) 98,5 (2) 0,0151 (21) γ 4,0 (Np) 117,60 (15) 0,57 (5) γ 6,1 (Np) 141,90 (6) 0,115 (8) γ 7,2 (Np) 169 0,0012 γ 9,5 (Np) 195,0 (18) 0, Main Production Modes Pu 239(mult. ncapture) U 238(mult. ncapture) 8 References M.M.Bé, V. Chisté, C. Dulieu, E. Browne, V. Chechev, N. Kuzmenko, R. Helmer, A. Nichols, E. Schönfeld, R. Dersch.. Monographie BIPM5, ISBN () (Am241 halflife) F. Stephens, J. Hummel, F. Asaro. Phys. Rev. 98 (1955) 261 (Am alphaparticle emission probabilities.) J.P. Hummel. Thesis. Univ. of California UCRL3456 (1956) (Am alphaparticle emission probabilities.) R.F. Barnes, D.J. Henderson, A.L. Harkness, H. Diamond. J. Inorg. Nucl. Chem. 9 (1959) 105 (Am halflife.) F. Asaro, F.S. Stephens, J.M. Hollander, I. Perlman. Phys. Rev. 117 (1960) 492 (Am gammaray emission probabilities.) A.B. Beadle, D.F. Dance, K.M. Glover, J. Milsted. J. Inorg. Nucl. Chem. 12 (1960) 359 (Am halflife.) S.A. Baranov, V.M. Kulakov, V.M. Shatinsky. Nucl. Phys. 56 (1964) 252 (Am alphaparticle energies and emission probab) C.M. Lederer, J.K. Poggenburg, F. Asaro, J.O. Rasmussen, I. Perlman. Nucl. Phys. 84 (1966) 481 (Am alphaparticle emission probabilities.) B.A. Gvozdev, B.B. Zakhvataev, V.I. Kuznetsov, V.P. Perelygin, S.V. Pirozkov, E.G. Chudinov, I.K. Shvetsov. Sov. Radiochem. 8 (1966) 459 (Spontaneous fission branching) S.A. Baranov, V.M. Kulakov, V.M. Shatinskii. Sov. J. Nucl. Phys. 7 (1968) 442 (Am alphaparticle energies.) G. Berzins, M.E. Bunker, J.W. Starner. Nucl. Phys. A114 (1968) 512 (Am halflife.) J.R. Van Hise, D. Engelkemeir. Phys. Rev. 171 (1968) 1325 (Am gammaray energies and emission probabilities.) LBNL,LNHB,INEEL /E.Browne,M.M. Bé, R.G.Helmer 5 22/09/ /2/2010
6 D. Engelkemeir. Phys. Rev. 181 (1969) 1675 (Am gammaray energies.) B.M. Aleksandrov, O.I. Grigorev, N.S. Shimanskaya. Soviet J. Nucl. Phys. 10 (1970) 8 (Am gammaray emission probabilities.) I. Ahmad, M. Wahlgren. Nucl. Instrum. Methods 99 (1972) 333 (Am gammaray emission probabilities. ) V.G. Polyukov, G.A. Timofeev, P.A. Privalova, V.Y. Gabeskiriya, A.P. Chetverikov. Sov. At. Energ. 37 (1975) 1103 (Am halflife.) J.C. Pate, K.R. Baker, R.W. Fink, D.A. McClure, N.S. Kendrick Jr.. Z. Phys. A272 (1975) 169 (Am gammaray energies and emission probabilities.) D.I. Starozhukov, Y.S. Popov, P.A. Privalova. Sov. At. 42 (1977) 355 (Am gammaray emission probabilities. ) F.P. Larkins. At. Data Nucl. Data Tables 20 (1977) 311 (Atomic electron binding energies.) F. Rösel, H.M. Fries, K. Alder, H.C. Pauli. At. Data Nucl. Data Tables 21 (1978) 92 (gammaray theoretical internal conversion coefficients.) Y.S. Popov, D.I. Starozhukov, V.B. Mishenev, P.A. Privalova, A.I. Mishchenko. Sov. At. 46 (1979) 123 (Am gammaray emission probabilities.) S.K. Aggarwal, A.R. Parab, H.C. Jain. Phys. Rev. C22 (1980) 767 (Am halflife.) I. Ahmad. Nucl. Instrum. Methods 193 (1982) 9 (Am gammaray energies and emission probabilities.) R. Vaninbroukx, G. Bortels, B. Denecke. Int. J. Appl. Radiat. Isotop. 