Your search keyword '"Isotropic etch"' showing total 8 results

1. Plasma Etch Equipment

Author

Pu, Yuan, Wang, Yangyuan, editor, Chi, Min-Hwa, editor, Lou, Jesse Jen-Chung, editor, and Chen, Chun-Zhang, editor

Published

2024

2. Fabrication of High-Density Out-of-Plane Microneedle Arrays with Various Heights and Diverse Cross-Sectional Shapes

Author

Hyeonhee Roh, Young Jun Yoon, Jin Soo Park, Dong-Hyun Kang, Seung Min Kwak, Byung Chul Lee, and Maesoon Im

Subjects

Microneedle, Various heights, Cross-sectional shapes, Isotropic etch, Deep reactive ion etching, Technology

Abstract

Abstract Out-of-plane microneedle structures are widely used in various applications such as transcutaneous drug delivery and neural signal recording for brain machine interface. This work presents a novel but simple method to fabricate high-density silicon (Si) microneedle arrays with various heights and diverse cross-sectional shapes depending on photomask pattern designs. The proposed fabrication method is composed of a single photolithography and two subsequent deep reactive ion etching (DRIE) steps. First, a photoresist layer was patterned on a Si substrate to define areas to be etched, which will eventually determine the final location and shape of each individual microneedle. Then, the 1st DRIE step created deep trenches with a highly anisotropic etching of the Si substrate. Subsequently, the photoresist was removed for more isotropic etching; the 2nd DRIE isolated and sharpened microneedles from the predefined trench structures. Depending on diverse photomask designs, the 2nd DRIE formed arrays of microneedles that have various height distributions, as well as diverse cross-sectional shapes across the substrate. With these simple steps, high-aspect ratio microneedles were created in the high density of up to 625 microneedles mm−2 on a Si wafer. Insertion tests showed a small force as low as ~ 172 µN/microneedle is required for microneedle arrays to penetrate the dura mater of a mouse brain. To demonstrate a feasibility of drug delivery application, we also implemented silk microneedle arrays using molding processes. The fabrication method of the present study is expected to be broadly applicable to create microneedle structures for drug delivery, neuroprosthetic devices, and so on.

Published

2021

3. Formation Mechanism of Rounded SiGe-Etch Front in Isotropic SiGe Plasma Etching for Gate-All-Around FETs

Author

Yu Zhao, Taku Iwase, Makoto Satake, and Hirotaka Hamamura

Subjects

Etch front, GAA-FET, isotropic etch, dry etch, selective SiGe etch, Electrical engineering. Electronics. Nuclear engineering, TK1-9971

Abstract

We investigated the formation mechanism of a rounded silicon-germanium (SiGe)-etch front (rounding) in gate-all-around field-effect transistor (GAA-FET) manufacturing. This rounding is created by the isotropic etching of the SiGe layer after anisotropic etching of the SiGe/Si stack, which degrades device characteristics. The etch-time dependence of the rounding amount during isotropic SiGe etching with nitrogen trifluoride plasma indicates that rounding is mainly formed in an initial stage of SiGe etching, namely, etch time less than 15 s. Cross-sectional scanning transmission electron microscopy and energy dispersive x-ray spectroscopy (STEM EDX) measurement indicated that a Ge-containing layer formed on the sidewall of SiGe/Si patterns before isotropic SiGe etching. From these results, we propose a formation model of SiGe rounding below. The Ge composition in the Ge-containing layer has a gradient due to ion-assisted Ge diffusion during anisotropic etching of the SiGe/Si stack. This gradient induces rounding during isotropic SiGe etching because the etch rate of the SiGe layer decreases as the Ge composition decreases. To validate our model, the Ge-containing layer after anisotropic etching was removed by post-etch treatment and the Ge spectra on the sidewall was reduced to the detection limit of STEM EDX. As a result, the rounding amount after isotropic SiGe etching improved from 2.7 to 1.8 nm. This reduction indicates that the formation of the Ge-containing layer during anisotropic etching of the SiGe/Si stack is one of the main causes of rounding after isotropic SiGe etching.

