The Effect of Calcination Conditions on Luminescence Efficiency of BeO Ceramics Synthesized Using Co-Precipitation Method

Volkan Altunal; Veysi Güçkan; Adnan Özdemir; Zehra Yegingil

Research Article

The Effect of Calcination Conditions on Luminescence Efficiency of BeO Ceramics Synthesized Using Co-Precipitation Method

Year 2019, Volume: 2 Issue: 2, 40 - 44, 26.12.2019

Volkan Altunal Veysi Güçkan Adnan Özdemir Zehra Yegingil

Abstract

BeO ceramics were
synthesized by co-precipitation method. The luminescent behaviors of the BeO
ceramics prepared under different reaction conditions were investigated for
radiation dosimetry applications. The appropriate calcination temperature and
time for the sol-gel synthesis of BeO was determined as 1000 °C for 4 hours by
analyzing optically stimulated luminescence (OSL), thermoluminescence (TL)
sensitivities and radioluminescence (RL) emissions of the products. While
similar characteristic broad emission peak of BeO ceramics between 200 and 500
nm was obtained in RL spectra, an unexpected peak between 650 and 800 nm which
may be associated with the anion defects in BeO was observed. While highly
sensitive two TL peaks were observed up to 250 °C, low sensitive four TL peaks
were found up to 650 °C. The results showed that luminescent signals from the
BeO pellets produced at appropriate synthesis conditions were suitable for
radiation measurement applications in personal dosimetry.

Keywords

Beryllium oxide (BeO), Precipitation synthesis, Calcination Conditions, Radiation Dosimetry, Luminescence

Supporting Institution

Çukurova Üniversitesi

Project Number

FDK-2018-10190

Thanks

This project has been supported by the Çukurova University Rectorate through the project FDK-2018-10190. We are grateful to Çukurova University Rectorate for their supports. We appreciate Prof. Kasım Kurt for RL measurements.

References

[1] Rivera, T. (2011). Synthesis and thermoluminescent characterization of ceramics materials. Advances in ceramics–synthesis and characterization, processing and specific applications. InTech, Rijeka, Croatia, 127-164.
[2] Boch, P., & Niepce, J.-C. (2010). Ceramic Materials: Processes, Properties, and Applications (Vol. 98): John Wiley & Sons.
[3] Carter, C. B., & Norton, M. G. (2007). Ceramic materials: science and engineering (Vol. 716): Springer.
[4] Albrecht, H. O., & Mandeville, C. E. (1956). Storage of Energy in Beryllium Oxide. Physical Review, 101(4), 1250-1252. doi:10.1103/PhysRev.101.1250
[5] Rhyner, C. R., & Miller, W. G. (1970). Radiation dosimetry by optically-stimulated luminescence of BeO. Health Physics, 18, 681-684.
[6] Tochilin, E., Goldstein, N., & Miller, W. (1969). Beryllium oxide as a thermoluminescent dosimeter. Health Physics, 16(1), 1-7.
[7] McKeever, S. W., Moscovitch, M., & Townsend, P. D. (1995). Thermoluminescence dosimetry materials: properties and uses.
[8] Bulur, E., & Goksu, H. Y. (1998). OSL from BEO ceramics: New observations from an old material. Radiation Measurements, 29(6), 639-650. doi:Doi 10.1016/S1350-4487(98)00084-5
[9] Bos, A. J. J. (2001). High sensitivity thermoluminescence dosimetry. Nuclear Instruments & Methods in Physics Research Section B-Beam Interactions with Materials and Atoms, 184(1-2), 3-28. doi:Doi 10.1016/S0168-583x(01)00717-0
[10] Sommer, M., & Henniger, J. (2006). Investigation of a BeO-based optically stimulated luminescence dosemeter. Radiat Prot Dosimetry, 119(1-4), 394-397. doi:10.1093/rpd/nci626
[11] Sommer, M., Jahn, A., & Henniger, J. (2008). Beryllium oxide as optically stimulated luminescence dosimeter. Radiation Measurements, 43(2-6), 353-356. doi:10.1016/j.radmeas.2007.11.018
[12] Jahn, A., Sommer, M., Ullrich, W., Wickert, M., & Henniger, J. (2013). The BeOmax system – Dosimetry using OSL of BeO for several applications. Radiation Measurements, 56, 324-327. doi:10.1016/j.radmeas.2013.01.069
[13] Altunal, V., Guckan, V., Ozdemir, A., Sotelo, A., & Yegingil, Z. (2019). Effect of sintering temperature on dosimetric properties of BeO ceramic pellets synthesized using precipitation method. Nuclear Instruments and Methods in Physics Research Section B: Beam Interactions with Materials and Atoms, 441, 46-55.
[14] Altunal, V., Guckan, V., Ozdemir, A., Can, N., & Yegingil, Z. (2019). Luminescence characteristics of Al-and Ca-doped BeO obtained via a sol-gel method. Journal of Physics and Chemistry of Solids.doi: https://doi.org/10.1016/j.jpcs.2019.04.003