35 (1984) 1081 (Am gammaray emission probabilities.) W.L. Zijp. Report ECN FYS/RASA85/19 (1985) (Discrepant Data Limited Relative Statistical Weight Method.) A. Lorenz. IAEA Tech. Rept. Ser. 261 (1986) (Am recommended halflife. ) E. Browne. Nucl. Instrum. Methods Phys. Res. A265 (1988) 541 (Uncertainties in alphaparticle emission probabilities.) W. Bambynek, T. Barta, R. Jedlovszky, P. Christmas, N. Coursol, K. Debertin, R.G. Helmer, A.L. Nichols, F.J. Schima, Y. Yoshizawa. IAEATECDOC619 (1991) (Am recommended halflife.) A. Rytz. At. Data Nucl. Data Tables 47 (1991) 205 (Am alphaparticle energies.) E. GarciaTorano, M.L. Acena, G. Bortels, D. Mouchel. Nucl. Instrum. Methods Phys. Res. A312 (1992) 317 (Am alphaparticle energies and emission probabilities.) Y.A. Akovali. Nucl. Data Sheets 66 (1992) 897 (Am recommended halflife.) E. Schönfeld, H. Janssen. Nucl. Instrum. Methods. Phys. Res. A369 (1996) 527 (Atomic data, Xrays, Auger electrons.) D. Sardari, T.D. Mac Mahon, S.P. Holloway. Nucl. Instrum. Methods Phys. Res. A369 (1996) 486 (Am gammaray energies and emission probabilities.) S.A. Woods, D.H. Woods, M.J. Woods, S.M. Jerome, M. Burke, N.E. Bowles, S.E.M. Lucas, C. Paton. Nucl. Instrum. Methods Phys. Res. A369 (1996) 472 (Am gammaray emission probabilities.) A.M. Sanchez, P.R. Montero, F.V. Tome. Nucl. Instrum. Methods Phys. Res. A369 (1996) 593 (Am alphaparticle energies and emission probabilities.) E.Schönfeld, G. Rodloff. Report PTB , Braunschweig (1998) (Auger electron energies.) Y.A. Akovali. Nucl. Data Sheets 84 (1998) 1 (Alpha decay. Radius parameter of eveneven nuclei.) Jichun Yang, Jianzhong Ni. Nucl. Instrum. Methods Phys. Res. A413 (1998) 239 (Alpha emission intensities) E. Schönfeld, H. Janssen. Applied Radiation Isotopes 52 (2000) 595 (Xray and Auger electron emission probabilities.) LBNL,LNHB,INEEL /E.Browne,M.M. Bé, R.G.Helmer 6 22/09/ /2/2010
7 F. Dayras. Nucl. Instrum. Methods Phys. Res. A490 (2002) 492 (Am alphaparticle energies and emission probabilities.) R. Sampathkumar, P.C. Kalsi, A. Ramaswami. J. Radioanal. Nucl. Chem. 253 (2002) 523 (Am spontaneous fission branching.) G. Audi, A.H. Wapstra, C. Thibault. Nucl. Phys. A729 (2003) 337 (2003 Atomic Mass Adjustment.) E. Browne. Nucl. Data Sheets 98 (2003) 665 (Evaluated data (ENSDF for nuclei with A=239)) S.K. Aggarwal, et al.. Nucl. Instrum. Methods Phys. Res. A571 (2007) 663 (Am halflife.) T. Kibedi, T.W. Burrows, M.B. Trzhaskovskaya, P.M. Davidson, and C.W.Nestor, Jr. Nucl. Instrum. Methods Phys. Res. A589 (2008) 202 (Theoretical Internal Conversion Coefficients) LBNL,LNHB,INEEL /E.Browne,M.M. Bé, R.G.Helmer 7 22/09/ /2/2010
8 LNELNHB/CEA Table de Radionucléides γ Emission intensities per 100 disintegrations 0 α Am /2 ; (23) a 95Am148 0, (5/2) ; (11/2) ; , , , , (9/2) ; 359 (7/2,9/2) ; 347 (5/2) ; 325 (13/2) ; 317,4 0,0009 0,0009 0,002 0,002 0, , (5/2) ; 267 (11/2) ; 240 0, ,00 0,01 0,01 0,11 9/2 ; 173,02 1,383 0,04 ns ,06 0,34 0,57 (11/2) ; 122,4 7/2 ; 117,84 11,46 1,39 ns 2,356 (3) d ,89 6 7,2 239 Np α Q = 5438,8 % α = ,04 5/2 ; 74,66 9/2 ; 71 7/2 ; 31,13 5/2 ; 0 LBNL, LNHB, INEEL / E.Browne,M.M. Bé,R.G.Helmer Scheme page : 1/1 22/09/ /05/ ,74 0,192 0,24
