Your search keyword '"Deep Reactive Ion Etching"' showing total 13 results

1. Fabrication of X-ray Gratings for Interferometric Imaging by Conformal Seedless Gold Electroplating

Author

Konstantins Jefimovs, Joan Vila-Comamala, Carolina Arboleda, Zhentian Wang, Lucia Romano, Zhitian Shi, Matias Kagias, and Marco Stampanoni

Subjects

X-ray interferometry, phase contrast imaging, grating, high aspect ratio, deep reactive ion etching, Bosch process, Mechanical engineering and machinery, TJ1-1570

Abstract

We present a method to produce small pitch gratings for X-ray interferometric imaging applications, allowing the phase sensitivity to be increased and/or the length of the laboratory setup to be minimized. The method is based on fabrication of high aspect ratio silicon microstructures using deep reactive ion etching (Bosch technique) of dense grating arrays and followed by conformal electroplating of Au. We demonstrated that low resistivity Si substrates (

Published

2021

2. Reduced Etch Lag and High Aspect Ratios by Deep Reactive Ion Etching (DRIE)

Author

Michael S. Gerlt, Nino F. Läubli, Michel Manser, Bradley J. Nelson, and Jürg Dual

Subjects

fabrication, deep reactive ion etching, process optimization, reduced etch lag, high aspect ratio, small structures, Mechanical engineering and machinery, TJ1-1570

Abstract

Deep reactive ion etching (DRIE) with the Bosch process is one of the key procedures used to manufacture micron-sized structures for MEMS and microfluidic applications in silicon and, hence, of increasing importance for miniaturisation in biomedical research. While guaranteeing high aspect ratio structures and providing high design flexibility, the etching procedure suffers from reactive ion etching lag and often relies on complex oxide masks to enable deep etching. The reactive ion etching lag, leading to reduced etch depths for features exceeding an aspect ratio of 1:1, typically causes a height difference of above 10% for structures with aspect ratios ranging from 2.5:1 to 10:1, and, therefore, can significantly influence subsequent device functionality. In this work, we introduce an optimised two-step Bosch process that reduces the etch lag to below 1.5%. Furthermore, we demonstrate an improved three-step Bosch process, allowing the fabrication of structures with 6 μm width at depths up to 180 μm while maintaining their stability.

Published

2021

3. Metasurface Fabrication by Cryogenic and Bosch Deep Reactive Ion Etching

Author

Angela M. Baracu, Christopher A. Dirdal, Andrei M. Avram, Adrian Dinescu, Raluca Muller, Geir Uri Jensen, Paul Conrad Vaagen Thrane, and Hallvard Angelskår

Subjects

metasurface fabrication, cryogenic etching, bosch process, deep reactive ion etching, Mechanical engineering and machinery, TJ1-1570

Abstract

The research field of metasurfaces has attracted considerable attention in recent years due to its high potential to achieve flat, ultrathin optical devices of high performance. Metasurfaces, consisting of artificial patterns of subwavelength dimensions, often require fabrication techniques with high aspect ratios (HARs). Bosch and Cryogenic methods are the best etching candidates of industrial relevance towards the fabrication of these nanostructures. In this paper, we present the fabrication of Silicon (Si) metalenses by the UV-Nanoimprint Lithography method and cryogenic Deep Reactive Ion Etching (DRIE) process and compare the results with the same structures manufactured by Bosch DRIE both in terms of technological achievements and lens efficiencies. The Cryo- and Bosch-etched lenses attain efficiencies of around 39% at wavelength λ = 1.50 µm and λ = 1.45 µm against a theoretical level of around 61% (for Si pillars on a Si substrate), respectively, and process modifications are suggested towards raising the efficiencies further. Our results indicate that some sidewall surface roughness of the Bosch DRIE is acceptable in metalense fabrication, as even significant sidewall surface roughness in a non-optimized Bosch process yields reasonable efficiency levels.

Published

2021

4. Three-Dimensional Simulation of DRIE Process Based on the Narrow Band Level Set and Monte Carlo Method.

Author

Yu, Jia-Cheng, Zhou, Zai-Fa, Su, Jia-Le, Xia, Chang-Feng, Zhang, Xin-Wei, Wu, Zong-Ze, and Huang, Qing-An

Subjects

SEMICONDUCTOR etching, LEVEL set methods, MONTE Carlo method

Abstract

A three-dimensional topography simulation of deep reactive ion etching (DRIE) is developed based on the narrow band level set method for surface evolution and Monte Carlo method for flux distribution. The advanced level set method is implemented to simulate the time-related movements of etched surface. In the meanwhile, accelerated by ray tracing algorithm, the Monte Carlo method incorporates all dominant physical and chemical mechanisms such as ion-enhanced etching, ballistic transport, ion scattering, and sidewall passivation. The modified models of charged particles and neutral particles are epitomized to determine the contributions of etching rate. The effects such as scalloping effect and lag effect are investigated in simulations and experiments. Besides, the quantitative analyses are conducted to measure the simulation error. Finally, this simulator will be served as an accurate prediction tool for some MEMS fabrications. [ABSTRACT FROM AUTHOR]

