Optimization of the depth resolution for profiling SiO2/SiC interfaces by dual‐beam TOF‐SIMS combined with etching

Sameshima, Junichiro; Takenaka, Aya; Muraji, Yuichi; Ogawa, Shingo; Yoshikawa, Masanobu; Suganuma, Katsuaki

doi:10.1002/sia.6645

Cited by 6 publications

(4 citation statements)

References 17 publications

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“…In this study, an application of simulation was conducted for these experimental depth profiles obtained with high depth resolution mode. It aims to confirm if the simulation can duplicate slight differences of depth profiles appeared experimentally among samples in the previous report [8]. Additionally a possibility of acquiring a more authentic distribution at the SiO2/SiC interface was examined.…”

Section: Introductionmentioning

confidence: 84%

“…Hence, depth profiling for steep distribution such as that at the SiO2/SiC interface needs a high depth resolution suppressing mixing and knock-on effect and detecting slight discrepancies in the distribution at the interface in SIMS measurement. In a previous study, an experimental method to achieve the high resolution depth profiling of sub-nm by using dual-beam time-of-flight SIMS (TOF-SIMS) was developed, in which the determination of the optimal dual-beam analytical conditions, verification of the etching methods to thin the SiO2 layer, and confirmation of the benefits of the low-energy sputtering beam had been established [8], and the roughness of the etched surface and mixing effect due to sputtering ion beam have been minimized. Nevertheless, an uncertainty in the experimental profiles remains unsolved due to the slight roughness of both at the surface and at the SiO2/SiC interface, and due to ion mixing caused by sputtering ion beam.…”

Section: Introductionmentioning

confidence: 99%

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Profiling with Depth Resolution of Sub-nm for SiO2/ SiC Interface by Dual-Beam TOF-SIMS Combined with Simulation

Sameshima

Takenaka

Muraji

et al. 2020

MSF

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For precise investigation of distribution for impurity or composition at SiO2/SiC interface, dual-beam Time-of-flight Secondary ion mass spectrometry (TOF-SIMS) with low energy sputtering beam was available. In addition to the experimental profiles, simulation using MRI model, in which Mixing, Roughness and Information depth were employed as parameters, enabled to acquire a more authentic distribution at the SiO2/SiC interface. Slight discrepancy on depth profiles between samples with different surface roughness was duplicated on the convoluted profiles in the simulation. Moreover, reconstructed profile of nitrogen indicated a real distribution with less impact of mixing and roughness, although that may contain uncertainty due to incompletion in the simulation model or variation of the distribution owing to detection species in the experiment. From the result of carbon profiles of both experimental and convoluted profiles, the relative discrepancy on the carbon distribution between samples was clarified, which suggested the possibility that a carbon thin layer at the SiO2/SiC interface would be found in the future.

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Section: Introductionmentioning

confidence: 84%

Section: Introductionmentioning

confidence: 99%

Profiling with Depth Resolution of Sub-nm for SiO2/ SiC Interface by Dual-Beam TOF-SIMS Combined with Simulation

Sameshima

Takenaka

Muraji

et al. 2020

MSF

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“…The raster scanned area of the Bi + beam, which is equivalent to the detection field area, was set as 20 μm × 20 μm or 100 μm × 100 μm, whereas the ion current was adjusted between 4.0 and 4.3 pA. After setting the Cs + and Bi + parameters, the potential damage due to excessive irradiation of high‐energy Bi + primary ions was taken into consideration. Based on previous studies, 21,22 a primary ion to sputtering ion ratio that would not exceed the damage threshold was determined. In addition, the raster scanning areas of both ion beams were appropriately chosen to exclude the crater edge effect.…”

Section: Methodsmentioning

confidence: 99%

Behavior and process of background signal formation of hydrogen, carbon, nitrogen, and oxygen in silicon wafers during depth profiling using dual‐beam TOF‐SIMS

Sameshima

Numao

2021

Surface & Interface Analysis

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The behavior and mechanism of background signals during depth profiling of atmospheric elements using dual‐beam time‐of‐flight secondary ion mass spectrometry (TOF‐SIMS) have been experimentally investigated for silicon wafers. The background signals of atmospheric elements were found to be inversely proportional to the sputtering rate. Most of the background signals are largely attributable to the accumulation of components through adsorption and ion bombardment in the pre‐equilibrium state. On the other hand, the contribution of real‐time adsorption during the instant after the last sputtering in the equilibrium state is negligible under the present experimental conditions. H2O is dominant in the background formation process of hydrogen and oxygen, which is supported by the higher adsorption coefficients. The background levels of carbon and nitrogen are lower than those of hydrogen and oxygen. Furthermore, the background signal of carbon with respect to the sputtering rate shows a different trend than the other elements. This could be attributed to accumulation in the pre‐equilibrium state. These results indicate that the background levels can be lowered close to those of dynamic‐SIMS by using an extremely high sputtering rate in dual‐beam TOF‐SIMS.