1 Decay Scheme. 2 Nuclear Data. 2.1 α Transitions
1 Decay Scheme Cf- disintegrates by alpha emissions mainly to the Cm-248 ground state level, and by spontaneous fission for 3,086(8) %. The average number of neutrons emitted by spontaneous fission is:
1 Decay Scheme. 2 Nuclear Data. 2.1 β Transitions
1 Decay Scheme Np decays 87,8 (6) % by electron capture to U, 12,0 (6) % by beta minus emission to Pu, a possible alpha emission of 0,16 (6)% to Pa232 has not been observed. Le neptunium se désintègre
1 Decay Scheme. 2 Nuclear Data. 236m. 2.1 Electron Capture Transitions. 2.2 β Transitions
1 Decay Scheme Np- (isomer state of Np-236, J=1, E1 =60 ) decays 53(1) % by electron capture to U-236 and 47(1) % by beta minus emission to Pu-236. Le neptunium 236 isomère se désintègre par capture électronique
1 Decay Scheme. 2 Nuclear Data. 2.1 α Transitions
1 Decay Scheme Bi- undergoes beta decay to Po- (64.07(7)%), and alpha decay to Tl-208 (35.93(7)%). 0.014(1)% of the beta branch undergoes prompt long-range alpha decay to Pb-208. Le bismuth se désintègre
1 Decay Scheme. 2 Nuclear Data. 2.1 α Transitions
1 Decay Scheme Pa is a member of the natural U235 decay chain. Pa disintegrates by alpha emission to various excited levels and the ground state of Ac227. Le protactinium se désintègre par émissions alpha
1 Decay Scheme. 2 Nuclear Data. 2.1 β Transitions
1 Decay Scheme Pb ground state (J π = 9/2 + ) decays by 100 % beta minus to Bi. The strongest branch (91.28 (12) %) decays directly to the ground state (J π = 9/2 ). Le plomb se désintègre par émissions
1 Decay Scheme. 2 Nuclear Data. 2.1 Electron Capture Transitions. 2.2 β Transitions
1 Decay Scheme Le césium se désintègre essentiellement par émission bêta moins vers des niveaux excités du baryum. Cs- desintegrates mainly by beta minus emissions to excited levels in Ba-. 2 Nuclear Data
1 Decay Scheme. 2 Nuclear Data. 2.1 β Transitions. 2.2 Gamma Transitions and Internal Conversion Coefficients
1 Decay Scheme Pb disintegrates by beta minus emission to excited levels and to the ground state level of Bi. Le plomb se désintègre par émission bêta moins vers des niveaux excités et le niveau fondamental
1 Decay Scheme. 2 Nuclear Data. 2.1 α Transitions
1 Decay Scheme Cm decays 1% by alpha transitions to Pu38 and by spontaneous fission with branching fraction of 6.36 (14) E6 %. Le curium se désintègre à 1% par transition alpha vers le plutonium 38 et
1 Decay Scheme. 2 Nuclear Data. 2.1 α Transitions
1 Decay Scheme Bi- disintegrates 97.91(3) % by beta minus emission to the levels in Po- and 2.09(3) % through alpha decay to Tl-209. Le bismuth se désintègre principalement par émissions bêta vers le polonium
1 Decay Scheme. 2 Nuclear Data. 2.1 α Transitions
1 Decay Scheme Uranium decays primarily by alpha decay to excited states in Th-228. A small branching of exotic decay via Ne-24 emission and a smaller branching of spontaneous fission have been reported.