Published

2018

5. Simple Stacking Methods for Silicon Micro Fuel Cells

Author

Gianmario Scotti, Petri Kanninen, Tanja Kallio, and Sami Franssila

Subjects

silicon, micro fuel cell, stacking, deep reactive ion etching, polymer electrolyte membrane, black silicon, Mechanical engineering and machinery, TJ1-1570

Abstract

We present two simple methods, with parallel and serial gas flows, for the stacking of microfabricated silicon fuel cells with integrated current collectors, flow fields and gas diffusion layers. The gas diffusion layer is implemented using black silicon. In the two stacking methods proposed in this work, the fluidic apertures and gas flow topology are rotationally symmetric and enable us to stack fuel cells without an increase in the number of electrical or fluidic ports or interconnects. Thanks to this simplicity and the structural compactness of each cell, the obtained stacks are very thin (~1.6 mm for a two-cell stack). We have fabricated two-cell stacks with two different gas flow topologies and obtained an open-circuit voltage (OCV) of 1.6 V and a power density of 63 mW·cm−2, proving the viability of the design.

Published

2014

6. Three-Dimensional Simulation of DRIE Process Based on the Narrow Band Level Set and Monte Carlo Method

Author

Jia-Cheng Yu, Zai-Fa Zhou, Jia-Le Su, Chang-Feng Xia, Xin-Wei Zhang, Zong-Ze Wu, and Qing-An Huang

Subjects

deep reactive ion etching, level set method, Monte Carlo simulation, ray tracing algorithm, surface evolution, Mechanical engineering and machinery, TJ1-1570

Abstract

A three-dimensional topography simulation of deep reactive ion etching (DRIE) is developed based on the narrow band level set method for surface evolution and Monte Carlo method for flux distribution. The advanced level set method is implemented to simulate the time-related movements of etched surface. In the meanwhile, accelerated by ray tracing algorithm, the Monte Carlo method incorporates all dominant physical and chemical mechanisms such as ion-enhanced etching, ballistic transport, ion scattering, and sidewall passivation. The modified models of charged particles and neutral particles are epitomized to determine the contributions of etching rate. The effects such as scalloping effect and lag effect are investigated in simulations and experiments. Besides, the quantitative analyses are conducted to measure the simulation error. Finally, this simulator will be served as an accurate prediction tool for some MEMS fabrications.

Published

2018

7. Reduced Etch Lag and High Aspect Ratios by Deep Reactive Ion Etching (DRIE)

Author

Gerlt, Michael S., Läubli, Nino, Manser, Michel, Nelson, Bradley J., and Dual, Jürg

Subjects

high aspect ratio, process optimization, TJ1-1570, fabrication, deep reactive ion etching, reduced etch lag, small structures, Mechanical engineering and machinery, Article

Abstract

Deep reactive ion etching (DRIE) with the Bosch process is one of the key procedures used to manufacture micron-sized structures for MEMS and microfluidic applications in silicon and, hence, of increasing importance for miniaturisation in biomedical research. While guaranteeing high aspect ratio structures and providing high design flexibility, the etching procedure suffers from reactive ion etching lag and often relies on complex oxide masks to enable deep etching. The reactive ion etching lag, leading to reduced etch depths for features exceeding an aspect ratio of 1:1, typically causes a height difference of above 10% for structures with aspect ratios ranging from 2.5:1 to 10:1, and, therefore, can significantly influence subsequent device functionality. In this work, we introduce an optimised two-step Bosch process that reduces the etch lag to below 1.5%. Furthermore, we demonstrate an improved three-step Bosch process, allowing the fabrication of structures with 6 µm width at depths up to 180 µm while maintaining their stability., Micromachines, 12 (5), ISSN:2072-666X

Published

2021

8. Fabrication of X-ray Gratings for Interferometric Imaging by Conformal Seedless Gold Electroplating

Author

Joan Vila-Comamala, Marco Stampanoni, Carolina Arboleda, Zhitian Shi, Matias Kagias, Konstantins Jefimovs, Zhentian Wang, and Lucia Romano