Year 2019, Volume: 2 Issue: 2, 40 - 44, 26.12.2019

Volkan Altunal Veysi Güçkan Adnan Özdemir Zehra Yegingil

Abstract

Project Number

FDK-2018-10190

References

[1] Rivera, T. (2011). Synthesis and thermoluminescent characterization of ceramics materials. Advances in ceramics–synthesis and characterization, processing and specific applications. InTech, Rijeka, Croatia, 127-164.
[2] Boch, P., & Niepce, J.-C. (2010). Ceramic Materials: Processes, Properties, and Applications (Vol. 98): John Wiley & Sons.
[3] Carter, C. B., & Norton, M. G. (2007). Ceramic materials: science and engineering (Vol. 716): Springer.
[4] Albrecht, H. O., & Mandeville, C. E. (1956). Storage of Energy in Beryllium Oxide. Physical Review, 101(4), 1250-1252. doi:10.1103/PhysRev.101.1250
[5] Rhyner, C. R., & Miller, W. G. (1970). Radiation dosimetry by optically-stimulated luminescence of BeO. Health Physics, 18, 681-684.
[6] Tochilin, E., Goldstein, N., & Miller, W. (1969). Beryllium oxide as a thermoluminescent dosimeter. Health Physics, 16(1), 1-7.
[7] McKeever, S. W., Moscovitch, M., & Townsend, P. D. (1995). Thermoluminescence dosimetry materials: properties and uses.
[8] Bulur, E., & Goksu, H. Y. (1998). OSL from BEO ceramics: New observations from an old material. Radiation Measurements, 29(6), 639-650. doi:Doi 10.1016/S1350-4487(98)00084-5
[9] Bos, A. J. J. (2001). High sensitivity thermoluminescence dosimetry. Nuclear Instruments & Methods in Physics Research Section B-Beam Interactions with Materials and Atoms, 184(1-2), 3-28. doi:Doi 10.1016/S0168-583x(01)00717-0
[10] Sommer, M., & Henniger, J. (2006). Investigation of a BeO-based optically stimulated luminescence dosemeter. Radiat Prot Dosimetry, 119(1-4), 394-397. doi:10.1093/rpd/nci626
[11] Sommer, M., Jahn, A., & Henniger, J. (2008). Beryllium oxide as optically stimulated luminescence dosimeter. Radiation Measurements, 43(2-6), 353-356. doi:10.1016/j.radmeas.2007.11.018
[12] Jahn, A., Sommer, M., Ullrich, W., Wickert, M., & Henniger, J. (2013). The BeOmax system – Dosimetry using OSL of BeO for several applications. Radiation Measurements, 56, 324-327. doi:10.1016/j.radmeas.2013.01.069
[13] Altunal, V., Guckan, V., Ozdemir, A., Sotelo, A., & Yegingil, Z. (2019). Effect of sintering temperature on dosimetric properties of BeO ceramic pellets synthesized using precipitation method. Nuclear Instruments and Methods in Physics Research Section B: Beam Interactions with Materials and Atoms, 441, 46-55.
[14] Altunal, V., Guckan, V., Ozdemir, A., Can, N., & Yegingil, Z. (2019). Luminescence characteristics of Al-and Ca-doped BeO obtained via a sol-gel method. Journal of Physics and Chemistry of Solids.doi: https://doi.org/10.1016/j.jpcs.2019.04.003

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Details

Primary Language	English
Journal Section	Research Papers
Authors	Volkan Altunal 0000-0001-9411-3441 Veysi Güçkan 0000-0001-7693-7770 Adnan Özdemir This is me 0000-0002-2685-1562 Zehra Yegingil 0000-0001-7408-847X
Project Number	FDK-2018-10190
Publication Date	December 26, 2019
Submission Date	October 23, 2019
Acceptance Date	December 25, 2019
Published in Issue	Year 2019 Volume: 2 Issue: 2

Cite

APA	Altunal, V., Güçkan, V., Özdemir, A., Yegingil, Z. (2019). The Effect of Calcination Conditions on Luminescence Efficiency of BeO Ceramics Synthesized Using Co-Precipitation Method. Journal of Investigations on Engineering and Technology, 2(2), 40-44.

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