1 Decay Scheme. 2 Nuclear Data. 2.1 α Transitions
1 Decay Scheme Cm- decays 100% by alpha transitions to Pu-240 and by spontaneous fission with branching fraction of 1.36 (1) E-4 %. Le curium se désintègre par émission alpha et par fission spontanée dans
1 Decay Scheme. 2 Nuclear Data. 2.1 α Transitions
1 Decay Scheme U- disintegrates by alpha emission mainly to the ground and 49- states in Th-232, and by 9,3 10 8 % spontaneous fission. L uranium se désintègre par émission alpha et par fission spontanée
1 Decay Scheme. 2 Nuclear Data. 2.1 Electron Capture Transitions. 2.2 Gamma Transitions and Internal Conversion Coefficients
1 Decay Scheme Se disintegrates 100% by electron capture to excited levels and to the ground state of As. Le Se se désintègre à 100% par capture électronique vers des niveaux excités et le niveau fondamental
1 Decay Scheme. 2 Nuclear Data. 2.1 β + Transitions. 2.2 Electron Capture Transitions
1 Decay Scheme Ni disintegrates by electron capture (56.6 %) and positron emission (43.4 %) to excited levels in Co. The transition to the ground state has not been observed. Le nickel se désintègre par
1 Decay Scheme. 2 Nuclear Data. 2.1 Electron Capture Transitions. 2.2 Gamma Transitions and Internal Conversion Coefficients
1 Decay Scheme In- disintegrates by > 99.99% electron capture via the excited level of 416.6 in Cd- and by < 0.01% electron capture via the isomer level in Cd- (T 1/2 = 48.5 min) at 396.2. Transitions
1 Decay Scheme. 2 Nuclear Data. 2.1 Electron Capture Transitions
1 Decay Scheme I- disintegrates by electron capture mainly via the 159 level of Te- (97%). L iode se désintègre par capture électronique principalement vers le niveau excité de 159 du tellure, avec une
1 Decay Scheme. 2 Nuclear Data. 2.1 Electron Capture Transitions. 2.2 Gamma Transitions and Internal Conversion Coefficients
1 Decay Scheme Sn- decays by electron capture mainly to the In-m isomer which has a half-life of 99 minutes. After a sufficient time, the ratio of the In-m (99 min) and Sn- activities remains constant
1 Decay Scheme. 2 Nuclear Data. 2.1 α Transitions
1 Decay Scheme Pu- decays 100% by alpha transitions to U-234. Most of the alpha decay populates the U-234 ground state (71.04 %) and the U-234 first excited level with energy of 43.50 (28.85 %). Branching
1 Decay Scheme. 2 Nuclear Data. 2.1 α Transitions
1 Decay Scheme Pu- decays approximately 100 % by beta minus emission to the ground state of Am- and 0,00244 % by alpha emission to levels of U-237. The spontaneous fission decay branching is less than
1 Decay Scheme. 2 Nuclear Data. 2.1 β Transitions
1 Decay Scheme Rh- disintegrates by beta minus emission to the ground state and excited levels of Pd-. Le rhodium se désintègre par émission bêta principalement vers le niveau fondamental et les niveaux