Published

2021

4. Fabrication of High-Density Out-of-Plane Microneedle Arrays with Various Heights and Diverse Cross-Sectional Shapes.

Author

Roh, Hyeonhee, Yoon, Young Jun, Park, Jin Soo, Kang, Dong-Hyun, Kwak, Seung Min, Lee, Byung Chul, and Im, Maesoon

Subjects

*DURA mater, *SCANNING electron microscopy, *PHOTOLITHOGRAPHY

Abstract

Highlights: High-density out-of-plane microneedle arrays were fabricated with a single photolithography and two deep reactive ion etching (DRIE) steps in anisotropic and isotropic modes, respectively. Microneedles in various heights were monolithically created by the identical DRIE processes and scanning electron microscopy images showed extremely sharp sub-micron (~145-nm-wide) tip. Diverse cross-sectional shapes of microneedles were implemented by altering photomask patterns. Out-of-plane microneedle structures are widely used in various applications such as transcutaneous drug delivery and neural signal recording for brain machine interface. This work presents a novel but simple method to fabricate high-density silicon (Si) microneedle arrays with various heights and diverse cross-sectional shapes depending on photomask pattern designs. The proposed fabrication method is composed of a single photolithography and two subsequent deep reactive ion etching (DRIE) steps. First, a photoresist layer was patterned on a Si substrate to define areas to be etched, which will eventually determine the final location and shape of each individual microneedle. Then, the 1st DRIE step created deep trenches with a highly anisotropic etching of the Si substrate. Subsequently, the photoresist was removed for more isotropic etching; the 2nd DRIE isolated and sharpened microneedles from the predefined trench structures. Depending on diverse photomask designs, the 2nd DRIE formed arrays of microneedles that have various height distributions, as well as diverse cross-sectional shapes across the substrate. With these simple steps, high-aspect ratio microneedles were created in the high density of up to 625 microneedles mm−2 on a Si wafer. Insertion tests showed a small force as low as ~ 172 µN/microneedle is required for microneedle arrays to penetrate the dura mater of a mouse brain. To demonstrate a feasibility of drug delivery application, we also implemented silk microneedle arrays using molding processes. The fabrication method of the present study is expected to be broadly applicable to create microneedle structures for drug delivery, neuroprosthetic devices, and so on. [ABSTRACT FROM AUTHOR]

Published

2022

5. 69‐1: Etch Properties of Silicon Nitride Films Using a New In‐Line Equipment with Atmospheric Glow Plasma for the OLED Flexible Display.

Author

Park, Jang-Sick, Heo, Yoon-Suk, Kang, Bang-Kwon, You, Byoung-Gon, and SeongWook, Yoo

Subjects

SILICON nitride films, SILICON nitride, ATMOSPHERIC pressure, FLEXIBLE display systems, CHEMICAL energy, ETCHING

Abstract

DBD non‐thermal atmospheric pressure plasma (NAPP) is suitable for the OLED display manufacturing process using flexible substrate because it is low‐temperature atmospheric pressure process, low cost process and does not need a vacuum system. High dynamic etch rate of 220À·cm/s in Si3N4 thin films was obtained in flow rate ratio (O2/CF4) of 0.13, rf 480W, the speed of 10mm/s in a 200mm new inline NAPP system. About 5% increase of dynamic etch rate by N2 gas injection was conformed. Etch profile of Si3N4 film with patterned PR shows perfectly isotropic without undercut because the species such as CF3, COF2, F and O have low energy and chemical reaction. [ABSTRACT FROM AUTHOR]

Published

2019

6. Fabrication of High-Density Out-of-Plane Microneedle Arrays with Various Heights and Diverse Cross-Sectional Shapes

Author

Roh, Hyeonhee, Yoon, Young Jun, Park, Jin Soo, Kang, Dong-Hyun, Kwak, Seung Min, Lee, Byung Chul, and Im, Maesoon

Subjects

Technology, Various heights, Isotropic etch, Deep reactive ion etching, Microneedle, Electrical and Electronic Engineering, Article, Cross-sectional shapes, Surfaces, Coatings and Films, Electronic, Optical and Magnetic Materials

