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Isotopes of technetium

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Isotopes of technetium (43Tc)
Main isotopes[1] Decay
abun­dance half-life (t1/2) mode pro­duct
95mTc synth 61.96 d β+ 95Mo
IT 95Tc
96Tc synth 4.28 d β+ 96Mo
97Tc synth 4.21×106 y ε 97Mo
97mTc synth 91.1 d IT 97Tc
ε 97Mo
98Tc synth 4.2×106 y β 98Ru
99Tc trace 2.111×105 y β 99Ru
99mTc synth 6.01 h IT 99Tc
β 99Ru

Technetium (43Tc) is one of the two elements with Z < 83 that have no stable isotopes; the other such element is promethium.[2] It is primarily artificial, with only trace quantities existing in nature produced by spontaneous fission (there are an estimated 2.5×10−13 grams of 99Tc per gram of pitchblende)[3] or neutron capture by molybdenum. The first isotopes to be synthesized were 97Tc and 99Tc[disputeddiscuss] in 1936, the first artificial element to be produced. The most stable radioisotopes are 97Tc (half-life of 4.21 million years), 98Tc (half-life: 4.2 million years), and 99Tc (half-life: 211,100 years).[4][5]

Thirty-three other radioisotopes have been characterized with atomic masses ranging from 85Tc to 120Tc.[6] Most of these have half-lives that are less than an hour; the exceptions are 93Tc (half-life: 2.75 hours), 94Tc (half-life: 4.883 hours), 95Tc (half-life: 20 hours), and 96Tc (half-life: 4.28 days).[7]

Technetium also has numerous meta states. 97mTc is the most stable, with a half-life of 91.0 days (0.097 MeV).[4] This is followed by 95mTc (half-life: 61 days, 0.038 MeV) and 99mTc (half-life: 6.04 hours, 0.143 MeV). 99mTc only emits gamma rays, subsequently decaying to 99Tc.[7]

For isotopes lighter than 98Tc, the primary decay mode is electron capture to isotopes of molybdenum. For the heavier isotopes, the primary mode is beta emission to isotopes of ruthenium, with the exception that 100Tc can decay both by beta emission and electron capture.[7][8]

Technetium-99m is the hallmark technetium isotope employed in the nuclear medicine industry. Its low-energy isomeric transition, which yields a gamma-ray at ~140.5 keV, is ideal for imaging using Single Photon Emission Computed Tomography (SPECT). Several technetium isotopes, such as 94mTc, 95Tc, and 96Tc, which are produced via (p,n) reactions using a cyclotron on molybdenum targets, have also been identified as potential Positron Emission Tomography (PET) or gamma-emitting agents for medical imaging.[9][10][11] Technetium-101 has been produced using a D-D fusion-based neutron generator from the 100Mo(n,γ)101Mo reaction on natural molybdenum and subsequent beta-minus decay of 101Mo to 101Tc. Despite its shorter half-life (i.e., 14.22 min), 101Tc exhibits unique decay characteristics suitable for radioisotope diagnostic or therapeutic procedures, where it has been proposed that its implementation, as a supplement for dual-isotopic imaging or replacement for 99mTc, could be performed by on-site production and dispensing at the point of patient care.[12]

Technetium-99 is the most common and most readily available isotope, as it is a major fission product from fission of actinides like uranium and plutonium with a fission product yield of 6% or more, and in fact the most significant long-lived fission product. Lighter isotopes of technetium are almost never produced in fission because the initial fission products normally have a higher neutron/proton ratio than is stable for their mass range, and therefore undergo beta decay until reaching the ultimate product. Beta decay of fission products of mass 95–98 stops at the stable isotopes of molybdenum of those masses and does not reach technetium. For mass 100 and greater, the technetium isotopes of those masses are very short-lived and quickly beta decay to isotopes of ruthenium. Therefore, the technetium in spent nuclear fuel is practically all 99Tc. In the presence of fast neutrons a small amount of 98
Tc
will be produced by (n,2n) "knockout" reactions. If nuclear transmutation of fission-derived Technetium or Technetium waste from medical applications is desired, fast neutrons are therefore not desirable as the long lived 98
Tc
increases rather than reducing the longevity of the radioactivity in the material.

One gram of 99Tc produces 6.2×108 disintegrations a second (that is, 0.62 GBq/g).[13]

Technetium has no primordial isotopes and does not occur in nature in significant quantities, and thus a standard atomic weight cannot be given.

