Materials (Nov 2021)

Quartz Tuning Fork Sensor-Based Dosimetry for Sensitive Detection of Gamma Radiation

  • Nadyah Alanazi,
  • Abdullah N. Alodhayb,
  • Atheer Almutairi,
  • Hanan Alshehri,
  • Sarah AlYemni,
  • Ghadah Alsowygh,
  • Sabaa Abdulmawla,
  • Khaled Shamma,
  • Hamad Albrithen,
  • Muthumareeswaran Muthuramamoorthy,
  • Aljawhara H. Almuqrin

DOI
https://doi.org/10.3390/ma14227035
Journal volume & issue
Vol. 14, no. 22
p. 7035

Abstract

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This study generally relates to nuclear sensors and specifically to detecting nuclear and electromagnetic radiation using an ultrasensitive quartz tuning fork (QTF) sensor. We aim to detect low doses of gamma radiation with fast response time using QTF. Three different types of QTFs (uncoated and gold coated) were used in this study in order to investigate their sensitivity to gamma radiations. Our results show that a thick gold coating on QTF can enhance the quality factor and increase the resonance frequency from 32.7 to 32.9 kHz as compared to uncoated QTF. The results also show that increasing the surface area of the gold coating on the QTF can significantly enhance the sensitivity of the QTF to radiation. We investigated the properties of gold-coated and uncoated QTFs before and after irradiation by scanning electron microscopy. We further investigated the optical properties of SiO2 wafers (quartz) by spectroscopic ellipsometry (SE). The SE studies revealed that even a small change in the microstructure of the material caused by gamma radiation would have an impact on mechanical properties of QTF, resulting in a shift in resonance frequency. Overall, the results of the experiments demonstrated the feasibility of using QTF sensors as an easy to use, low-cost, and sensitive radiation detector.

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