Secondary Fluorescence Correction for Characteristic and Bremsstrahlung X-Rays Using Monte Carlo X-ray Depth Distributions Applied to Bulk and Multilayer Materials

Yuan, Yu; Demers, Hendrix; Rudinsky, Samantha; Gauvin, Raynald

doi:10.1017/s1431927618016215

Cited by 8 publications

(11 citation statements)

References 29 publications

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“…The analytical model used to perform the SF correction of voxels is an extension of the model used for multilayers (Yuan et al, 2019), which is based on analytical models from previous research (Cox et al, 1979; Armigliato et al, 1982; Armstrong & Buseck, 1985; Youhua et al, 1988; Waldo, 1991; Pfeiffer et al, 1996). The derivation of the model is discussed below.…”

Section: Methodsmentioning

confidence: 99%

“…However, for materials with complex structures, it can be important (Cox et al, 1979). Although SF corrections of bulk and multilayer materials for MC X-ray have been implemented (Yuan et al, 2019), it has not been formulated or applied to materials with arbitrarily complex structures. This paper provides an accurate solution to this widely appreciated problem.…”

Section: Introductionmentioning

confidence: 99%

“…They obtained physical interaction parameters from PENELOPE and calculated SF using an analytical model. Following Llovet et al (2012), Yuan et al (2019) proposed a hybrid model which used MC X-ray to calculate the depth distribution of X-ray intensity and adopted an analytical model to calculate both characteristic and bremsstrahlung fluorescence. It can be applied to any bulk or multilayer materials.…”

Section: Introductionmentioning

confidence: 99%

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Secondary Fluorescence of 3D Heterogeneous Materials Using a Hybrid Model

Yuan

Demers²,

Wang

et al. 2020

Microsc Microanal

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In electron probe microanalysis or scanning electron microscopy, the Monte Carlo method is widely used for modeling electron transport within specimens and calculating X-ray spectra. For an accurate simulation, the calculation of secondary fluorescence (SF) is necessary, especially for samples with complex geometries. In this study, we developed a program, using a hybrid model that combines the Monte Carlo simulation with an analytical model, to perform SF correction for three-dimensional (3D) heterogeneous materials. The Monte Carlo simulation is performed using MC X-ray, a Monte Carlo program, to obtain the 3D primary X-ray distribution, which becomes the input of the analytical model. The voxel-based calculation of MC X-ray enables the model to be applicable to arbitrary samples. We demonstrate the derivation of the analytical model in detail and present the 3D X-ray distributions for both primary and secondary fluorescence to illustrate the capability of our program. Examples for non-diffusion couples and spherical inclusions inside matrices are shown. The results of our program are compared with experimental data from references and with results from other Monte Carlo codes. They are found to be in good agreement.

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Section: Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Secondary Fluorescence of 3D Heterogeneous Materials Using a Hybrid Model

Yuan

Demers²,

Wang

et al. 2020

Microsc Microanal

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“…There is no preferred growth on Ag microstructures whereas the density of MoO 3 NRs varies from Au NSs to the Si substrate. For further confirmation, we have simulated the Mo X-ray intensity using CASINO (Huvington et al, 1997; Yuan et al, 2019) software for both MoO 3 /Ag/Si and MoO 3 /Au/SiO 2 /Si systems to check if there is any contribution of backscattered electrons from Au to the Mo signal. We have found almost the same Mo intensity for both the cases [ I Mo (MoO 3 /Au/SiO 2 /Si)/ I Mo (MoO 3 /Ag/Si) = 1.06].…”

Section: Resultsmentioning

confidence: 99%

Growth of Molybdenum Trioxide Nanoribbons on Oriented Ag and Au Nanostructures: A Scanning Electron Microscopy (SEM) Study

et al. 2019

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We report the growth of molybdenum trioxide (MoO3) nanoribbons (NRs) on epitaxial Ag and oriented Au nanostructures (NSs) using an ultra-high vacuum (UHV)-molecular beam epitaxy (MBE) technique at different substrate temperatures. An approximately 2 nm silver (Ag) film has been deposited at different growth temperatures (using UHV-MBE) on cleaned Si(100), Si(110), and Si(111) substrates. For faceted Au NSs, an approximately 50 nm Au film has been deposited (using high-vacuum thermal evaporation) on a Si(100) substrate with a native oxide layer at the interface and the sample was annealed in low vacuum (≈10−2) and at high temperature (≈975°C). Scanning electron microscopy measurements were performed to determine the morphology of MoO3/Ag and MoO3/Au composite films. From energy dispersive X-ray spectroscopy elemental mapping and line scans it is found that faceted Au NSs are more favorable for the growth of MoO3 NRs than epitaxial Ag microstructures.

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“…The advantage of the Monte Carlo method is that it can be applied to samples with relatively complex geometries (see, e.g., Jennings et al, 2019aJennings et al, , 2019b. Its main drawback is that results are affected by statistical uncertainties, which in principle can only be reduced by increasing the simulation time, but recent progress in variance reduction techniques along with the increasing availability of fast computers have enhanced the attractiveness of this method for SF calculations (Llovet & Salvat, 2017;Ritchie, 2017;Yuan et al, 2019). The Monte Carlo simulation program PENEPMA (Llovet & Salvat, 2017) has the advantage over other existing codes that it simulates not only the transport of primary and secondary electrons but also that of generated X-rays, thus providing the SF contribution without any further calculation.…”

Section: Introductionmentioning

confidence: 99%