This article may be too technical for most readers to understand.(January 2014) |
Specific activity (symbol a) is the activity per unit mass of a radionuclide and is a physical property of that radionuclide.[1][2] It is usually given in units of becquerel per kilogram (Bq/kg), but another commonly used unit of specific activity is the curie per gram (Ci/g).
Activity | |
---|---|
Common symbols | A |
SI unit | becquerel |
Other units | rutherford, curie |
In SI base units | s−1 |
Specific activity | |
---|---|
Common symbols | a |
SI unit | becquerel per kilogram |
Other units | rutherford per gram, curie per gram |
In SI base units | s−1⋅kg−1 |
In the context of radioactivity, activity or total activity (symbol A) is a physical quantity defined as the number of radioactive transformations per second that occur in a particular radionuclide.[3] The unit of activity is the becquerel (symbol Bq), which is defined equivalent to reciprocal seconds (symbol s-1). The older, non-SI unit of activity is the curie (Ci), which is 3.7×1010 radioactive decays per second. Another unit of activity is the rutherford, which is defined as 1×106 radioactive decays per second.
The specific activity should not be confused with level of exposure to ionizing radiation and thus the exposure or absorbed dose, which is the quantity important in assessing the effects of ionizing radiation on humans.
Since the probability of radioactive decay for a given radionuclide within a set time interval is fixed (with some slight exceptions, see changing decay rates), the number of decays that occur in a given time of a given mass (and hence a specific number of atoms) of that radionuclide is also a fixed (ignoring statistical fluctuations).
Formulation
editRelationship between λ and T1/2
editRadioactivity is expressed as the decay rate of a particular radionuclide with decay constant λ and the number of atoms N:
The integral solution is described by exponential decay:
where N0 is the initial quantity of atoms at time t = 0.
Half-life T1/2 is defined as the length of time for half of a given quantity of radioactive atoms to undergo radioactive decay:
Taking the natural logarithm of both sides, the half-life is given by
Conversely, the decay constant λ can be derived from the half-life T1/2 as
Calculation of specific activity
editThe mass of the radionuclide is given by
where M is molar mass of the radionuclide, and NA is the Avogadro constant. Practically, the mass number A of the radionuclide is within a fraction of 1% of the molar mass expressed in g/mol and can be used as an approximation.
Specific radioactivity a is defined as radioactivity per unit mass of the radionuclide:
Thus, specific radioactivity can also be described by
This equation is simplified to
When the unit of half-life is in years instead of seconds:
Example: specific activity of Ra-226
editFor example, specific radioactivity of radium-226 with a half-life of 1600 years is obtained as
This value derived from radium-226 was defined as unit of radioactivity known as the curie (Ci).
Calculation of half-life from specific activity
editExperimentally measured specific activity can be used to calculate the half-life of a radionuclide.
Where decay constant λ is related to specific radioactivity a by the following equation:
Therefore, the half-life can also be described by
Example: half-life of Rb-87
editOne gram of rubidium-87 and a radioactivity count rate that, after taking solid angle effects into account, is consistent with a decay rate of 3200 decays per second corresponds to a specific activity of 3.2×106 Bq/kg. Rubidium atomic mass is 87 g/mol, so one gram is 1/87 of a mole. Plugging in the numbers:
Other calculations
editThis section may need to be cleaned up. It has been merged from Becquerel. |
For a given mass (in grams) of an isotope with atomic mass (in g/mol) and a half-life of (in s), the radioactivity can be calculated using:
With = 6.02214076×1023 mol−1, the Avogadro constant.
Since is the number of moles ( ), the amount of radioactivity can be calculated by:
For instance, on average each gram of potassium contains 117 micrograms of 40K (all other naturally occurring isotopes are stable) that has a of 1.277×109 years = 4.030×1016 s,[4] and has an atomic mass of 39.964 g/mol,[5] so the amount of radioactivity associated with a gram of potassium is 30 Bq.
