A proposed numerical method for absolute efficiency calibration of α-spectrometers and its application for activity calculation

In this work, an absolute method to calibrate an α-spectrometer is proposed taking into account the Source-to-Detector, and lateral distances due to eccentric source distribution. An analytical formula to calibrate an α-spectrometer is derived and the Simpson's integration method was utilized t...

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Bibliographic Details
Published in:Heliyon 2024-04, Vol.10 (7), p.e28498-e28498, Article e28498
Main Authors: El-Kourghly, K.M., El-Gammal, W., Damoom, Mohamed M., Alhawsawi, Abdulsalam M., Abdelati, M., Khedr, H.I., Abouzaid, R.
Format: Article
Language:English
Subjects:
Absolute method
Alpha spectrometers
Analytical-numerical
computer software
detectors
equations
exhibitions
MCNP
measurement
men
normal values
sampling
Solid angle
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Summary:In this work, an absolute method to calibrate an α-spectrometer is proposed taking into account the Source-to-Detector, and lateral distances due to eccentric source distribution. An analytical formula to calibrate an α-spectrometer is derived and the Simpson's integration method was utilized to solve these equations in its integral form numerically using a written C computer code. The general Monte Carlo N-particle code, MCNP as well as experimental measurements for some standard α-emitters are used to benchmark the proposed method. An agreement was found between the efficiency results calculated by MC and the proposed method with a maximum relative difference of about 0.5%. While, experimental measurement of α-emitters activity employing the proposed method differs by about 1.65% from the certified values. Accounting for the man made error allows to accurately quantify the assayed sample. Therefore, the inaccuracy in the efficiency results due to non-accurate inputs pertained to the source, and detector radii, Source–Detector distances, and eccentric source distribution are investigated in the Source-to-Detector distance range of (4 to 44 mm). The results show that a difference of ±1% in the detector radius, and Source-to-Detector distance than the normal values yields a relative difference of about ±2%, while a difference of ±50% in the source radius or source lateral distance from detector symmetry axis could only yields inaccuracy of less than ±3% in the efficiency results.
ISSN:2405-8440
2405-8440
DOI:10.1016/j.heliyon.2024.e28498