Calculation of Radiation Absorption Parameters for Some Selected Ferrite Ceramics

Yıl 2019, Cilt: 9 Sayı: 2, 771 - 779, 01.06.2019

Mehmet Fatih Turhan Fatma Akdemir Ferdi Akman Aslı Araz Rıdvan Durak

https://doi.org/10.21597/jist.442584

Öz

Ferrite ceramics are the most commonly used permanent magnet materials because

comparatively low-cost, easy to produce, excellent corrosion and demagnetization resistance

properties. Ferrite ceramics are utilized in the medical devices, magnetic therapy, magnetic toys,

speakers, microphones, audio systems, permanent magnetic actuators, watt-hour meters, sensors, cell

phones, electric motors, etc. In this study, mass attenuation coefficients, molecular cross sections,

atomic cross sections, electronic cross sections, effective atomic numbers and effective electron

densities were investigated in the energy range from 1 keV to 100 GeV for BaFe12O19, SrFe12O19,

Y3Fe5O12, LiFeO2. The changes in the absorption parameters were interpreted with the photoelectric

effect, Compton scattering and pair production processes.

Anahtar Kelimeler

Ferrite ceramic, Mass attenuation coefficient, Cross section, Effective atomic number, Effective electron density

Bazı Seçilen Ferrit Seramikler İçin Radyasyon Soğurma Parametrelerinin Hesaplanması

Öz

Ferrit seramikleri nispeten düşük maliyetli, üretilmesi kolay, mükemmel korozyon ve demanyetizasyon direnci özelliklerinden dolayı en yaygın kullanılan kalıcı mıknatıs malzemeleridir.

Ferrit seramikler tıbbi cihazlarda, manyetik terapide, manyetik oyuncaklarda, hoparlörlerde, mikrofonlarda, ses sistemlerinde, kalıcı manyetik aktüatörlerde, watt-saat metrelerde, sensörlerde, cep

telefonlarında, elektrik motorlarında, vb. kullanılırlar. Bu çalışmada 1 keV ile 100 GeV enerji aralığında BaFe12O19, SrFe12O19, Y3Fe5O12, LiFeO2 için kütle soğurma katsayıları, moleküler tesir

kesitleri, atomik tesir kesitleri, elektronik tesir kesitleri, etkin atom numaraları ve etkin elektron yoğunlukları incelenmiştir. Soğurma parametrelerinin değişimi fotoelektrik etki, Compton saçılması ve

çift oluşum süreçleriyle yorumlanmıştır.

Anahtar Kelimeler

Ferrit seramik, Kütle soğurma katsayısı, Tesir kesiti, Etkin atom numarası, Etkin elektron yoğunluğu