List of isotopes

[edit]


Nuclide
[n 1]
Z N Isotopic mass (Da)[14]
[n 2][n 3]
Half-life[1]
Decay
mode
[1]
[n 4]
Daughter
isotope

[n 5][n 6]
Spin and
parity[1]
[n 7][n 8]
Isotopic
abundance
Excitation energy[n 8]
86Tc 43 43 85.94464(32)# 55(7) ms β+ 86Mo (0+)
86mTc 1524(10) keV 1.10(12) μs IT 86Tc (6+)
87Tc 43 44 86.9380672(45) 2.14(17) s β+ 87Mo 9/2+#
β+, p (<0.7%) 86Nb
87mTc 71(1) keV 647(24) ns IT 87Tc 7/2+#
88Tc 43 45 87.9337942(44) 6.4(8) s β+ 88Mo (2+)
88m1Tc 70(3) keV 5.8(2) s β+ 88Mo (6+)
88m2Tc 95(1) keV 146(12) ns IT 88Tc (4+)
89Tc 43 46 88.9276486(41) 12.8(9) s β+ 89Mo (9/2+)
89mTc 62.6(5) keV 12.9(8) s β+ 89Mo (1/2−)
90Tc 43 47 89.9240739(11) 49.2(4) s β+ 90Mo (8+)
90mTc 144.0(17) keV 8.7(2) s β+ 90Mo 1+
91Tc 43 48 90.9184250(25) 3.14(2) min β+ 91Mo (9/2)+
91mTc 139.3(3) keV 3.3(1) min β+ (99%) 91Mo (1/2)−
92Tc 43 49 91.9152698(33) 4.25(15) min β+ 92Mo (8)+
92m1Tc 270.09(8) keV 1.03(6) μs IT 92Tc (4+)
92m2Tc 529.42(13) keV <0.1 μs IT 92Tc (3+)
92m3Tc 711.33(15) keV <0.1 μs IT 92Tc 1+
93Tc 43 50 92.9102451(11) 2.75(5) h β+ 93Mo 9/2+
93m1Tc 391.84(8) keV 43.5(10) min IT (77.4%) 93Tc 1/2−
β+ (22.6%) 93Mo
93m2Tc 2185.16(15) keV 10.2(3) μs IT 93Tc (17/2)−
94Tc 43 51 93.9096523(44) 293(1) min β+ 94Mo 7+
94mTc 76(3) keV 52(1) min β+ (>99.82%) 94Mo (2)+
IT (<0.18%) 94Tc
95Tc 43 52 94.9076523(55) 19.258(26) h β+ 95Mo 9/2+
95mTc 38.91(4) keV 61.96(24) d β+ (96.1%) 95Mo 1/2−
IT (3.9%) 95Tc
96Tc 43 53 95.9078667(55) 4.28(7) d β+ 96Mo 7+
96mTc 34.23(4) keV 51.5(10) min IT (98.0%) 96Tc 4+
β+ (2.0%) 96Mo
97Tc 43 54 96.9063607(44) 4.21(16)×106 y EC 97Mo 9/2+
97mTc 96.57(6) keV 91.1(6) d IT (96.06%) 97Tc 1/2−
EC (3.94%) 97Mo
98Tc 43 55 97.9072112(36) 4.2(3)×106 y β 98Ru 6+
98mTc 90.77(16) keV 14.7(5) μs IT 98Tc (2,3)−
99Tc[n 9] 43 56 98.90624968(97) 2.111(12)×105 y β 99Ru 9/2+ trace
99mTc[n 10] 142.6836(11) keV 6.0066(2) h IT 99Tc 1/2−
β (0.0037%) 99Ru
100Tc 43 57 99.9076527(15) 15.46(19) s β 100Ru 1+
EC (0.0018%) 100Mo
100m1Tc 200.67(4) keV 8.32(14) μs IT 100Tc (4)+
100m2Tc 243.95(4) keV 3.2(2) μs IT 100Tc (6)+
101Tc 43 58 100.907305(26) 14.22(1) min β 101Ru 9/2+
101mTc 207.526(20) keV 636(8) μs IT 101Tc 1/2−
102Tc 43 59 101.9092072(98) 5.28(15) s β 102Ru 1+
102mTc[n 11] 50(50)# keV 4.35(7) min β 102Ru (4+)
103Tc 43 60 102.909174(11) 54.2(8) s β 103Ru 5/2+
104Tc 43 61 103.911434(27) 18.3(3) min β 104Ru (3−)
