Critical-dimension scanning electron microscope characterization of smoothly varying wave structures with a Monte Carlo simulation

Khan, Muhammad Saadat Shakoor; Yang, Liguang; Xiao, Deng; Mao, Shifeng; Zou, Yu-Gang; Li, Y G; Li, H M; Ding, Zejun

doi:10.1088/1361-6463/ac0de5

Cited by 4 publications

(9 citation statements)

References 73 publications

(87 reference statements)

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“…Zou et al [18] have further studied the MBL method to include those parameters considered later in ISO 21466; for example, the beam-sample interaction model contains two effective parameters, namely, the line material and substrate material. Khan et al [32] applied the MBL method to characterize more complex sample structures having a smooth waveform and with a coated film, and we [33] have further extended the application of the method to rather more complex grating lines in 3D morphology and material components or electronic structure. Villarrubia et al [34] confirmed that the MBL method can be applied to linewidth measurements down to 10 nm scale; the measurements were in good agreement with the direct observation by a transmission electron microscope.…”

Section: Introductionmentioning

confidence: 99%

Application of a machine learning method to model-based library approach for critical dimension measurements using CD-SEM

Guo,

Miao,

Zou

et al. 2024

Meas. Sci. Technol.

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The model-based library (MBL) method has already been established for the accurate measurement of critical dimension (CD) of semiconductor linewidth from a critical dimension scanning electron microscope (CD-SEM) image. In this work the MBL method has been further investigated by combing the CD-SEM image simulation with a neural network algorithm. The secondary electron linescan profiles were calculated at first by a Monte Carlo simulation method, enabling to obtain the dependence of linescan profiles on the selected values of various geometrical parameters (e.g., top CD, sidewall angle and height) for Si and Au trapezoidal line structures. The machine learning methods have then been applied to predicate the linescan profiles from a randomly selected training set of the calculated profiles. The predicted results agree very well with the calculated profiles with the standard deviation of 0.1% and 6% for the relative error distributions of Si and Au line structures, respectively. This result shows that the machine learning methods can be practically applied to the MBL method for the purpose of reducing the library size, accelerating the construction of the MBL database and enriching the content of an available MBL database.

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Section: Introductionmentioning

confidence: 99%

Application of a machine learning method to model-based library approach for critical dimension measurements using CD-SEM

Guo,

Miao,

Zou

et al. 2024

Meas. Sci. Technol.

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“…For example, the Cr grating directly formed by laser-focused atom deposition in a standing wave has a smooth wave-like line shape. In our previous study, the SEM characterization of a Cr grating having a multilayer structure (Pt layer covering the Cr line on a Si substrate) was successfully performed with a Monte Carlo-simulated MBL database [46]. Unlike a sharp-edged trapezoidal line structure, the SEM linescan profile of this waveform line structure does not exhibit the usual edge effect, that is the sharp intensity bloom at an edge.…”

Section: Introductionmentioning

confidence: 99%

“…Unlike a sharp-edged trapezoidal line structure, the SEM linescan profile of this waveform line structure does not exhibit the usual edge effect, that is the sharp intensity bloom at an edge. However, one can still characterize such a wave structure by the side effects to obtain the structure feature parameters such as peak height, width, and tilt angle [46].…”

Section: Introductionmentioning

confidence: 99%

Linewidth characterization of a self-traceable grating by SEM

Guo,

Miao,

Mao

et al. 2024

J. Phys. D: Appl. Phys.

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In order to achieve high-precision nanometrology, a self-traceable grating reference material has been reported and prepared by atom lithography and soft X-ray interference techniques (J. Liu et al., Nanotechnology 32 (2021) 175301). In this work we employ a Monte Carlo simulation method to study the scanning electron microscopy (SEM) image contrast and linewidth characterization of the grating linewidth. The 3D structure of the mushroom-shaped grating line made of the multilayer (Pt, SiO2 and Si) is modeled according to the transmission electron microscopy (TEM) image, enabling the SEM linescan profiles of secondary electron signals to be obtained for different values of structural linewidth parameter from Monte Carlo simulations. In the light of the principle of the model-based library method a model database of Monte Carlo simulated SEM linescan profiles by varying the incident electron beam conditions and the grating linewidths is thus constructed; then the grating linewidth has been successfully characterized with experimental SEM image. By comparison with the TEM measurement, the measurement accuracy is verified to within 0.3% for the linewidth of ~25 nm.

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“…31–36 Simulation results were found to be in good agreement with experiments. 37–42 By combining Mott's cross section for describing the electron elastic scattering and the dielectric function for the electron inelastic scattering, we have developed and applied classic trajectory Monte Carlo (CTMC) simulation models to SEM, 43–52 AES 53–56 and reflected electron energy loss spectroscopy 57–64 with different simulation codes. 65 This CTMC simulation approach has also been applied to the analysis of thin film nanomaterials.…”

Section: Introductionmentioning

confidence: 99%

“…66–68 Even though one of the most significant advantages of the MC simulation method is on easy handling of complex sample geometrical boundaries, the previous Monte Carlo simulations have been mostly performed for simple and regular sample geometries until the applications of various numerical methods to the construction of the material interfaces. 47,49,51,52,69–74 For our present purpose it is necessary to apply these geometry construction methods to real-world nanomaterial morphologies for more comprehensive XPS analyses. Powell et al have used the simulation of electron spectra for surface analysis (SESSA) software, 27,28 where the sample structure was created with the PENGEOM geometry package, which uses analytic quadric surfaces to construct a NP morphology.…”

Section: Introductionmentioning

confidence: 99%

A theoretical characterization method for non-spherical core–shell nanoparticles by XPS

Gong

Khan

et al. 2023

Phys. Chem. Chem. Phys.

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Critical-dimension scanning electron microscope characterization of smoothly varying wave structures with a Monte Carlo simulation

Cited by 4 publications

References 73 publications

Application of a machine learning method to model-based library approach for critical dimension measurements using CD-SEM

Application of a machine learning method to model-based library approach for critical dimension measurements using CD-SEM

Linewidth characterization of a self-traceable grating by SEM

A theoretical characterization method for non-spherical core–shell nanoparticles by XPS

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