Kaynakça

• Akça B. and Erzeneoğlu SZ, 2014. The Mass Attenuation Coefficients, Electronic, Atomic, and Molecular Cross Sections, Effective Atomic Numbers, and Electron Densities for Compounds of Some Biomedically Important Elements at 59.5 keV. Science and Technology of Nuclear Installations, 901465:1-8.
• Akkurt I, 2009. Effective atomic and electron numbers of some steels at different energies. Annals of Nuclear Energy, 36:1702-1705.
• Akman F, Durak R, Turhan MF, Kaçal MR, 2015. Studies on effective atomic numbers, electron densities from mass attenuation coefficients near the K edge in some samarium compounds. Applied Radiation and Isotopes, 101:107–113.
• Akman F, Kaçal MR, Akman F, Soylu MS, 2017. Determination of effective atomic numbers and electron densities from mass attenuation coefficients for some selected complexes containing lanthanides. Canadian Journal of Physics, 95:1005-1011.
• Akman F, Geçibesler IH, Sayyed, MI, Tijani SA, Tufekci AR, Demirtas I, 2018. Determination of some useful radiation interaction parameters for waste foods. Nuclear Engineering and Technology, 50: 944-949.
• Baltaş H, Çevik U, 2008. Determination of the effective atomic numbers and electron densities for YBaCuO superconductor in the range 59.5–136 keV. Nuclear Instruments and Methods in Physics Research B, 266:1127–1131.
• Berger MJ and Hubbell JH, 1987. XCOM photon cross sections on a personal computer. NBSIR 87-3597. National Bureau of Standards (former name of NIST). Gaithersburg, MD. Available from: <http://physics.nist.gov.xcom>.
• Gerward L, Guilbert N, Jensen KB, Levring H, 2001. X-ray absorption in matter, reengineering XCom. Radiation Physics and Chemistry, 60:23-24.
• Han I, Demir L, Şahin M, 2009a. Determination of mass attenuation coefficients, effective atomic and electron numbers for some natural minerals. Radiation Physics and Chemistry, 78:760–764.
• Han I and Demir L, 2009b. Mass attenuation coefficients, effective atomic and electron numbers of Ti and Ni alloys. Radiation Measurements, 44:289–294.
• Han I and Demir L, 2009c. Studies on effective atomic numbers, electron densities from mass attenuation coefficients in TixCo1-x and CoxCu1-x alloys. Nuclear Instruments and Methods in Physics Research B, 267:3505–3510.
• Hubbell JH, 1982. Photon mass attenuation and energy absorption coefficients from 1 keV to 20 MeV. The International Journal of Applied Radiation and Isotopes, 33:1269–1290.
• Hubbell JH and Seltzer SM, 1995. Tables of X-ray attenuation coefficients and mass energy-absorption coefficients from 1 keV–20 MeV for elements Z-1 to 92 and 48 additional substances of dosimetry interest. NISTIR 5632.
• Issa SAM, Sayyed MI, Zaid MHM, Matori KA, 2018. Photon parameters for gamma rays sensing properties of some oxide of lanthanides. Results in Physics, 9:206-210.
• Kadam RH, Alone ST, Bıchıle GK, Jadhav KM, 2007. Measurement of atomic number and mass attenuation coefficient in magnesium ferrite. Pramana - Journal of Physics, 68(5):869-874.
• Kaçal MR, Karataş HA, Akman F, 2017. Photon Absorption characteristics of some selected Enzyme Inhibitors used in Cancer Research in the Energy range 1 keV-100 GeV. Journal of Radiology and Oncology, 1:60-68.
• Kaur P, Singh T, Singh D, 2017. Photon Interaction Parameters for Some ZnO–Al2O3–Fe2O3–P2O5 Glasses. Glass Physics and Chemistry, 43(3):227-232.
• Kore PS, Pawar PP, 2014. Measurements of mass attenuation coefficient, effective atomic number and electron density of some amino acids. Radiation Physics and Chemistry, 98:86–91.
• Manjunatha HC, 2017. A study of gamma attenuation parameters in poly methyl methacrylate and Kapton. Radiation Physics and Chemistry, 137:254–259.
• Pawar PP, Bichile GK, 2013. Studies on mass attenuation coefficient, effective atomic number and electron density of some amino acids in the energy range 0.122–1.330 MeV. Radiation Physics and Chemistry, 92:22–27.
• Singh G, Gupta MK, Dhaliwal AS, Kahlon KS, 2015. Measurement of attenuation coefficient, effective atomic number and electron density of oxides of lanthanides by using simplified ATM-method. Journal of Alloys and Compounds, 619:356–360.
• Singh K, Kaur R, Vandana, Kumar V, 1995. Study of effective Atomic Numbers and Mass Attenuation Coefficients in Some Compounds. Radiation Physics and Chemistry, 47:535-541.
• Singh VP, Badiger NM, Korkut T, 2018. Gamma exposure buildup factors and neutron total cross section of ceramic hosts for high level radioactive wastes. Progress in Nuclear Energy, 104:1-7.
• Vejdani-Noghreiyan A, Aliakbari E, Ebrahimi-Khankook A, Ghasemifard M, 2016. Theoretical and experimental determination of mass attenuation coefficients of lead-based ceramics and their comparison with simulation. Nuclear Technology & Radiation Protection, 31(2):142-149.