Examples
editIsotope | Half-life | Mass of 1 curie | Specific Activity (a) (activity per 1 kg) |
---|---|---|---|
232Th | 1.405×1010 years | 9.1 tonnes | 4.07 MBq (110 μCi or 4.07 Rd) |
238U | 4.471×109 years | 2.977 tonnes | 12.58 MBq (340 μCi, or 12.58 Rd) |
235U | 7.038×108 years | 463 kg | 79.92 MBq (2.160 mCi, or 79.92 Rd) |
40K | 1.25×109 years | 140 kg | 262.7 MBq (7.1 mCi, or 262.7 Rd) |
129I | 15.7×106 years | 5.66 kg | 6.66 GBq (180 mCi, or 6.66 kRd) |
99Tc | 211×103 years | 58 g | 629 GBq (17 Ci, or 629 kRd) |
239Pu | 24.11×103 years | 16 g | 2.331 TBq (63 Ci, or 2.331 MRd) |
240Pu | 6563 years | 4.4 g | 8.51 TBq (230 Ci, or 8.51MRd) |
14C | 5730 years | 0.22 g | 166.5 TBq (4.5 kCi, or 166.5 MRd) |
226Ra | 1601 years | 1.01 g | 36.63 TBq (990 Ci, or 36.63 MRd) |
241Am | 432.6 years | 0.29 g | 126.91 TBq (3.43 kCi, or 126.91 MRd) |
238Pu | 88 years | 59 mg | 629 TBq (17 kCi, or 629 MRd) |
137Cs | 30.17 years | 12 mg | 3.071 PBq (83 kCi, or 3.071 GRd) |
90Sr | 28.8 years | 7.2 mg | 5.143 PBq (139 kCi, or 5.143 GRd) |
241Pu | 14 years | 9.4 mg | 3.922 PBq (106 kCi, or 3.922 GRd) |
3H | 12.32 years | 104 μg | 355.977 PBq (9.621 MCi, or 355.977 GRd) |
228Ra | 5.75 years | 3.67 mg | 10.101 PBq (273 kCi, or 10.101 GRd) |
60Co | 1925 days | 883 μg | 41.884 PBq (1.132 MCi, or 41.884 GRd) |
210Po | 138 days | 223 μg | 165.908 PBq (4.484 MCi, or 165.908 GRd) |
131I | 8.02 days | 8 μg | 4.625 EBq (125 MCi, or 4.625 TRd) |
123I | 13 hours | 518 ng | 71.41 EBq (1.93 GCi, or 71.41 TRd) |
212Pb | 10.64 hours | 719 ng | 51.43 EBq (1.39 GCi, or 51.43 TRd) |
Applications
editThe specific activity of radionuclides is particularly relevant when it comes to select them for production for therapeutic pharmaceuticals, as well as for immunoassays or other diagnostic procedures, or assessing radioactivity in certain environments, among several other biomedical applications.[6][7][8][9][10][11]
References
edit- ^ Breeman, Wouter A. P.; Jong, Marion; Visser, Theo J.; Erion, Jack L.; Krenning, Eric P. (2003). "Optimising conditions for radiolabelling of DOTA-peptides with 90Y, 111In and 177Lu at high specific activities". European Journal of Nuclear Medicine and Molecular Imaging. 30 (6): 917–920. doi:10.1007/s00259-003-1142-0. ISSN 1619-7070. PMID 12677301. S2CID 9652140.
- ^ de Goeij, J. J. M.; Bonardi, M. L. (2005). "How do we define the concepts specific activity, radioactive concentration, carrier, carrier-free and no-carrier-added?". Journal of Radioanalytical and Nuclear Chemistry. 263 (1): 13–18. doi:10.1007/s10967-005-0004-6. ISSN 0236-5731. S2CID 97433328.
- ^ "SI units for ionizing radiation: becquerel". Resolutions of the 15th CGPM (Resolution 8). 1975. Retrieved 3 July 2015.
- ^ "Table of Isotopes decay data". Lund University. 1990-06-01. Retrieved 2014-01-12.
- ^ "Atomic Weights and Isotopic Compositions for All Elements". NIST. Retrieved 2014-01-12.
- ^ Duursma, E. K. "Specific activity of radionuclides sorbed by marine sediments in relation to the stable element composition". Radioactive contamination of the marine environment (1973): 57–71.
- ^ Wessels, Barry W. (1984). "Radionuclide selection and model absorbed dose calculations for radiolabeled tumor associated antibodies". Medical Physics. 11 (5): 638–645. Bibcode:1984MedPh..11..638W. doi:10.1118/1.595559. ISSN 0094-2405. PMID 6503879.
- ^ I. Weeks; I. Beheshti; F. McCapra; A. K. Campbell; J. S. Woodhead (August 1983). "Acridinium esters as high-specific-activity labels in immunoassay". Clinical Chemistry. 29 (8): 1474–1479. doi:10.1093/clinchem/29.8.1474. PMID 6191885.
- ^ Neves, M.; Kling, A.; Lambrecht, R. M. (2002). "Radionuclide production for therapeutic radiopharmaceuticals". Applied Radiation and Isotopes. 57 (5): 657–664. CiteSeerX 10.1.1.503.4385. doi:10.1016/S0969-8043(02)00180-X. ISSN 0969-8043. PMID 12433039.
- ^ Mausner, Leonard F. (1993). "Selection of radionuclides for radioimmunotherapy". Medical Physics. 20 (2): 503–509. Bibcode:1993MedPh..20..503M. doi:10.1118/1.597045. ISSN 0094-2405. PMID 8492758.
- ^ Murray, A. S.; Marten, R.; Johnston, A.; Martin, P. (1987). "Analysis for naturally occuring [sic] radionuclides at environmental concentrations by gamma spectrometry". Journal of Radioanalytical and Nuclear Chemistry. 115 (2): 263–288. doi:10.1007/BF02037443. ISSN 0236-5731. S2CID 94361207.
Further reading
edit- Fetter, Steve; Cheng, E. T.; Mann, F. M. (1990). "Long-term radioactive waste from fusion reactors: Part II". Fusion Engineering and Design. 13 (2): 239–246. CiteSeerX 10.1.1.465.5945. doi:10.1016/0920-3796(90)90104-E. ISSN 0920-3796.
- Holland, Jason P.; Sheh, Yiauchung; Lewis, Jason S. (2009). "Standardized methods for the production of high specific-activity zirconium-89". Nuclear Medicine and Biology. 36 (7): 729–739. doi:10.1016/j.nucmedbio.2009.05.007. ISSN 0969-8051. PMC 2827875. PMID 19720285.
- McCarthy, Deborah W.; Shefer, Ruth E.; Klinkowstein, Robert E.; Bass, Laura A.; Margeneau, William H.; Cutler, Cathy S.; Anderson, Carolyn J.; Welch, Michael J. (1997). "Efficient production of high specific activity 64Cu using a biomedical cyclotron". Nuclear Medicine and Biology. 24 (1): 35–43. doi:10.1016/S0969-8051(96)00157-6. ISSN 0969-8051. PMID 9080473.