Subjects

seedless electroplating, Materials science, Fabrication, Silicon, X-ray interferometry, Phase contrast imaging, Grating, High aspect ratio, Deep reactive ion etching, Bosch process, Gold, Seedless electroplating, Visibility, chemistry.chemical_element, 02 engineering and technology, 01 natural sciences, Article, grating, Etching (microfabrication), 0103 physical sciences, TJ1-1570, Deep reactive-ion etching, Wafer, Mechanical engineering and machinery, Electrical and Electronic Engineering, Electroplating, deep reactive ion etching, 010302 applied physics, business.industry, Mechanical Engineering, silicon, visibility, gold, 021001 nanoscience & nanotechnology, Computer Science::Other, chemistry, high aspect ratio, Control and Systems Engineering, Optoelectronics, 0210 nano-technology, business, Layer (electronics), phase contrast imaging

Abstract

We present a method to produce small pitch gratings for X-ray interferometric imaging applications, allowing the phase sensitivity to be increased and/or the length of the laboratory setup to be minimized. The method is based on fabrication of high aspect ratio silicon microstructures using deep reactive ion etching (Bosch technique) of dense grating arrays and followed by conformal electroplating of Au. We demonstrated that low resistivity Si substrates (, Micromachines, 12 (5), ISSN:2072-666X

Published

2021

9. Simple Stacking Methods for Silicon Micro Fuel Cells.

Author

Scotti, Gianmario, Kanninen, Petri, Kallio, Tanja, and Franssila, Sami

Subjects

FUEL cells, SILICON, GAS flow, ELECTRIC potential, DENSITY

Abstract

We present two simple methods, with parallel and serial gas flows, for the stacking of microfabricated silicon fuel cells with integrated current collectors, flow fields and gas diffusion layers. The gas diffusion layer is implemented using black silicon. In the two stacking methods proposed in this work, the fluidic apertures and gas flow topology are rotationally symmetric and enable us to stack fuel cells without an increase in the number of electrical or fluidic ports or interconnects. Thanks to this simplicity and the structural compactness of each cell, the obtained stacks are very thin (~1.6 mm for a two-cell stack). We have fabricated two-cell stacks with two different gas flow topologies and obtained an open-circuit voltage (OCV) of 1.6 V and a power density of 63 mWcnT2, proving the viability of the design. [ABSTRACT FROM AUTHOR]

Published

2014

10. Metasurface Fabrication by Cryogenic and Bosch Deep Reactive Ion Etching

Author

Adrian Dinescu, Angela Baracu, Hallvard Angelskår, Raluca Muller, Christopher A. Dirdal, Paul Conrad Vaagen Thrane, Andrei Avram, and Geir Uri Jensen

Subjects

bosch process, Materials science, Fabrication, Nanostructure, Silicon, Deep reactive ion etching, chemistry.chemical_element, 02 engineering and technology, 01 natural sciences, Article, law.invention, 010309 optics, law, Etching (microfabrication), 0103 physical sciences, TJ1-1570, Surface roughness, Cryogenic etching, Deep reactive-ion etching, Mechanical engineering and machinery, Electrical and Electronic Engineering, Metasurface fabrication, deep reactive ion etching, Lithography, Bosch process, cryogenic etching, business.industry, Mechanical Engineering, metasurface fabrication, 021001 nanoscience & nanotechnology, Lens (optics), chemistry, Control and Systems Engineering, Optoelectronics, 0210 nano-technology, business

Abstract

The research field of metasurfaces has attracted considerable attention in recent years due to its high potential to achieve flat, ultrathin optical devices of high performance. Metasurfaces, consisting of artificial patterns of subwavelength dimensions, often require fabrication techniques with high aspect ratios (HARs). Bosch and Cryogenic methods are the best etching candidates of industrial relevance towards the fabrication of these nanostructures. In this paper, we present the fabrication of Silicon (Si) metalenses by the UV-Nanoimprint Lithography method and cryogenic Deep Reactive Ion Etching (DRIE) process and compare the results with the same structures manufactured by Bosch DRIE both in terms of technological achievements and lens efficiencies. The Cryo- and Bosch-etched lenses attain efficiencies of around 39% at wavelength λ = 1.50 µm and λ = 1.45 µm against a theoretical level of around 61% (for Si pillars on a Si substrate), respectively, and process modifications are suggested towards raising the efficiencies further. Our results indicate that some sidewall surface roughness of the Bosch DRIE is acceptable in metalense fabrication, as even significant sidewall surface roughness in a non-optimized Bosch process yields reasonable efficiency levels.