Abstract

High-density out-of-plane microneedle arrays were fabricated with a single photolithography and two deep reactive ion etching (DRIE) steps in anisotropic and isotropic modes, respectively.Microneedles in various heights were monolithically created by the identical DRIE processes and scanning electron microscopy images showed extremely sharp sub-micron (~145-nm-wide) tip.Diverse cross-sectional shapes of microneedles were implemented by altering photomask patterns., Out-of-plane microneedle structures are widely used in various applications such as transcutaneous drug delivery and neural signal recording for brain machine interface. This work presents a novel but simple method to fabricate high-density silicon (Si) microneedle arrays with various heights and diverse cross-sectional shapes depending on photomask pattern designs. The proposed fabrication method is composed of a single photolithography and two subsequent deep reactive ion etching (DRIE) steps. First, a photoresist layer was patterned on a Si substrate to define areas to be etched, which will eventually determine the final location and shape of each individual microneedle. Then, the 1st DRIE step created deep trenches with a highly anisotropic etching of the Si substrate. Subsequently, the photoresist was removed for more isotropic etching; the 2nd DRIE isolated and sharpened microneedles from the predefined trench structures. Depending on diverse photomask designs, the 2nd DRIE formed arrays of microneedles that have various height distributions, as well as diverse cross-sectional shapes across the substrate. With these simple steps, high-aspect ratio microneedles were created in the high density of up to 625 microneedles mm−2 on a Si wafer. Insertion tests showed a small force as low as ~ 172 µN/microneedle is required for microneedle arrays to penetrate the dura mater of a mouse brain. To demonstrate a feasibility of drug delivery application, we also implemented silk microneedle arrays using molding processes. The fabrication method of the present study is expected to be broadly applicable to create microneedle structures for drug delivery, neuroprosthetic devices, and so on.

Published

2021

7. Formation Mechanism of Rounded SiGe-Etch Front in Isotropic SiGe Plasma Etching for Gate-All-Around FETs

Author

Hirotaka Hamamura, Taku Iwase, Zhao Yu, and Makoto Satake

Subjects

Plasma etching, Materials science, business.industry, fungi, Isotropy, technology, industry, and agriculture, GAA-FET, Front (oceanography), dry etch, macromolecular substances, TK1-9971, Electronic, Optical and Magnetic Materials, Mechanism (engineering), selective SiGe etch, stomatognathic system, Etch front, Optoelectronics, Electrical engineering. Electronics. Nuclear engineering, Electrical and Electronic Engineering, business, isotropic etch, Biotechnology

Abstract

We investigated the formation mechanism of a rounded silicon-germanium (SiGe)-etch front (rounding) in gate-all-around field-effect transistor (GAA-FET) manufacturing. This rounding is created by the isotropic etching of the SiGe layer after anisotropic etching of the SiGe/Si stack, which degrades device characteristics. The etch-time dependence of the rounding amount during isotropic SiGe etching with nitrogen trifluoride plasma indicates that rounding is mainly formed in an initial stage of SiGe etching, namely, etch time less than 15 s. Cross-sectional scanning transmission electron microscopy and energy dispersive x-ray spectroscopy (STEM EDX) measurement indicated that a Ge-containing layer formed on the sidewall of SiGe/Si patterns before isotropic SiGe etching. From these results, we propose a formation model of SiGe rounding below. The Ge composition in the Ge-containing layer has a gradient due to ion-assisted Ge diffusion during anisotropic etching of the SiGe/Si stack. This gradient induces rounding during isotropic SiGe etching because the etch rate of the SiGe layer decreases as the Ge composition decreases. To validate our model, the Ge-containing layer after anisotropic etching was removed by post-etch treatment and the Ge spectra on the sidewall was reduced to the detection limit of STEM EDX. As a result, the rounding amount after isotropic SiGe etching improved from 2.7 to 1.8 nm. This reduction indicates that the formation of the Ge-containing layer during anisotropic etching of the SiGe/Si stack is one of the main causes of rounding after isotropic SiGe etching.

Published

2021

8. Development and Characterization of Tapered Silicon Etch Process by Topography Modeling for TSV Application.

Author

Ranganathan, N., Malar, A., Lee, D. Y., Prasad, K., and Pey, K. L.

Subjects

*SEMICONDUCTOR etching, *MANUFACTURING processes, *MODELS & modelmaking, *SWITCHING theory, *SIMULATION methods & models, *RELIABILITY (Personality trait), *SIMULATION software

Abstract

A dual-etch via tapering technology has been presented which combines Bosch process and isotropic etch process. It has been shown that the dual-etch process technology provides a high degree of process flexibility to the user by independently controlling and optimizing the etch rate and profile tapering process. Based on experimental work, RIE process models have been set up using ELITE simulation software from Silvaco. Detailed DOE has been done to optimize the RIE models so that the experimental and simulation results match over a wide range of via geometries and aspect ratios. The optimized models have been further used to predict the aspect ratio induced RIE lag effects. [ABSTRACT FROM AUTHOR]

Published

2010