1 Decay Scheme. 2 Nuclear Data. 2.1 Electron Capture Transitions. 2.2 Gamma Transitions and Internal Conversion Coefficients
1 Decay Scheme Co disintegrates by 100% electron capture to the excited levels of 706.42 (0.18%), and 136.47 (99.82%) in Fe. Le cobalt se désintègre à 100 % par capture électronique principalement vers
1 Decay Scheme. 2 Nuclear Data. 2.1 β Transitions. 2.2 Gamma Transitions and Internal Conversion Coefficients
1 Decay Scheme Eu- disintegrates 100 % via beta minus disintegration to excited levels and to the ground state in Gd-. L europium se désintègre par émission bêta moins vers des niveaux excités et le niveau
1 Decay Scheme. 2 Nuclear Data. 2.1 β Transitions
1 Decay Scheme Nd- disintegrates by beta minus emission to excited levels of Pm-. If a transition to the ground state level exists, it is less than 0.15 %. Le néodyme se désintègre par émission bêta moins
1 Decay Scheme. 2 Nuclear Data. 2.1 Electron Capture Transitions. 2.2 Gamma Transitions and Internal Conversion Coefficients
1 Decay Scheme Pb- disintegrates by electron capture to Tl- via excited levels. Le plomb se désintègre par capture électronique vers des niveaux excités du thallium. 2 Nuclear Data T 1/2 ( Pb ) : 51,929
1 Decay Scheme. 2 Nuclear Data. 2.1 Electron Capture Transitions
1 Decay Scheme - disintegrates 19.58 (11) % by beta plus emission and 8.2 (11) % by electron capture to Fe-. - emits gamma rays with energies up to 612 and the energies and emission probabilities for many
1 Decay Scheme. 2 Nuclear Data. 2.1 Electron Capture Transitions. 2.2 Gamma Transitions and Internal Conversion Coefficients
1 Decay Scheme Co decays 100% by electron capture to the excited levels of 706.42 kev (0.183%) and 136.47 kev (99.80%) in Fe. Le cobalt se désintègre par capture électronique vers des niveaux excités du
1 Decay Scheme. 2 Nuclear Data. 2.1 Electron Capture Transitions. 2.2 β + Transitions
1 Decay Scheme Zr- (half-life of 78.42 h) undergoes 100% EC/positron decay (Q EC of 2832.8(28) kev) to various nuclear levels, including the metastable and ground states of Y-. Le zirconium se désintègre
1 Decay Scheme. 2 Nuclear Data. 2.1 Electron Capture Transitions
1 Decay Scheme Ba disintegrates by electron capture mainly to two Cs excited levels of 437 kev (85.4%) and of 383 kev (14.5%) with three very minor branches to the 160 kev, 81 kev excited levels and the
Th, Ra, Rn, Po, Pb, Bi, & Tl K x-rays. Rn Kα1. Rn Kα2. 93( 227 Th)/Rn Kβ3. Ra Kα2. Po Kα2 /Bi K α1 79( 227 Th)/Po Kα1. Ra Kα1 /Bi K β1.
Page -1-10 8 10 7 10 6 10 5 10 4 334 ( Th) Counts/Channel 10 3 10 2 10 1 49 ( Th)/ 50 ( Th)/ 50 ( Fr) 0 100 200 300 400 500 600 700 800 900 1000 1000 1100 1200 1300 1400 1500 1600 1700 1800 1900 2000 Channel
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Appendix B Table of Radionuclides Γ Container 1 Posting Level cm per (mci) mci
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