Published

2021

11. Three-Dimensional Simulation of DRIE Process Based on the Narrow Band Level Set and Monte Carlo Method

Author

Su Jiale, Changfeng Xia, Jia-Cheng Yu, Zai-Fa Zhou, Xinwei Zhang, Qing-An Huang, and Zong-Ze Wu

Subjects

Level set method, Materials science, lcsh:Mechanical engineering and machinery, Monte Carlo method, 02 engineering and technology, 01 natural sciences, Article, surface evolution, Ballistic conduction, 0103 physical sciences, ray tracing algorithm, Deep reactive-ion etching, lcsh:TJ1-1570, Electrical and Electronic Engineering, deep reactive ion etching, Monte Carlo simulation, 010302 applied physics, Microelectromechanical systems, Scattering, Mechanical Engineering, 021001 nanoscience & nanotechnology, level set method, Charged particle, Computational physics, Computer Science::Other, Control and Systems Engineering, Ray tracing (graphics), 0210 nano-technology

Abstract

A three-dimensional topography simulation of deep reactive ion etching (DRIE) is developed based on the narrow band level set method for surface evolution and Monte Carlo method for flux distribution. The advanced level set method is implemented to simulate the time-related movements of etched surface. In the meanwhile, accelerated by ray tracing algorithm, the Monte Carlo method incorporates all dominant physical and chemical mechanisms such as ion-enhanced etching, ballistic transport, ion scattering, and sidewall passivation. The modified models of charged particles and neutral particles are epitomized to determine the contributions of etching rate. The effects such as scalloping effect and lag effect are investigated in simulations and experiments. Besides, the quantitative analyses are conducted to measure the simulation error. Finally, this simulator will be served as an accurate prediction tool for some MEMS fabrications.

Published

2018

12. Fabrication of X-ray Gratings for Interferometric Imaging by Conformal Seedless Gold Electroplating.

Author

Jefimovs, Konstantins, Vila-Comamala, Joan, Arboleda, Carolina, Wang, Zhentian, Romano, Lucia, Shi, Zhitian, Kagias, Matias, Stampanoni, Marco, and Mohseni, Parsian K.

Subjects

ELECTROPLATING, X-rays, X-ray imaging, GOLD, GOLD nanoparticles

Abstract

We present a method to produce small pitch gratings for X-ray interferometric imaging applications, allowing the phase sensitivity to be increased and/or the length of the laboratory setup to be minimized. The method is based on fabrication of high aspect ratio silicon microstructures using deep reactive ion etching (Bosch technique) of dense grating arrays and followed by conformal electroplating of Au. We demonstrated that low resistivity Si substrates (<0.01 Ohm·cm) enable the metal seeding layer deposition step to be avoided, which is normally required to initiate the electroplating process. Etching conditions were optimized to realize Si recess structures with a slight bottom tapering, which ensured the void-free Au filling of the trenches. Vapor HF was used to remove the native oxide layer from the Si grating surface prior to electroplating in the cyanide-based Au electrolyte. Fabrication of Au gratings with pitch in the range 1.2–3.0 µm was successfully realized. A substantial improved aspect ratio of 45:1 for a pitch size of 1.2 µm was achieved with respect to the prior art on 4-inch wafer-based technology. The fabricated Au gratings were tested with X-ray interferometers in Talbot–Laue configuration with measured visibility of 13% at an X-ray design energy of 26 keV. [ABSTRACT FROM AUTHOR]

Published

2021

13. Metasurface Fabrication by Cryogenic and Bosch Deep Reactive Ion Etching.

Author

Baracu, Angela M., Dirdal, Christopher A., Avram, Andrei M., Dinescu, Adrian, Muller, Raluca, Jensen, Geir Uri, Thrane, Paul Conrad Vaagen, Angelskår, Hallvard, and Romano, Lucia

Subjects

SILICON solar cells, ETCHING, CHEMICAL milling, SURFACE roughness, OPTICAL devices, IONS

Abstract

The research field of metasurfaces has attracted considerable attention in recent years due to its high potential to achieve flat, ultrathin optical devices of high performance. Metasurfaces, consisting of artificial patterns of subwavelength dimensions, often require fabrication techniques with high aspect ratios (HARs). Bosch and Cryogenic methods are the best etching candidates of industrial relevance towards the fabrication of these nanostructures. In this paper, we present the fabrication of Silicon (Si) metalenses by the UV-Nanoimprint Lithography method and cryogenic Deep Reactive Ion Etching (DRIE) process and compare the results with the same structures manufactured by Bosch DRIE both in terms of technological achievements and lens efficiencies. The Cryo- and Bosch-etched lenses attain efficiencies of around 39% at wavelength λ = 1.50 µm and λ = 1.45 µm against a theoretical level of around 61% (for Si pillars on a Si substrate), respectively, and process modifications are suggested towards raising the efficiencies further. Our results indicate that some sidewall surface roughness of the Bosch DRIE is acceptable in metalense fabrication, as even significant sidewall surface roughness in a non-optimized Bosch process yields reasonable efficiency levels. [ABSTRACT FROM AUTHOR]

Published

2021