Effective atomic number studies in clay minerals for total photon interaction in the energy region 10 keV–10 MeV

An attempt has been made to calculate the effective atomic number and Kerma for photon energy absorption of organic scintillators in the energy region 1 keV to 20 MeV. We have chosen seven organic scintillators viz., anthracene, stilbene, naphthalene, p -terphenyl, PPO, butyl PBD and PBD. The Z PEA, eff and Kerma values are calculated by using mass-energy absorption coefficient from Hubbell and Seltzer. We also calculated Z PI, eff for total photon interaction with coherent scattering by using WinXCom and compared with the Z PEA, eff.

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The effective atomic number revisited in the light of modern photon-interaction cross-section databases

Applied Radiation and Isotopes ◽

10.1016/j.apradiso.2009.09.047 ◽

2010 ◽

Vol 68 (4-5) ◽

pp. 784-787 ◽

Cited By ~ 27

Author(s):

S.R. Manohara ◽

S.M. Hanagodimath ◽

K.S. Thind ◽

L. Gerward

Keyword(s):

Cross Section ◽

Atomic Number ◽

Effective Atomic Number ◽

Interaction Cross Section ◽

Photon Interaction

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Comparative study on results of calculating the effective atomic number by means of various methods in the photon energy region of 250–700 keV

Nuclear Instruments and Methods in Physics Research Section B Beam Interactions with Materials and Atoms ◽

10.1016/j.nimb.2021.10.002 ◽

2021 ◽

Vol 508 ◽

pp. 34-40

Author(s):

A.N. Eritenko ◽

A.L. Tsvetyansky ◽

A.A. Polev

Keyword(s):

Comparative Study ◽

Photon Energy ◽

Atomic Number ◽

Energy Region ◽

Effective Atomic Number

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Material Identification in Presence of Metal for Baggage Screening

Electronic Imaging ◽

10.2352/issn.2470-1173.2020.14.coimg-294 ◽

2020 ◽

Vol 2020 (14) ◽

pp. 294-1-294-8

Author(s):

Sandamali Devadithya ◽

David Castañón

Keyword(s):

Atomic Number ◽

Effective Atomic Number ◽

Simulated Data ◽

Dual Energy ◽

Basis Functions ◽

Total Variation Regularization ◽

Ct Scanner ◽

Edge Preserving ◽

Baggage Screening ◽

Dual Energy Imaging

Dual-energy imaging has emerged as a superior way to recognize materials in X-ray computed tomography. To estimate material properties such as effective atomic number and density, one often generates images in terms of basis functions. This requires decomposition of the dual-energy sinograms into basis sinograms, and subsequently reconstructing the basis images. However, the presence of metal can distort the reconstructed images. In this paper we investigate how photoelectric and Compton basis functions, and synthesized monochromatic basis (SMB) functions behave in the presence of metal and its effect on estimation of effective atomic number and density. Our results indicate that SMB functions, along with edge-preserving total variation regularization, show promise for improved material estimation in the presence of metal. The results are demonstrated using both simulated data as well as data collected from a dualenergy medical CT scanner.

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A Spectrum-Adaptive Decomposition Method for Effective Atomic Number Estimation Using Dual Energy CT

Electronic Imaging ◽

10.2352/issn.2470-1173.2020.14.coimg-293 ◽

2020 ◽

Vol 2020 (14) ◽

pp. 293-1-293-7

Author(s):

Ankit Manerikar ◽

Fangda Li ◽

Avinash C. Kak

Keyword(s):

Atomic Number ◽

Decomposition Method ◽

Traditional Approach ◽

Effective Atomic Number ◽

Dual Energy ◽

Performance Comparison ◽

Estimation Methods ◽

Dual Energy Ct ◽

Projection Data ◽

X Ray

Dual Energy Computed Tomography (DECT) is expected to become a significant tool for voxel-based detection of hazardous materials in airport baggage screening. The traditional approach to DECT imaging involves collecting the projection data using two different X-ray spectra and then decomposing the data thus collected into line integrals of two independent characterizations of the material properties. Typically, one of these characterizations involves the effective atomic number (Zeff) of the materials. However, with the X-ray spectral energies typically used for DECT imaging, the current best-practice approaches for dualenergy decomposition yield Zeff values whose accuracy range is limited to only a subset of the periodic-table elements, more specifically to (Z < 30). Although this estimation can be improved by using a system-independent ρe — Ze (SIRZ) space, the SIRZ transformation does not efficiently model the polychromatic nature of the X-ray spectra typically used in physical CT scanners. In this paper, we present a new decomposition method, AdaSIRZ, that corrects this shortcoming by adapting the SIRZ decomposition to the entire spectrum of an X-ray source. The method reformulates the X-ray attenuation equations as direct functions of (ρe, Ze) and solves for the coefficients using bounded nonlinear least-squares optimization. Performance comparison of AdaSIRZ with other Zeff estimation methods on different sets of real DECT images shows that AdaSIRZ provides a higher output accuracy for Zeff image reconstructions for a wider range of object materials.

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