Talk:Isotopes of silver/Archive 1
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| Archive 1 |
Data 2003
This article is part of Wikipedia:Wikiproject Isotopes. Please keep style and phrasings consistent across the set of pages. For later reference and improved reliability, data from all considered multiple sources is collected here. References are denoted by these letters:
- (A) G. Audi, O. Bersillon, J. Blachot, A.H. Wapstra. The Nubase2003 evaluation of nuclear and decay properties, Nuc. Phys. A 729, pp. 3-128 (2003). — Where this source indicates a speculative value, the # mark is also applied to values with weak assignment arguments from other sources, if grouped together. An asterisk after the A means that a comment of some importance may be available in the original.
- (B) National Nuclear Data Center, Brookhaven National Laboratory, information extracted from the NuDat 2.1 database. (Retrieved Sept. 2005, from the code of the popup boxes).
- (C) David R. Lide (ed.), Norman E. Holden in CRC Handbook of Chemistry and Physics, 85th Edition, online version. CRC Press. Boca Raton, Florida (2005). Section 11, Table of the Isotopes. — The CRC uses rounded numbers with implied uncertainties, where this concurs with the range of another source it is treated as exactly equal in this comparison.
- (D) More specific level data from reference B's Levels and Gammas database.
- (E) Same as B but excitation energy replaced with that from D.
Z N refs symbol half-life spin excitation energy 47 46 A* |Ag-93 |5# ms [>1.5 µs] |9/2+# 47 46 B |Ag-93 |>1.5 µs | 47 47 A |Ag-94 |37(18) ms |0+# 47 47 B |Ag-94 |26(+26-9) ms |(0+) 47 47 C |Ag-94 |0.38 s | 47 47 A |Ag-94m1 |422(16) ms |(7+) |1350(400)# keV 47 47 B |Ag-94m1 |0.59(2) s |(7+) |0 MeV 47 47 D |Ag-94m1 |0.36(3) s |(7+) |0+X keV 47 47 A |Ag-94m2 |300(200) ms |(21+) |6500(2000)# keV 47 47 B |Ag-94m2 |0.47(8) s |(21+) |0 MeV 47 47 D |Ag-94m2 |0.3(2) s |(>=17) |0+Y keV 47 47 C |Ag-94m |0.03 s | 47 48 A |Ag-95 |1.74(13) s |(9/2+) 47 48 B |Ag-95 |2.0(1) s | 47 48 C |Ag-95 |2.0 s | 47 48 A |Ag-95m1 |<0.5 s |(1/2-) |344.2(3) keV 47 48 A |Ag-95m2 |<16 ms |(23/2+) |2531(1) keV 47 48 A |Ag-95m3 |<40 ms |(37/2+) |4859(1) keV 47 49 A |Ag-96 |4.45(4) s |(8+) 47 49 B |Ag-96 |4.40(6) s |(8+) 47 49 C |Ag-96 |7. s |2+ 47 49 A |Ag-96m1 |6.9(6) s |(2+) |0(50)# keV 47 49 B |Ag-96m1 |6.9(6) s |(2+) |0 MeV 47 49 D |Ag-96m1 |5.1(4) s |(8+,9+) |0 keV 47 49 C |Ag-96m1 |4.4 s |8+ 47 49 A |Ag-96m2 |700(200) ns | | 47 50 A |Ag-97 |25.3(3) s |(9/2+) 47 50 B |Ag-97 |25.9(4) s |9/2+ 47 50 C |Ag-97 |19. s | 47 51 A |Ag-98 |47.5(3) s |(5+) 47 51 B |Ag-98 |47.5(3) s |(6+) 47 51 C |Ag-98 |47.6 s |5+ 47 51 A |Ag-98m |220(20) ns |(3+) |167.83(15) keV 47 52 AB |Ag-99 |124(3) s |(9/2)+ 47 52 C |Ag-99 |2.07 min |9/2+ 47 52 AE |Ag-99m |10.5(5) s |(1/2-) |506.1(4) keV 47 52 C |Ag-99m |11. s |1/2- 47 53 AB |Ag-100 |2.01(9) min |(5)+ 47 53 C |Ag-100 |2.0 min |5+ 47 53 AE |Ag-100m |2.24(13) min |(2)+ |15.52(16) keV 47 53 C |Ag-100m |2.3 min |2+ 47 54 ABC |Ag-101 |11.1(3) min |9/2+ 47 54 A |Ag-101m |3.10(10) s |1/2- |274.1(3) keV 