The Effect of Boronizing on the Radiation Shielding Properties of Steel

Abstract: The radiation shielding properties of steel and its variation with the boronizing process have been investigated. For this purposes the linear attenuation coefficients of steel have been measured before and after boronizing the steel at the photon energy of 662 and 1250 keV. The measured results before boronizing were compared with the theoretical calculation. It was clearly seen that boronizing improved the radiation shielding properties of steel.

“…From this figure, we say that the μ increases with increasing Ni content due to changing the of borided Fe-Ni binary alloys. The same results for μ have been reported in the other studies [5,6]. They showed that attenuation coefficient depends on the chemical composition of materials.…”

“…The studies showed that the degree to which gamma radiation is attenuated is dependent upon the energy of the incident gamma radiation, the atomic number and density of the elements in the shielding material, and the thickness of the shielding [1][2][3][4][5][6]. Carbon steels or stainless steels, as lead (Pb), have been commonly used as materials for thermal and radiation shields [2,3,[7][8][9].…”

“…Corresponding to this, it has been found that the measured effective linear attenuation coefficient (µ) of carbon steel gives an average value of 0.340 cm -1 [2]. On the other hand, in recent years, boron has been used as an alternative for radiation shielding, although heavy metals such as Pb have been used for this purpose [4,5,10,11]. In relation to this, it has been shown that the borided AISI 316L and microalloyed stainless steels, especially in the middle energy region, have radiation shielding properties that are similar to those of Pb, the standard shielding material [3,4].…”

RADIATION SHIELDING PROPERTIES OF BORIDED Fe-Ni ALLOYS.

“…From this figure, we say that the μ increases with increasing Ni content due to changing the of borided Fe-Ni binary alloys. The same results for μ have been reported in the other studies [5,6]. They showed that attenuation coefficient depends on the chemical composition of materials.…”

“…The studies showed that the degree to which gamma radiation is attenuated is dependent upon the energy of the incident gamma radiation, the atomic number and density of the elements in the shielding material, and the thickness of the shielding [1][2][3][4][5][6]. Carbon steels or stainless steels, as lead (Pb), have been commonly used as materials for thermal and radiation shields [2,3,[7][8][9].…”

“…Corresponding to this, it has been found that the measured effective linear attenuation coefficient (µ) of carbon steel gives an average value of 0.340 cm -1 [2]. On the other hand, in recent years, boron has been used as an alternative for radiation shielding, although heavy metals such as Pb have been used for this purpose [4,5,10,11]. In relation to this, it has been shown that the borided AISI 316L and microalloyed stainless steels, especially in the middle energy region, have radiation shielding properties that are similar to those of Pb, the standard shielding material [3,4].…”

RADIATION SHIELDING PROPERTIES OF BORIDED Fe-Ni ALLOYS.

Effective atomic and electron numbers of some steels at different energies

Investigation of gamma-ray attenuation coefficients for solid boronized 304L stainless steel