• Title/Summary/Keyword: Ion beam milling

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The ocused Ion Beam Etching Characteristic of Au (집속 이온빔 가공변수에 따른 Au 에칭 특성 연구)

  • Park, J.J.;Kim, S.D.
    • Transactions of the Korean Society of Machine Tool Engineers
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    • v.16 no.5
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    • pp.129-133
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    • 2007
  • Focused Ion Beam(FIB) systems is a useful tool for the fabrication of micro-nano scale structures. In this study, the effects of FIB etching on the Au microstructure are systematically investigated. As the fabrication parameters, ion dose, dwell time and beam overlap ratio are studied. First, the increases of Ga ion dose makes the milling yield higher and the sidewall of milling profile steeper. Dwell time is found to have little effects on the milling profile due to the relatively large milling area of $1\times1{\mu}m^2$ used in this study. However, beam overlap significantly affects not only milling rate but also milling profile. As the beam overlap ratio changes from positive to negative, the development of regular cross-stripe patterns at the bottom with low milling rate is observed.

Cross-Sectional Transmission Electron Microscopy Specimen Preparation Technique by Backside Ar Ion Milling

  • Yoo, Jung Ho;Yang, Jun-Mo
    • Applied Microscopy
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    • v.45 no.4
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    • pp.189-194
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    • 2015
  • Backside Ar ion milling technique for the preparation of cross-sectional transmission electron microscopy (TEM) specimens, and backside-ion milling combined with focused ion beam (FIB) operation for electron holography were introduced in this paper. The backside Ar ion milling technique offers advantages in preparing cross-sectional specimens having thin, smooth and uniform surfaces with low surface damages. The back-side ion milling combined with the FIB technique could be used to observe the two-dimensional p-n junction profiles in semiconductors with the sample quality sufficient for an electron holography study. These techniques have useful applications for accurate TEM analysis of the microstructure of materials or electronic devices such as arrayed hole patterns, three-dimensional integrated circuits, and also relatively thick layers (> $1{\mu}m$).

Focused Ion Beam Milling for Nanostencil Lithography (나노스텐실 제작을 위한 집속이온빔 밀링 특성)

  • Kim, Gyu-Man
    • Journal of the Korean Society for Precision Engineering
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    • v.28 no.2
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    • pp.245-250
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    • 2011
  • A high-resolution shadow mask, a nanostencil, is widely used for high resolution lithography. This high-resolution shadowmask is often fabricated by a combination of MEMS processes and focused ion beam (FIB) milling. In this study, FIB milling on 500-nm-thin SiN membrane was tested and characterized. 500 nm thick and $2{\times}2$ mm large membranes were made on a silicon wafer by micro-fabrication processes of LPCVD, photolithography, ICP etching and bulk silicon etching. A subsequent FIB milling enabled local membrane thinning and aperture making into the thinned silicon nitride membrane. Due to the high resolution of the FIB milling process, nanoscale apertures down to 60 nm could be made into the membrane. The nanostencil could be used for nanoscale patterning by local deposition through the apertures.

Optimization of TEM Sample Preparation for the Microstructural Analysis of Nitride Semiconductors (질화물 반도체의 미세구조 분석을 위한 최적의 TEM 시편 준비법)

  • Cho, Hyung-Koun;Kim, Dong-Chan
    • Korean Journal of Materials Research
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    • v.13 no.9
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    • pp.598-605
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    • 2003
  • The optimized conditions for the cross-sectional TEM sample preparation using tripod polisher and ion-beam miller was confirmed by AFM and TEM. For the TEM observation of interfaces including InGaN layers like InGaN/GaN MQW structures, the sample preparation by the only tripod polishing was useful due to the reduction of artifacts. On the other hand, in case of the thick nitride films like ELO, PE, and superlattice, both tripod polishing and controlled ion-beam milling were required to improve the reproducibility. As a result, the ion-beam milling with the $60^{\circ}$modulation showed the minimum height difference between film and sapphire interface and the ion-beam milling of the $80^{\circ}$modulation showed the broad observable width.

Fabrication of a Nano Pattern Using Focused Ion Beam (집속이온빔을 이용한 나노 패턴 형성)

  • Han J.;Min B.K.;Lee S.J.;Park C.W.;Lee J.H.
    • Proceedings of the Korean Society of Precision Engineering Conference
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    • 2005.06a
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    • pp.1531-1534
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    • 2005
  • Nano pattern is being utilized to produce micro optical components, sensors, and information storage devices. In this study, a study on nano pattern fabrication using raster-scan type Focused Ion Beam (FIB) milling is introduced. Because the intensity of ion beam has Gaussian distribution, the overlapping of the Gaussian beam results in a 3D pattern, and the shape of the pattern can be adjusted by variation of FIB milling parameters, such as overlap, ion dose, and dwell time. The Gaussian shape of single beam intensity has been investigated by experiment, and 3D nano patterns with pitch of 200nm generated by FIB is demonstrated.