47 54 E |Ag-101m |3.10(10) s |(1/2)- |274.1(3) keV 47 54 C |Ag-101m |3.1 s |1/2- 47 55 AB |Ag-102 |12.9(3) min |5+ 47 55 C |Ag-102 |13.0 min |5+ 47 55 AE |Ag-102m |7.7(5) min |2+ |9.3(4) keV 47 55 C |Ag-102m |7.8 min |2+ 47 56 AB |Ag-103 |65.7(7) min |7/2+ 47 56 C |Ag-103 |1.10 h |7/2+ 47 56 AE |Ag-103m |5.7(3) s |1/2- |134.45(4) keV 47 56 C |Ag-103m |5.7 s |1/2- 47 57 ABC |Ag-104 |69.2(10) min |5+ 47 57 AE |Ag-104m |33.5(20) min |2+ |6.9(4) keV 47 57 C |Ag-104m |33. min |2+ 47 58 ABC |Ag-105 |41.29(7) d |1/2- 47 58 AE |Ag-105m |7.23(16) min |7/2+ |25.465(12) keV 47 58 C |Ag-105m |7.2 min |7/2+ 47 59 AB |Ag-106 |23.96(4) min |1+ 47 59 C |Ag-106 |24.0 min |1+ 47 59 AE |Ag-106m |8.28(2) d |6+ |89.66(7) keV 47 59 C |Ag-106m |8.4 d |6+ 47 60 ABC |Ag-107 |STABLE |1/2- 47 60 A |Ag-107m |44.3(2) s |7/2+ |93.125(19) keV 47 60 E |Ag-107m |44.5(8) s |7/2+ |93.125(19) keV 47 60 C |Ag-107m |44.2 s |7/2+ 47 61 AB |Ag-108 |2.37(1) min |1+ 47 61 C |Ag-108 |2.39 min |1+ 47 61 A* |Ag-108m |418(21) a |6+ |109.440(7) keV 47 61 E |Ag-108m |438(9) a |6+ |109.440(7) keV 47 61 C |Ag-108m |418. a |6+ 47 62 ABC |Ag-109 |STABLE |1/2- 47 62 A |Ag-109m |39.6(2) s |7/2+ |88.0341(11) keV 47 62 E |Ag-109m |38.0(12) s |7/2+ |88.0341(11) keV 47 62 C |Ag-109m |39.8 s |7/2+ 47 63 ABC |Ag-110 |24.6(2) s |1+ 47 63 D |Ag-110m1|660(40) ns |2- |1.113 keV 47 63 A |Ag-110m2|249.950(24) d |6+ |117.59(5) keV 47 63 E |Ag-110m2|249.76(4) d |6+ |117.59(5) keV 47 63 C |Ag-110m2|249.8 d |6+ 47 64 AB |Ag-111 |7.45(1) d |1/2- 47 64 C |Ag-111 |7.47 d |1/2- 47 64 AE |Ag-111m |64.8(8) s |7/2+ |59.82(4) keV 47 64 C |Ag-111m |1.08 min |7/2+ 47 65 AB |Ag-112 |3.130(9) h |2(-) 47 65 C |Ag-112 |3.13 h |2- 47 66 AB |Ag-113 |5.37(5) h |1/2- 47 66 C |Ag-113 |5.3 h |1/2- 47 66 AE |Ag-113m |68.7(16) s |7/2+ |43.50(10) keV 47 66 C |Ag-113m |1.14 min |7/2+ 47 67 AB |Ag-114 |4.6(1) s |1+ 47 67 C |Ag-114 |4.6 s |1+ 47 67 A |Ag-114m |1.50(5) ms |(<7+) |199(5) keV 47 67 D |Ag-114m |1.50(5) ms |(<=6+) |199 keV 47 68 ABC |Ag-115 |20.0(5) min |1/2- 47 68 AE |Ag-115m |18.0(7) s |7/2+ |41.16(10) keV 47 68 C |Ag-115m |18.7 s |7/2+ 47 69 AB |Ag-116 |2.68(10) min |(2)- 47 69 C |Ag-116 |2.68 min |2- 47 69 AE |Ag-116m |8.6(3) s |(5+) |81.90(20) keV 47 69 C |Ag-116m |10.5 s |5+ 47 70 A |Ag-117 |73.6(14) s |1/2-# 47 70 B |Ag-117 |72.8(+20-7) s |(1/2-) 47 70 C |Ag-117 |1.22 min |1/2- 47 70 AE |Ag-117m |5.34(5) s |(7/2+) |28.6(2) keV 47 70 C |Ag-117m |5.3 s |7/2+ 47 71 A |Ag-118 |3.76(15) s |1- 47 71 B |Ag-118 |3.76(15) s |1(-) 47 71 C |Ag-118 |4.0 s | 47 71 D |Ag-118m1|~0.1 µs |0(-) to 2(-) |45.79(9) keV 47 71 A |Ag-118m2|2.0(2) s |4(+) |127.49(5) keV 47 71 E |Ag-118m2|2.0(2) s |4(+) |127.63(10) keV 47 71 D |Ag-118m3|~0.1 µs |(2+,3+) |279.37(20) keV 47 71 C |Ag-118m |2.8 s | 47 72 A |Ag-119 |6.0(5) s |1/2-# 47 72 B |Ag-119 |2.1(1) s |(7/2+) 47 72 C |Ag-119 |2.1 s |7/2+ 47 72 A |Ag-119m |2.1(1) s |7/2+# |20(20)# keV 47 72 D |Ag-119m |2.1(1) s |(7/2+) |0+X keV 47 72 E |Ag-119m |6.0(5) s |(1/2-) |0+Y keV 47 73 AB |Ag-120 |1.23(4) s |3(+#) 47 73 C |Ag-120 |1.23 s | 47 73 A |Ag-120m |371(24) ms |6(-) |203.0(10) keV 47 73 B |Ag-120m |0.40(3) s |6(-) |0.2030 MeV 47 73 D |Ag-120m |0.32(4) s |6(-) |203.0(10) keV 47 73 C |Ag-120m |0.32 s | 47 74 AB |Ag-121 |0.79(2) s |(7/2+)# 47 74 C |Ag-121 |0.78 s | 47 75 A |Ag-122 |520(14) ms |(3+) 47 75 B |Ag-122 |0.529(13) s |(3+) 47 75 C |Ag-122 |0.44 s | 47 75 A |Ag-122m |1.5(5) s |8-# |80(50)# keV 47 75 B |Ag-122m |1.5(5) s |(8-) |0.0800 MeV 47 75 D |Ag-122m |0.48(8) s |(3+) |0 keV 47 75 C |Ag-122m |1. s | 47 76 A |Ag-123 |296(6) ms |(7/2+) 47 76 B |Ag-123 |0.300(5) s |(7/2+) 47 76 C |Ag-123 |0.31 s | 47 77 A |Ag-124 |172(5) ms |3+# 47 77 B |Ag-124 |0.172(5) s | 47 77 C |Ag-124 |0.22 s | 47 77 A* |Ag-124m |200# ms |8-# |0(100)# keV 47 77 D |Ag-124m |0.172(5) s | |0 keV 47 78 AB |Ag-125 |166(7) ms |(7/2+)# 47 78 C |Ag-125 |0.17 s | 47 79 A |Ag-126 |107(12) ms |3+# 47 79 B |Ag-126 |107(12) ms | 47 79 C |Ag-126 |0.11 s | 47 80 A |Ag-127 |79(3) ms |7/2+# 47 80 B |Ag-127 |79(3) ms |(1/2-) 47 80 C |Ag-127 |0.11 s | 47 81 ABC |Ag-128 |58(5) ms | 47 82 A* |Ag-129 |44(7) ms |7/2+# 47 82 B |Ag-129 |46(+5-9) ms |(9/2+) 47 82 C |Ag-129 |0.05 s | 47 82 A |Ag-129m |~160 ms |1/2-# |0(200)# keV 47 82 E |Ag-129m |~160 ms |(1/2-) |X keV 47 83 A |Ag-130 |~50 ms |0+ 47 83 B |Ag-130 |~50 ms |
Femto 15:46, 14 November 2005 (UTC)
comment
Why does it say "(False Information)" after the first sentence in this article stating that silver is occurs in nature in two common isotopes. I understand this is correct, as stated in :http://ie.lbl.gov/education/parent/Ag_iso.htm —Preceding unsigned comment added by 132.68.74.88 (talk) 19:26, 7 March 2010 (UTC)
If in a review of the interrelationship between the reported halflives of the various isotopes in this section it is noticed that the halflife of all of the isotopes of OOAg47 114 are ridiculously low with respect to the stability trend line of the adjacent associated OOAg isotopes, is it then in order to report this in this section and hope that somebody with status will ever get around to finding out what is the data problem in this situation?.WFPM (talk) 09:16, 23 September 2011 (UTC) This fact can be determined by comparing the halflife of the isotope OO47Ag114 with that of the rest of the OO isotopes coming down in mass value from the maximum OO halflife value (438years) @ OO47Ag 108 through OO47Ag114 @4.6 seconds and then back up to OO47Ag116 @ 2.68 minutes. A halflife versus atomic mass chart of these values shows the data much better.WFPM (talk) 23:54, 26 October 2011 (UTC)
47Ag silver is the 9th of the 2 + 4 + 4 = 10 element second transition metal series. It has 2 stable isotopes which are OE47Ag107 with 47 deuterons plus 13 extra neutrons (48%) and OE47Ag109 with 47 deuterons and 15 extra neutrons (52%). The element is the 9th in the second transition metal series. The stability trend lines associated with these 2 stable isotopes have the formula A = 3Z - 34 for OE47Ag107 and A=3Z-32 for OE47Ag109. The dominant A=3Z-32 trendline runs from EE42Mn94 through OE57La139, a total of 16 elements. Note that the isotope OE43Tc97 lies on this stability line