104m1Tc 69.7(2) keV 3.5(3) μs IT 104Tc (5−)
104m2Tc 106.1(3) keV 400(20) ns IT 104Tc 4#
105Tc 43 62 104.911662(38) 7.64(6) min β 105Ru (3/2−)
106Tc 43 63 105.914357(13) 35.6(6) s β 106Ru (1,2)(+#)
107Tc 43 64 106.9154584(93) 21.2(2) s β 107Ru (3/2−)
107m1Tc 30.1(1) keV 3.85(5) μs IT 107Tc (1/2+)
107m2Tc 65.72(14) keV 184(3) ns IT 107Tc (5/2+)
108Tc 43 65 107.9184935(94) 5.17(7) s β 108Ru (2)+
109Tc 43 66 108.920254(10) 905(21) ms β (99.92%) 109Ru (5/2+)
β, n (0.08%) 108Ru
110Tc 43 67 109.923741(10) 900(13) ms β (99.96%) 110Ru (2+,3+)
β, n (0.04%) 109Ru
111Tc 43 68 110.925899(11) 350(11) ms β (99.15%) 111Ru 5/2+#
β, n (0.85%) 110Ru
112Tc 43 69 111.9299417(59) 323(6) ms β (98.5%) 112Ru (2+)
β, n (1.5%) 111Ru
112mTc 352.3(7) keV 150(17) ns IT 112Tc
113Tc 43 70 112.9325690(36) 152(8) ms β (97.9%) 113Ru 5/2+#
β, n (2.1%) 113Ru
113mTc 114.4(5) keV 527(16) ns IT 113Tc 5/2−#
114Tc 43 71 113.93709(47) 121(9) ms β (98.7%) 114Ru 5+#
β, n (1.3%) 113Ru
114mTc[n 11] 160(430) keV 90(20) ms β (98.7%) 114Ru 1+#
β, n (1.3%) 113Ru
115Tc 43 72 114.94010(21)# 78(2) ms β 115Ru 5/2+#
116Tc 43 73 115.94502(32)# 57(3) ms β 116Ru 2+#
117Tc 43 74 116.94832(43)# 44.5(30) ms β 117Ru 5/2+#
118Tc 43 75 117.95353(43)# 30(4) ms β 118Ru 2+#
119Tc 43 76 118.95688(54)# 22(3) ms β 119Ru 5/2+#
120Tc 43 77 119.96243(54)# 21(5) ms β 120Ru 3+#
121Tc 43 78 120.96614(54)# 22(6) ms β 121Ru 5/2+#
122Tc 43 79 121.97176(32)# 13# ms
[>550 ns]
1+#
This table header & footer:
  1. ^ mTc – Excited nuclear isomer.
  2. ^ ( ) – Uncertainty (1σ) is given in concise form in parentheses after the corresponding last digits.
  3. ^ # – Atomic mass marked #: value and uncertainty derived not from purely experimental data, but at least partly from trends from the Mass Surface (TMS).
  4. ^ Modes of decay:
    EC: Electron capture
    IT: Isomeric transition
    n: Neutron emission
    p: Proton emission
  5. ^ Bold italics symbol as daughter – Daughter product is nearly stable.
  6. ^ Bold symbol as daughter – Daughter product is stable.
  7. ^ ( ) spin value – Indicates spin with weak assignment arguments.
  8. ^ a b # – Values marked # are not purely derived from experimental data, but at least partly from trends of neighboring nuclides (TNN).
  9. ^ Long-lived fission product
  10. ^ Used in medicine
  11. ^ a b Order of ground state and isomer is uncertain.

