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Americium-241

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Americium-241, 241Am
Small button containing 241AmO2 from a smoke alarm
General
Symbol241Am
Namesamericium-241, 241Am, Am-241
Protons (Z)95
Neutrons (N)146
Nuclide data
Natural abundance0 (synthetic)
Half-life (t1/2)432.6±0.6 years[1]
Isotope mass241.0568273(12)[1] Da
Spin5/2−
Excess energy52934.3±1.1[1] keV
Binding energy7543.2795(46)[1] keV
Parent isotopes241Pu (β)
241Cm (EC)
245Bk (α)
Decay products237Np
Decay modes
Decay modeDecay energy (MeV)
α-decay (alpha)5.486
γ-emission (gamma)0.0595409
CD (cluster decay)93.923
Isotopes of americium
Complete table of nuclides

Americium-241 (241Am, Am-241) is an isotope of americium. Like all isotopes of americium, it is radioactive, with a half-life of 432.2 years. 241Am is the most common isotope of americium as well as the most prevalent isotope of americium in nuclear waste. It is commonly found in ionization type smoke detectors and is a potential fuel for long-lifetime radioisotope thermoelectric generators (RTGs). Its common parent nuclides are β from 241Pu, EC from 241Cm, and α from 245Bk. 241Am is not fissile, but is fissionable, and the critical mass of a bare sphere is 57.6–75.6 kilograms (127.0–166.7 lb) and a sphere diameter of 19–21 centimetres (7.5–8.3 in).[2] Americium-241 has a specific activity of 3.43 Ci/g (126.91 GBq/g).[3] It is commonly found in the form of americium-241 dioxide (241AmO2). This isotope also has one meta state, 241mAm, with an excitation energy of 2.2 MeV (0.35 pJ) and a half-life of 1.23 μs. The presence of 241Am 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 241Pu contain a buildup of 241Am. Chemical removal of americium-241 from reworked plutonium (e.g., during reworking of plutonium pits) may be required in some cases.

Nucleosynthesis

[edit]

Americium-241 has been produced in small quantities in nuclear reactors for decades, and many kilograms of 241Am have been accumulated by now.[4]: 1262  Nevertheless, since it was first offered for sale in 1962, its price, about US$1,500 per gram of 241Am, remains almost unchanged owing to the very complex separation procedure.[5]

Americium-241 is not synthesized directly from uranium – the most common reactor material – but from plutonium-239 (239Pu). The latter needs to be produced first, according to the following nuclear process:

The capture of two neutrons by 239Pu (a so-called (n,γ) reaction), followed by a β-decay, results in 241Am:

The plutonium present in spent nuclear fuel contains about 12% of 241Pu. Because it converts to 241Am, 241Pu can be extracted and may be used to generate further 241Am.[5] However, this process is rather slow: half of the original amount of 241Pu decays to 241Am after about 14 years, and the 241Am amount reaches a maximum after 70 years.[6]

The obtained 241Am can be used for generating heavier americium isotopes by further neutron capture inside a nuclear reactor. In a light water reactor (LWR), 79% of neutron captures on 241Am convert to 242Am and 10% to its nuclear isomer 242mAm:[7]

79%:  

Decay

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Americium-241 decays mainly via alpha decay, with a weak gamma ray byproduct. The α-decay is shown as follows:

The α-decay energies are 5.486 MeV (0.8790 pJ) for 85% of the time (the one which is widely accepted for standard α-decay energy), 5.443 MeV (0.8721 pJ) for 13% of the time, and 5.388 MeV (0.8633 pJ) for the remaining 2%.[8] The γ-ray energy is 59.5409 keV (9.53950 fJ) for the most part, with little amounts of other energies such as 13.9 keV (2.23 fJ), 17.8 keV (2.85 fJ) and 26.4 keV (4.23 fJ).[9]

The second most common type of decay that americium-241 undergoes is spontaneous fission, with a branching ratio of 3.6×10−12[10] and happening 1.2 times a second per gram of 241Am. It is written as such (the asterisk denotes an excited nucleus):

The least common (rarest) type of decay for americium-241 is 34
Si
cluster decay, with a branching ratio of less than 7.4×10−16.[10] It is written as follows:

Applications

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Ionization-type smoke detector

[edit]