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Method of Ga removal from a specimen on a microelectromechanical system-based chip for in-situ transmission electron microscopy

  • Yena Kwon;Byeong-Seon An;Yeon-Ju Shin;Cheol-Woong Yang
    • Applied Microscopy
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    • v.50
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    • pp.22.1-22.6
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    • 2020
  • In-situ transmission electron microscopy (TEM) holders that employ a chip-type specimen stage have been widely utilized in recent years. The specimen on the microelectromechanical system (MEMS)-based chip is commonly prepared by focused ion beam (FIB) milling and ex-situ lift-out (EXLO). However, the FIB-milled thin-foil specimens are inevitably contaminated with Ga+ ions. When these specimens are heated for real time observation, the Ga+ ions influence the reaction or aggregate in the protection layer. An effective method of removing the Ga residue by Ar+ ion milling within FIB system was explored in this study. However, the Ga residue remained in the thin-foil specimen that was extracted by EXLO from the trench after the conduct of Ar+ ion milling. To address this drawback, the thin-foil specimen was attached to an FIB lift-out grid, subjected to Ar+ ion milling, and subsequently transferred to an MEMS-based chip by EXLO. The removal of the Ga residue was confirmed by energy dispersive spectroscopy.

Optimal Determination of the Fabrication Parameters in Focused Ion Beam for Milling Gold Nano Hole Array (금 나노홀 어레이 제작을 위한 집속 이온빔의 공정 최적화)

  • Cho, Eun Byurl;Kwon, Hee Min;Lee, Hee Sun;Yeo, Jong-Souk
    • Journal of the Korean Vacuum Society
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    • v.22 no.5
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    • pp.262-269
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    • 2013
  • Though focused ion beam (FIB) is one of the candidates to fabricate the nanoscale patterns, precision milling of nanoscale structures is not straightforward. Thus this poses challenges for novice FIB users. Optimal determination in FIB parameters is a crucial step to fabricate a desired nanoscale pattern. There are two main FIB parameters to consider, beam current (beam size) and dose (beam duration) for optimizing the milling condition. After fixing the dose, the proper beam current can be chosen considering both total milling time and resolution of the pattern. Then, using the chosen beam current, the metal nano hole structure can be perforated to the required depth by varying the dose. In this experiment, we found the adequate condition of $0.1nC/{\mu}m^2$ dose at 1 pA Ga ion beam current for 100 nm thickness perforation. With this condition, we perforated the periodic square array of elliptical nano holes.

The Parametric Influence on Focused Ion Beam Processing of Silicon (집속이온빔의 공정조건이 실리콘 가공에 미치는 영향)

  • Kim, Joon-Hyun;Song, Chun-Sam;Kim, Jong-Hyeong;Jang, Dong-Young;Kim, Joo-Hyun
    • Transactions of the Korean Society of Machine Tool Engineers
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    • v.16 no.2
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    • pp.70-77
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    • 2007
  • The application of focused ion beam(FIB) technology has been broadened in the fabrication of nanoscale regime. The extended application of FIB is dependent on complicated reciprocal relation of operating parameters. It is necessary for successful and efficient modifications on the surface of silicon substrate. The primary effect by Gaussian beam intensity is significantly shown from various aperture size, accelerating voltage, and beam current. Also, the secondary effect of other process factors - dwell time, pixel interval, scan mode, and pattern size has affected to etching results. For the process analysis, influence of the secondary factors on FIB micromilling process is examined with respect to sputtering depth during the milling process in silicon material. The results are analyzed by the ratio of signal to noise obtained using design of experiment in each parameter.

'AMADEUS' Software for ion Beam Nano Patterning and Characteristics of Nano Fabrication ('아마데우스' 이온빔 나노 패터닝 소프트웨어와 나노 가공 특성)

  • Kim H.B.;Hobler G.;Lugstein A.;Bertagonolli E.
    • Proceedings of the Korean Society of Precision Engineering Conference
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    • 2005.10a
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    • pp.322-325
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    • 2005
  • The shrinking critical dimensions of modern technology place a heavy requirement on optimizing feature shapes at the micro- and nano scale. In addition, the use of ion beams in the nano-scale world is greatly increased by technology development. Especially, Focused ion Beam (FIB) has a great potential to fabricate the device in nano-scale. Nevertheless, FIB has several limitations, surface swelling in low ion dose regime, precipitation of incident ions, and the re-deposition effect due to the sputtered atoms. In recent years, many approaches and research results show that the re-deposition effect is the most outstanding effect to overcome or reduce in fabrication of micro and nano devices. A 2D string based simulation software AMADEUS-2D $(\underline{A}dvanced\;\underline{M}odeling\;and\;\underline{D}esign\;\underline{E}nvironment\;for\;\underline{S}putter\;Processes)$ for ion milling and FIB direct fabrication has been developed. It is capable of simulating ion beam sputtering and re-deposition. In this paper, the 2D FIB simulation is demonstrated and the characteristics of ion beam induced direct fabrication is analyzed according to various parameters. Several examples, single pixel, multi scan box region, and re-deposited sidewall formation, are given.

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