Stability of technetium isotopes

[edit]

Technetium and promethium are unusual light elements in that they have no stable isotopes. Using the liquid drop model for atomic nuclei, one can derive a semiempirical formula for the binding energy of a nucleus. This formula predicts a "valley of beta stability" along which nuclides do not undergo beta decay. Nuclides that lie "up the walls" of the valley tend to decay by beta decay towards the center (by emitting an electron, emitting a positron, or capturing an electron). For a fixed number of nucleons A, the binding energies lie on one or more parabolas, with the most stable nuclide at the bottom. One can have more than one parabola because isotopes with an even number of protons and an even number of neutrons are more stable than isotopes with an odd number of neutrons and an odd number of protons. A single beta decay then transforms one into the other. When there is only one parabola, there can be only one stable isotope lying on that parabola. When there are two parabolas, that is, when the number of nucleons is even, it can happen (rarely) that there is a stable nucleus with an odd number of neutrons and an odd number of protons (although this happens only in five instances: 2H, 6Li, 10B, 14N and 180mTa). However, if this happens, there can be no stable isotope with an even number of neutrons and an even number of protons.

For technetium (Z = 43), the valley of beta stability is centered at around 98 nucleons. However, for every number of nucleons from 94 to 102, there is already at least one stable nuclide of either molybdenum (Z = 42) or ruthenium (Z = 44), and the Mattauch isobar rule states that two adjacent isobars cannot both be stable.[15] For the isotopes with odd numbers of nucleons, this immediately rules out a stable isotope of technetium, since there can be only one stable nuclide with a fixed odd number of nucleons. For the isotopes with an even number of nucleons, since technetium has an odd number of protons, any isotope must also have an odd number of neutrons. In such a case, the presence of a stable nuclide having the same number of nucleons and an even number of protons rules out the possibility of a stable nucleus.[15][16]

References

[edit]
  1. ^ a b c d Kondev, F. G.; Wang, M.; Huang, W. J.; Naimi, S.; Audi, G. (2021). "The NUBASE2020 evaluation of nuclear properties" (PDF). Chinese Physics C. 45 (3): 030001. doi:10.1088/1674-1137/abddae.
  2. ^ "Atomic weights of the elements 2011 (IUPAC Technical Report)" (PDF). IUPAC. p. 1059(13). Retrieved August 11, 2014. – Elements marked with a * have no stable isotope: 43, 61, and 83 and up.
  3. ^ Icenhower, J.P.; Martin, W.J.; Qafoku, N.P.; Zachara, J.M. (2008). The Geochemistry of Technetium: A Summary of the Behavior of an Artificial Element in the Natural Environment (Report). Pacific Northwest National Laboratory: U.S. Department of Energy. p. 2.1.
  4. ^ a b "Livechart - Table of Nuclides - Nuclear structure and decay data". www-nds.iaea.org. Retrieved 2017-11-18.
  5. ^ "Nubase 2016". NDS IAEA. 2017. Retrieved 18 November 2017.
  6. ^ National Nuclear Data Center. "NuDat 2.x database". Brookhaven National Laboratory.
  7. ^ a b c "Technetium". EnvironmentalChemistry.com.
  8. ^ Holden, Norman E. (2004). "11. Table of the Isotopes". In Lide, David R. (ed.). CRC Handbook of Chemistry and Physics (85th ed.). Boca Raton, Florida: CRC Press. ISBN 978-0-8493-0485-9.
  9. ^ Bigott, H. M.; Mccarthy, D. W.; Wüst, F. R.; Dahlheimer, J. L.; Piwnica-Worms, D. R.; Welch, M. J. (2001). "Production, processing and uses of 94mTc". Journal of Labelled Compounds and Radiopharmaceuticals. 44 (S1): S119–S121. doi:10.1002/jlcr.2580440141. ISSN 1099-1344.
  10. ^ Morley, Thomas; Benard, Francois; Schaffer, Paul; Buckley, Kenneth; Hoehr, Cornelia; Gagnon, Katherine; McQuarrie, Steve; Kovacs, Michael; Ruth, Thomas (2011-05-01). "Simple, rapid production of Tc-94m". Journal of Nuclear Medicine. 52 (supplement 1): 290. ISSN 0161-5505.
  11. ^ Hayakawa, Takehito; Hatsukawa, Yuichi; Tanimori, Toru (January 2018). "95g Tc and 96g Tc as alternatives to medical radioisotope 99m Tc". Heliyon. 4 (1): e00497. Bibcode:2018Heliy...400497H. doi:10.1016/j.heliyon.2017.e00497. ISSN 2405-8440. PMC 5766687. PMID 29349358.
  12. ^ Mausolf, Edward J.; Johnstone, Erik V.; Mayordomo, Natalia; Williams, David L.; Guan, Eugene Yao Z.; Gary, Charles K. (September 2021). "Fusion-Based Neutron Generator Production of Tc-99m and Tc-101: A Prospective Avenue to Technetium Theranostics". Pharmaceuticals. 14 (9): 875. doi:10.3390/ph14090875. PMC 8467155. PMID 34577575.
  13. ^ The Encyclopedia of the Chemical Elements, p. 693, "Toxicology", paragraph 2
  14. ^ Wang, Meng; Huang, W.J.; Kondev, F.G.; Audi, G.; Naimi, S. (2021). "The AME 2020 atomic mass evaluation (II). Tables, graphs and references*". Chinese Physics C. 45 (3): 030003. doi:10.1088/1674-1137/abddaf.
  15. ^ a b Johnstone, E.V.; Yates, M.A.; Poineau, F.; Sattelberger, A.P.; Czerwinski, K.R. (2017). "Technetium, the first radioelement on the periodic table". Journal of Chemical Education. 94 (3): 320–326. Bibcode:2017JChEd..94..320J. doi:10.1021/acs.jchemed.6b00343. OSTI 1368098.
  16. ^ Radiochemistry and Nuclear Chemistry