Isotopes of americium

Actinides Half-life Fission products
244Cm 241Pu f 250Cf 243Cmf 10–30 y 137Cs 90Sr 85Kr
232 f 238Pu f is for
fissile
69–90 y 151Sm nc➔
4n 249Cf  f 242Amf 141–351 No fission product
has half-life 102
to 2×105 years
241Am 251Cf  f 431–898
240Pu 229Th 246Cm 243Am 5–7 ky
4n 245Cmf 250Cm 239Pu f 8–24 ky
233U    f 230Th 231Pa 32–160
4n+1 234U 4n+3 211–290 99Tc 126Sn 79Se
248Cm 242Pu 340–373 Long-lived fission products
237Np 4n+2 1–2 My 93Zr 135Cs nc➔
236U 4n+1 247Cmf 6–23 My 107Pd 129I
244Pu 80 My >7% >5% >1% >.1%
232Th 238U 235U    f 0.7–12 Gy fission product yield

Americium (Am) is an artificial element, and thus a standard atomic mass cannot be given. Like all artificial elements, it has no stable isotopes. The first isotope to be synthesized was 241Am in 1944.

19 radioisotopes of americium have been characterized, with the most stable being 243Am with a half-life of 7,370 years, and 241Am with a half-life of 432.7 years. All of the remaining radioactive isotopes have half-lives that are less than 51 hours, and the majority of these have half-lives that are less than 100 minutes. This element also has 8 meta states, with the most stable being 242mAm (t½ 141 years). The isotopes of americium range in atomic weight from 231.046 u (231Am) to 249.078 u (249Am).

Contents

Some notable isotopes

Americium-241

Americium-241 is the most prevalent isotope of americium in nuclear waste.[1] It is the americium isotope used in an americium smoke detector based an ionization chamber. It is a potential fuel for long-lifetime radioisotope thermoelectric generators.

Parameter Value
Atomic mass 241.056823 u
Mass excess 52930 keV
Beta decay energy -767 keV
Spin 5/2-
Half-life 432.2 years
Spontaneous fissions 1200 per kg/s
Decay heat 114 watts/kg

Possible parent nuclides: beta from 241Pu, electron capture from 241Cm, alpha from 245Bk.

Americium-241 decays by alpha emission, with a by-product of gamma rays. Its presence in plutonium is determined by the original concentration of plutonium-241 and the sample age. Because of the low penetration of alpha radiation, Americium-241 only poses a health risk when ingested or inhaled. Older samples of plutonium containing plutonium-241 contain a buildup of 241Am. A chemical removal of americium from reworked plutonium, e.g. during reworking of plutonium pits, may be required.

Americium-242m

242mAm decay modes (halflife: 141 years)
Probability Decay mode Decay energy Decay product
99.54% isomeric transition 0.05 MeV 242Am
0.46% alpha decay 5.64 MeV 238Np
(1.5±0.6)×10−10[3] spontaneous fission ~200 MeV fission products

Americium-242m has a mass of 242.0595492 g/mol. It is one of the rare cases, like 180mTa, where a higher-energy nuclear isomer is more stable than the lower-energy one, Americium-242.[4]

242mAm is fissile (because it has an odd number of neutrons) and has a low critical mass, comparable to that of 239Pu.[5] It has a very high cross section for fission, and if in a nuclear reactor is destroyed relatively quickly. Another report claims that 242mAm has a much lower critical mass, can sustain a chain reaction even as a thin film, and could be used for a novel type of nuclear rocket.[6]

242Am decay modes (halflife: 16 hours)
Probability Decay mode Decay energy Decay product
82.70% beta decay 0.665 MeV 242Cm
17.30% electron capture 0.751 MeV 242Pu

Americium-243

Americium-243 has a mass of 243.06138 g/mol and a half-life of 7,370 years, the longest lasting of all americium isotopes. It is formed in the nuclear fuel cycle by neutron capture on plutonium-242 followed by beta decay.[7] Production increases exponentially with increasing burnup as a total of 5 neutron captures on 238U are required.