Americium-241 is the only synthetic isotope to have found its way into the household, where the most common type of smoke detector (the ionization-type) uses 241
Am
O
2
(americium-241 dioxide) as its source of ionizing radiation.[11] This isotope is preferred over 226
Ra
because it emits 5 times more alpha particles and relatively little harmful gamma radiation. With its half-life of 432.2 years, the americium in a smoke detector decreases and includes about 3% neptunium after 19 years, and about 5% after 32 years. The amount of americium in a typical new smoke detector is 0.29 micrograms (4.5×10−6 grains) (about 1/3000 the weight of a small grain of sand) with an activity of 1 microcurie (37 kBq). Some old industrial smoke detectors (notably from the Pyrotronics Corporation) can contain up to 80 microcuries (3,000 kBq). The amount of 241Am declines slowly as it decays into neptunium-237 (237Np), a different transuranic element with a much longer half-life (about 2.14 million years). The radiated alpha particles pass through an ionization chamber, an air-filled space between two electrodes, which allows a small, constant electric current to pass between the capacitor plates due to the radiation ionizing the air space between. Any smoke that enters the chamber blocks/absorbs some of the alpha particles from freely passing through and reduces the ionization and therefore causes a drop in the current. The alarm's circuitry detects this drop in the current and as a result, triggers the piezoelectric buzzer to sound. Compared to the alternative optical smoke detector, the ionization smoke detector is cheaper and can detect particles which are too small to produce significant light scattering. However, it is more prone to false alarms.[12][13][14][15]

Manufacturing process

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The process for making the americium used in the buttons on ionization-type smoke detectors begins with americium dioxide. The 241AmO2 is thoroughly mixed with gold, shaped into a briquette, and fused by pressure and heat at over 1,470 °F (800 °C). A backing of silver and a front covering of gold (or an alloy of gold or palladium) are applied to the briquette and sealed by hot forging. The briquette is then processed through several stages of cold rolling to achieve the desired thickness and levels of radiation emission. The final thickness is about 0.008 inches (0.20 mm), with the gold cover representing about one percent of the thickness. The resulting foil strip, which is about 0.8 inches (20 mm) wide, is cut into sections 39 inches (1 m) long. The sources are punched out of the foil strip. Each disc, about 0.2 inches (5.1 mm) in diameter, is mounted in a metal holder, usually made of aluminium. The holder is the housing, which is the majority of what is seen on the button. The thin rim on the holder is rolled over to completely seal the cut edge around the disc.[16]

RTG (radioisotope thermoelectric generator) power generation

[edit]

As 241Am has a roughly similar half-life to 238Pu (432.2 years vs. 87 years), it has been proposed as an active isotope of radioisotope thermoelectric generators, for use in spacecraft.[17] Even though americium-241 produces less heat and electricity than plutonium-238 (the power yield is 114.7 milliwatts per gram [3.25 watts per ounce] for 241Am vs. 570 mW/g [16 W/oz] for 238Pu)[17] and its radiation poses a greater threat to humans owing to gamma and neutron emission, it has advantages for long duration missions with its significantly longer half-life. The European Space Agency is working on RTGs based on americium-241 for its space probes[18] as a result of the global shortage of plutonium-238 and easy access to americium-241 in Europe from nuclear waste reprocessing.[19][20]

Its shielding requirements in an RTG are the second lowest of all possible isotopes: only 238Pu requires less. An advantage over 238Pu is that it is produced as nuclear waste and is nearly isotopically pure. Prototype designs of 241Am RTGs expect 2–2.2 We/kg for 5–50 We RTGs design, putting 241Am RTGs at parity with 238Pu RTGs within that power range, as the vast majority of the mass of an RTG is not the isotopes, but the thermoelectrics, radiators, and isotope containment mass.[21]

Neutron source

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Oxides of 241Am pressed with beryllium can be very efficient neutron sources, since they emit alpha particles during radioactive decay:

Here americium acts as the alpha source, and beryllium produces neutrons owing to its large cross-section for the (α,n) nuclear reaction:

The most widespread use of 241
Am
Be
neutron sources is a neutron probe – a device used to measure the quantity of water present in soil, as well as moisture/density for quality control in highway construction. 241Am neutron sources are also used in well logging applications, as well as in neutron radiography, tomography, and other radiochemical investigations.[22]

Production of other elements

[edit]
Chart displaying actinides and their decays and transmutations.

