Effect Model of Stress and Plastic Deformation on Conductivities of Various Magnetic Materials

X-ray fluorescence (XRF) analysis is a widespread and preferred method for a variety of analytical applications. Among other aspects, it is an excellent method for identifying inhomogeneities in elemental distribution due to its non-invasiveness and non-destructiveness. However, the fact that it uses relatively low-energy X-rays brings some limitations and problems in interpreting the measurement results, especially if objects with multi-layer thicker films are investigated. In this paper, an XRF mapping method based on a heavy metal tungsten target is presented to handle this problem. Using the principle of material genome engineering, 50 wt% Bi2 O3 -Sm2 O3 -Er2 O3 /natural rubber (NR) films for attenuating X-rays are prepared by a latex impregnation method. The combination of Bi2 O3 , Sm2 O3 and Er2 O3 can achieve the best protection effect on 20-100 keV wide-spectrum X-rays and also make up for the weak absorption region of a single material. Macroscopic (XRF mapping) and microscopic (submicron computed tomography (CT) and energy-dispersive spectrometer (EDS)) methods show that the filler is well dispersed in the NR. The shielding properties of Bi2 O3 -Sm2 O3 -Er2 O3 /NR flexible film show that it can be used in the X-ray protection field. The importance of the XRF mapping method is related to the need to identify the distribution of the chemical elements in large surface areas of objects by a non-destructive method compared to an EDS.

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Effect Model of Stress and Plastic Deformation on Conductivities of Various Magnetic Materials

Cited by 4 publications

References 22 publications

Modelling and validating of constitutive relationship between uniaxial stress and AC electromagnetic field

Modelling and validating of constitutive relationship between uniaxial stress and AC electromagnetic field

Changes in the Steinmetz Coefficients of Punched Soft-Magnetic Sheets

XRF mapping for identifying inhomogeneity of elemental distribution in multi-layer flexible films for attenuating X-rays

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