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“…Utilizing the approximation of binary collisions and the Monte Carlo method as its foundation, the simulations were performed using the SRIM 2013 software (Stopping and Range of Ions in Matter). This software is a collection of Windows-based tools that allow one to model both the trajectory of recoiling atoms in a solid and the trajectory of an ion at incidence energies between 10 eV and 2 GeV [41,42]. The three primary programs are the stopping power of ions computation (Stopping/Range Tables) and the detailed calculation (TRIM computation), both of which have an easy-to-use interface.…”

Section: Theory and Computational Detailsmentioning

confidence: 99%

Calculations of Stopping Power, Straggling and Range Projected of FeKr+

Farjallah

2024

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The present work consists of the simulation of the interaction of a beam of Kr+ ions with a solid iron target by the software SRIM (Stopping and Range of Ions In Matter). Our goal is to calculate different parameters related to sputtering and ion implantation in a target, such as the spatial distribution of implanted ions, the distributions of electronic and nuclear energy losses as a function of penetration depth and sputtering efficiency, as well as the damage created inside the target. The sputter induced photon spectroscopy technique was used to study the luminescence spectra of the species sputtered from Iron powder, during 5 keV Kr+ ions bombardment in vacuum better than 107 torr. The optical spectra recorded between 350 and 470 nm exhibit discrete lines which are attributed to neutral excited atoms of Iron (Fe). The experiments are also performed under 105 torr ultra-pure oxygen partial pressure. To ensure the maximum efficiency of molecular modification process, energy of irradiation was decided by using of SRIM software. Based on SRIM simulation of Iron ions interaction with Krypton, the areas on which effect of high energy ions will maximum were predicted. A comparative analysis of molecular before and after irradiation was carried out by scanning electron microscopy. The maximum change in Krypton morphology, in the form of destruction of walls, was appeared at a distance of about μm from the start point of Fe+ ions track inside the molecular. A substantiation of reason of wall degradation in this area was proposed.

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Optimization of the depth resolution for profiling SiO₂/SiC interfaces by dual‐beam TOF‐SIMS combined with etching

Cited by 6 publications

References 17 publications

Profiling with Depth Resolution of Sub-nm for SiO<sub>2</sub>/ SiC Interface by Dual-Beam TOF-SIMS Combined with Simulation

Profiling with Depth Resolution of Sub-nm for SiO<sub>2</sub>/ SiC Interface by Dual-Beam TOF-SIMS Combined with Simulation

Behavior and process of background signal formation of hydrogen, carbon, nitrogen, and oxygen in silicon wafers during depth profiling using dual‐beam TOF‐SIMS

Calculations of Stopping Power, Straggling and Range Projected of FeKr<sup>+</sup>

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Optimization of the depth resolution for profiling SiO2/SiC interfaces by dual‐beam TOF‐SIMS combined with etching

Cited by 6 publications

References 17 publications

Profiling with Depth Resolution of Sub-nm for SiO<sub>2</sub>/ SiC Interface by Dual-Beam TOF-SIMS Combined with Simulation

Profiling with Depth Resolution of Sub-nm for SiO<sub>2</sub>/ SiC Interface by Dual-Beam TOF-SIMS Combined with Simulation

Behavior and process of background signal formation of hydrogen, carbon, nitrogen, and oxygen in silicon wafers during depth profiling using dual‐beam TOF‐SIMS

Calculations of Stopping Power, Straggling and Range Projected of FeKr&lt;sup&gt;+&lt;/sup&gt;

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Optimization of the depth resolution for profiling SiO₂/SiC interfaces by dual‐beam TOF‐SIMS combined with etching

Calculations of Stopping Power, Straggling and Range Projected of FeKr<sup>+</sup>