Americium-241 is sometimes used as a starting material for the production of other transuranic elements and transactinides – for example, neutron bombardment of 241Am yields 242Am:

From there, 82.7% of 242Am decays to 242Cm and 17.3% to 242Pu:

82.7%

17.3%

In the nuclear reactor, 242Am is also up-converted by neutron capture to 243Am and 244Am, which transforms by β-decay to 244Cm:

Irradiation of 241Am by 12C or 22Ne ions yields einsteinium-253 (253Es) or dubnium-263 (263Db), respectively.[23] Furthermore, the element berkelium (243Bk isotope) had been first intentionally produced and identified by bombarding 241Am with alpha particles, in 1949, by the same Berkeley group, using the same 60-inch (1,500 mm) cyclotron that had been used for many previous experiments.[4]: 1262 

Spectrometer

[edit]

Americium-241 has been used as a portable source of both gamma rays and alpha particles for a number of medical and industrial uses. The 59.5409 keV (9.53950 fJ) gamma ray emissions from 241Am in such sources can be used for indirect analysis of materials in radiography and X-ray fluorescence spectroscopy, as well as for quality control in fixed nuclear density gauges and nuclear densometers. For example, this isotope has been employed to gauge glass thickness to help create flat glass.[4]: 1262  Americium-241 is also suitable for calibration of gamma-ray spectrometers in the low-energy range, since its spectrum consists of nearly a single peak and negligible Compton continuum (at least three orders of magnitude lower intensity).[24]

Medicine

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Gamma rays from americium-241 have been used to provide passive diagnosis of thyroid function. This medical application is now obsolete. Americium-241's gamma rays can provide reasonable quality radiographs, with a 10-minute exposure time. 241Am radiographs have only been taken experimentally due to the long exposure time which increases the effective dose to living tissue. Reducing exposure duration reduces the chance of ionization events causing damage to cells and DNA, and is a critical component in the "time, distance, shielding" maxim used in radiation protection.[25]

Hazards

[edit]

Americium-241 has the same general hazards as other americium isotopes: it is both extremely toxic and radioactive. Though α-particles can be stopped by a sheet of paper, there are serious health concerns for ingestion of α-emitters. Americium and its isotopes are also very chemically toxic as well, in the form of heavy-metal toxicity. As little as 0.03 microcuries (1.1 kBq) is the maximum permissible body burden for 241Am.[26]

Americium-241 is an α-emitter with a weak γ-ray byproduct. Safely handling americium-241 requires knowing and following proper safety precautions, as without them it would be extremely dangerous. Its specific gamma dose constant is 3.14×10−1 mR/hr/mCi or 8.48×10−5 mSv/hr/MBq at 1 metre (3 ft 3 in).[27]

If consumed, americium-241 is excreted within a few days and only 0.05% is absorbed in the blood. From there, roughly 45% of it goes to the liver and 45% to the bones, and the remaining 10% is excreted. The uptake to the liver depends on the individual and increases with age. In the bones, americium is first deposited over cortical and trabecular surfaces and slowly redistributes over the bone with time. The biological half-life of 241Am is 50 years in the bones and 20 years in the liver, whereas in the gonads (testicles and ovaries) it remains permanently; in all these organs, americium promotes formation of cancer cells as a result of its radioactivity.[28]

A container of Americium-241 in a smoke detector

Americium-241 often enters landfills from discarded smoke detectors. The rules associated with the disposal of smoke detectors are relaxed in most jurisdictions. In the U.S., the "Radioactive Boy Scout" David Hahn was able to concentrate americium-241 from smoke detectors after managing to buy a hundred of them at remainder prices and also stealing a few.[29][30][31][32] There have been a few cases of exposure to americium-241, the worst being Harold McCluskey who, at age 64, was exposed to 500 times the occupational standard for americium-241 as a result of an explosion in his lab. McCluskey died at age 75, not as a result of exposure, but of a heart disease which he had before the accident.[33][34] Americium-241 has also been detected in the oceans as a result of nuclear testing conducted by various nations.[35]

