Model improvements to simulate charging in scanning electron microscope

Arat, Kerim T.; Klimpel, Thomas; Hagen, C. W.

doi:10.1117/1.jmm.18.4.044003

Cited by 9 publications

(3 citation statements)

References 41 publications

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“…According to a report by K. T. Arat et al 4,5 , the simulated equilibrium state is reached such that δ ~ 1 for SiO2 in positive charging mode. On the other hand, in a report by T. Thome et al, 6 when the irradiation current density is increased, δ of Al2O3 in the equilibrium state becomes less than 1.…”

Section: Time Change In Secondary Emission Coefficientmentioning

confidence: 97%

Local voltage contrast changes in MOSFET using scanning electron microscopy with photoelectron beam technology

Sato,

Arakawa,

Niimi

et al. 2024

Metrology, Inspection, and Process Control XXXVIII

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Scanning electron microscopy (SEM) is used for metrology and inspection in semiconductor manufacturing. In addition, electrical defects such as short circuits and unintentional insulation appear as contrast differences called voltage contrast (VC) in SEM under low acceleration voltage conditions. Moreover, by using pulsed electron beams from a photocathode, the probe current can be arbitrarily changed by pixel in the SEM image. Using this technology, we succeeded in observing the change in the VC of the drain in the metal-oxide-semiconductor field effect transistor (MOSFET) by changing in electron beam irradiation on the gate only. In this study, to estimate the threshold voltage of n-type MOSFET (nMOS) from VC, we investigated quantitative changes in the specimen current of the drain (Id) and the gate (Ig) due to gate e-beam irradiation ON/OFF during SEM imaging. The landing energy of the electron beam was set to 0.8 keV, the probe current was 6.3 pA, and the e-beam was irradiated onto only the gate and drain electrodes. Id and Ig, which showed a positive value at the beginning, decreased with time, and saturated at negative values. When the electron beam irradiation to the gate was turned OFF, the Id decreased further and reached saturation. When the gate e-beam irradiation was turned ON again, Ig recovered to a positive and then saturated again to a negative value. On the other hand, the drain Id increased when the gate irradiation was turned ON and returned to the same value as before it was turned OFF.

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Section: Time Change In Secondary Emission Coefficientmentioning

confidence: 97%

Local voltage contrast changes in MOSFET using scanning electron microscopy with photoelectron beam technology

Sato,

Arakawa,

Niimi

et al. 2024

Metrology, Inspection, and Process Control XXXVIII

View full text Add to dashboard Cite

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“…The local dielectric charging induced by the line scanning during SEM observation is a well known phenomenon, which can be simulated using simple mathematical/statistical physical approaches [25,26] (including those approved by the standards of NIST (National Institute of Standards and Technology [27] )). The electric charging of electron microscopic specimens has been actively studied from 1960s or 1970s [28,29] .…”

Section: Article Infomentioning

confidence: 99%

Reaction-diffusion effects and spatiotemporal oscillations under SEM, STM and AFM-assisted charging in fiber-like and wire-like systems: From molecular and quantum wires to cooperative ferroelectric nanofibers and microfibers

Adamovich,

Buryanskaya,

Gradova

et al. 2023

Mater. Tech. Rep.

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This review addresses the problem of reaction-diffusion effects and spatiotemporal oscillations in fiber-like and wire-like systems under the electron beam in SEM and in the presence of electric field in some special AFM techniques, such as current sensing atomic force microscopy (CS-AFM)/conductive atomic force microscopy (C-AFM), electrostatic force microscopy (EFM) and Kelvin probe force microscopy (KPFM) also known as surface potential microscopy. Some similar reaction-diffusion effects also can be observed in scanning capacitance microscopy (SCM), scanning gate microscopy (SGM), scanning voltage microscopy (SVM) and piezoresponse force microscopy (PFM). At the end of this paper the authors provide analysis of their own results and approaches. In particular, the possibility of achieving the ion transfer controlled growth of cells along the ion concentration gradients in reaction-diffusion fibers and actuators is indicated. This fundamental idea is discussed within the framework of the implantable fiber “bioiontronics” and “neuroiontronics” controlled by acoustic and electrical signals that regulate the reaction-diffusion or chemical oscillation activity of such fiber structures as reaction-diffusion actuators and sensors. The literature review includes more than 130 references.

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“…The charging phenomenon shows a dynamically changing contrast. Arat et al [22] have introduced two physical mechanisms into the simulation to perform dynamic charging accurately in the Monte Carlo simulation. The first is the introduction of a first-principles scattering model into the interaction mechanism between PE and specimen material.…”

Section: ∆E = S × (De/ds)mentioning

confidence: 99%

Electron microscopy in semiconductor inspection

Nakamae

2021

Meas. Sci. Technol.

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Currently, semiconductor devices are manufactured in a technology node of several nanometers. Electron microscopy is mainly used in semiconductor inspection in manufacturing stages since accelerated electrons have wavelengths of nanometers or less, and a high spatial resolution can be expected. Among various electron microscopes since the scanning electron microscope (SEM) can observe the sample as it is without processing the sample, the SEM-based inspection instrument is mainly used at each stage of manufacturing the semiconductor device. The paper presents a review of SEM-based electron microscopy in semiconductor inspection. First, an overview of electron microscopy is described to understand the electron-sample interaction, the characteristics of electrons emitted from an irradiated specimen, charging, noise, and so on. Next, application areas such as mask inspection are introduced. Finally, future challenges are discussed.

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Model improvements to simulate charging in scanning electron microscope

Cited by 9 publications

References 41 publications

Local voltage contrast changes in MOSFET using scanning electron microscopy with photoelectron beam technology

Local voltage contrast changes in MOSFET using scanning electron microscopy with photoelectron beam technology

Reaction-diffusion effects and spatiotemporal oscillations under SEM, STM and AFM-assisted charging in fiber-like and wire-like systems: From molecular and quantum wires to cooperative ferroelectric nanofibers and microfibers

Electron microscopy in semiconductor inspection

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