It decays by either emitting an alpha particle (with a decay energy of 5.27MeV)[7] to become 239Np, which then quickly decays to 239Pu, or infrequently, by spontaneous fission.[8]

243Am is a hazardous substance, because it can cause cancer. 239Np, which is formed from 243Am, emits dangerous gamma rays, making 243Am the most dangerous isotope of Americium.[1]

Table

nuclide
symbol
Z(p) N(n)  
isotopic mass (u)
 
half-life decay
mode(s)[9][n 1]
daughter
isotope(s)
nuclear
spin
excitation energy
231Am 95 136 231.04556(32)# 30# s β+ 231Pu
α (rare) 227Np
232Am 95 137 232.04659(32)# 79(2) s β+ (98%) 232Pu
α (2%) 228Np
β+, SF (.069%) (various)
233Am 95 138 233.04635(11)# 3.2(8) min β+ 233Pu
α 229Np
234Am 95 139 234.04781(22)# 2.32(8) min β+ (99.95%) 234Pu
α (.04%) 230Np
β+, SF (.0066%) (various)
235Am 95 140 235.04795(13)# 9.9(5) min β+ 235Pu 5/2-#
α (rare) 231Np
236Am 95 141 236.04958(11)# 3.6(1) min β+ 236Pu
α 232Np
237Am 95 142 237.05000(6)# 73.0(10) min β+ (99.97%) 237Pu 5/2(-)
α (.025%) 233Np
238Am 95 143 238.05198(5) 98(2) min β+ 238Pu 1+
α (10−4%) 234Np
238mAm 2500(200)# keV 35(10) µs
239Am 95 144 239.0530245(26) 11.9(1) h EC (99.99%) 236Pu (5/2)-
α (.01%) 235Np
239mAm 2500(200) keV 163(12) ns (7/2+)
240Am 95 145 240.055300(15) 50.8(3) h β+ 240Pu (3-)
α (1.9×10−4%) 236Np
241Am[n 2] 95 146 241.0568291(20) 432.2(7) a α 237Np 5/2-
CD (7.4×10−10%) 207Tl, 34Si
SF (4.3×10−10%) (various)
241mAm 2200(100) keV 1.2(3) µs
242Am 95 147 242.0595492(20) 16.02(2) h β- (82.7%) 242Cm 1-
EC (17.3%) 242Pu
242m1Am 48.60(5) keV 141(2) a IT (99.54%) 242Am 5-
α (.46%) 238Np
SF (1.5×10−8%) (various)
242m2Am 2200(80) keV 14.0(10) ms (2+,3-)
243Am[n 2] 95 148 243.0613811(25) 7,370(40) a α 239Np 5/2-
SF (3.7×10−9%) (various)
244Am 95 149 244.0642848(22) 10.1(1) h β- 244Cm (6-)#
244mAm 86.1(10) keV 26(1) min β- (99.96%) 244Cm 1+
EC (.0361%) 244Pu
245Am 95 150 245.066452(4) 2.05(1) h β- 245Cm (5/2)+
246Am 95 151 246.069775(20) 39(3) min β- 246Cm (7-)
246m1Am 30(10) keV 25.0(2) min β- (99.99%) 246Cm 2(-)
IT (.01%) 246Am
246m2Am ~2000 keV 73(10) µs
247Am 95 152 247.07209(11)# 23.0(13) min β- 247Cm (5/2)#
248Am 95 153 248.07575(22)# 3# min β- 248Cm
249Am 95 154 249.07848(32)# 1# min β- 249Cm
  1. ^ Abbreviations:
    CD: Cluster decay
    EC: Electron capture
    IT: Isomeric transition
    SF: Spontaneous fission
  2. ^ a b Most common isotopes

Notes

See also


References

  1. ^ a b "Americium". Argonne National Laboratory, EVS. Retrieved 25 December 2009.
  2. ^ Sasahara, Akihiro; Matsumura, Tetsuo; Nicolaou, Giorgos; Papaioannou, Dimitri (April 2004). "Neutron and Gamma Ray Source Evaluation of LWR High Burn-up UO2 and MOX Spent Fuels". Journal of NUCLEAR SCIENCE and TECHNOLOGY 41 (4): 448–456. doi:10.3327/jnst.41.448. http://www.jstage.jst.go.jp/article/jnst/41/4/448/_pdf. 
  3. ^ Phys. Rev. 155 (1967): J. T. Caldwell, S. C. Fultz, C. D. Bowman, and R. W. Hoff - Spontaneous Fission Half-Life of 242mAm (halflife (9.5±3.5)×1011
  4. ^ 95-Am-242
  5. ^ http://typhoon.jaea.go.jp/icnc2003/Proceeding/paper/6.5_022.pdf
  6. ^ Extremely Efficient Nuclear Fuel Could Take Man To Mars In Just Two Weeks
  7. ^ a b "Americium-243". Oak Ridge National Laboratory. Retrieved 25 December 2009.
  8. ^ "Isotopes of the Element Americium". Jefferson Lab Science Education. Retrieved 25 December 2009.
  9. ^ http://www.nucleonica.net/unc.aspx
Isotopes of plutonium Isotopes of americium Isotopes of curium
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