See also

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References

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  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. ^ Dias, Hemanth; Tancock, Nigel; Clayton, Angela (20 October 2003). Critical mass calculations for 241Am, 242mAm and 243Am. Proceedings of the seventh international conference on nuclear criticality safety. Japan Atomic Energy Research Institute. CiteSeerX 10.1.1.540.1085 – via International Atomic Energy Agency (IAEA).
  3. ^ "Americium: Chemical, physical, and radiological information" (PDF). Agency for Toxic Substances and Disease Registry (CDC). pp. 103–111. Retrieved 24 July 2019.
  4. ^ a b c Greenwood, Norman N.; Earnshaw, Alan (1997). Chemistry of the Elements (2nd ed.). Pergamon Press. ISBN 978-0-7506-3365-9. LCCN 97036336. OCLC 1005231772. OL 689297M.
  5. ^ a b "Smoke detectors and americium". World Nuclear Association. January 2009. Archived from the original on 24 December 2008. Retrieved 2 September 2022.
  6. ^ "PLUTONIUM: THE LAST FIVE YEARS | Part I: The Trouble With Plutonium | A Review of Plutonium Destructiveness, Complexity, and Hazards". Blue Ridge Environmental Defense League. Archived from the original on 28 July 2022. Retrieved 2 September 2022.
  7. ^ Sasahara, Akihiro; Matsumura, Tetsuo; Nicolaou, Giorgos; Papaioannou, Dimitri (7 February 2012) [11 December 2003]. "Neutron and Gamma Ray Source Evaluation of LWR High Burn-up UO
    2
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  8. ^ "AMERICIUM-241".
  9. ^ "GAMMA RAY SPECTRUM OF AM-241 IN A BACK SCATTERING GEOMETRY USING A HIGH PURITY GERMANIUM DETECTOR" (PDF).
  10. ^ a b Audi, G.; Kondev, F. G.; Wang, M.; Huang, W. J.; Naimi, S. (2017). "The NUBASE2016 evaluation of nuclear properties" (PDF). Chinese Physics C. 41 (3): 030001. Bibcode:2017ChPhC..41c0001A. doi:10.1088/1674-1137/41/3/030001.
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  13. ^ Bukowski, Richard W.; Peacock, Richard D.; Averill, Jason D.; Cleary, Thomas G.; Bryner, Nelson P.; et al. (1 December 2007). Home Smoke Alarms Analysis of the Response of Several Available Technologies in Residential Fire Settings (Technical report). NIST TN 1455-1. Archived from the original on 8 March 2022. Retrieved 2 September 2022.Public Domain This article incorporates public domain material from the National Institute of Standards and Technology
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  15. ^ Agency for Toxic Substances and Disease Registry (April 2004). Toxicological Profile For Americium (PDF) (Report). Atlanta, GA: United States Department of Health and Human Services. CAS#: 7440-35-9. Archived (PDF) from the original on 27 July 2022. Retrieved 2 September 2022.Public Domain This article incorporates public domain material from websites or documents of the United States Department of Health and Human Services.
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  18. ^ Chahal, Major S. (8 February 2012). "European Space Nuclear Power Programme: UK Activities" (PDF). UK Space Agency. Archived (PDF) from the original on 16 May 2012. Retrieved 1 September 2022 – via United Nations Office for Outer Space Affairs.
  19. ^ Clark, Stephen (9 July 2010). "Space agencies tackle waning plutonium stockpiles". Spaceflight Now. Archived from the original on 28 July 2022. Retrieved 2 September 2022. ESA's nuclear program would likely focus on americium, according to Southwood. [...] Americium-241 has a longer half-life than plutonium-238, meaning it could survive longer in space, but the isotope produces less heat and electricity. Americium is also a greater radiation hazard to humans, according to scientists.
  20. ^ Greenfieldboyce, Nell (28 September 2009). "Plutonium Shortage Could Stall Space Exploration". NPR. Archived from the original on 12 August 2022. Retrieved 2 September 2022. NASA is running out of the special kind of plutonium needed to power deep space probes, worrying planetary scientists who say the U. S. urgently needs to restart production of plutonium-238.
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  30. ^ "'Radioactive Boy Scout' Charged in Smoke Detector Theft". Fox News. 4 August 2007. Archived from the original on 8 December 2007. Retrieved 28 November 2007.
  31. ^ "Man dubbed 'Radioactive Boy Scout' pleads guilty". Detroit Free Press. Associated Press. 27 August 2007. Archived from the original on 29 September 2007. Retrieved 27 August 2007.
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  33. ^ Cary, Annette (25 April 2008). "Doctor remembers Hanford's 'Atomic Man'". Tri-City Herald. Archived from the original on 10 February 2010. Retrieved 17 June 2008.
  34. ^ "Hanford nuclear workers enter site of worst contamination accident". Billings Gazette. Associated Press. 3 June 2005. Archived from the original on 13 October 2007. Retrieved 17 June 2007.
  35. ^ Rozmaric, M.; Chamizo, E.; Louw, D. C.; López-Lora, M.; Blinova, O.; Levy, I.; Mudumbi, B.; van der Plas, A. K.; Garcia Tenorio, R.; McGinnity, P.; Osvath, I. (1 January 2022). "Fate of anthropogenic radionuclides (90Sr, 137Cs, 238Pu, 239Pu, 240Pu, 241Am) in seawater in the northern Benguela upwelling system off Namibia". Chemosphere. 286 (Pt 1): 131514. Bibcode:2022Chmsp.28631514R. doi:10.1016/j.chemosphere.2021.131514. ISSN 0045-6535. PMID 34311394. Retrieved 1 January 2024 – via Elsevier Science Direct.