Your search keyword '"plasma chemical etching"' showing total 13 results

1. Silicon Nanowire-Based Room-Temperature Multi-environment Ammonia Detection.

Author

Kondratev, Valeriy M., Morozov, Ivan A., Vyacheslavova, Ekaterina A., Kirilenko, Demid A., Kuznetsov, Alexey, Kadinskaya, Svetlana A., Nalimova, Svetlana S., Moshnikov, Vyacheslav A., Gudovskikh, Alexander S., and Bolshakov, Alexey D.

Abstract

Nanowires represent numerous opportunities for nanoelectronics and sensorics, while metal contact fabrication makes the device development rather challenging. Here, we demonstrate that silicon (Si) nanowires deposited on interdigital metal contacts via simple drop casting exhibit an abrupt increase in conductivity upon exposure to ammonia vapors and aqueous solutions due to adsorption of the analyte species. To reduce the noise of the DC resistance measurements lacking ohmic conductivity, we exploit electronic impedance spectroscopy. The resistive response is found to be dependent on the ammonia content in vapor and liquid matter. The results demonstrate a detection limit of 4 μmol·L–1 (80 ppb), a sensitivity of 0.2% μmol–1·l (0.01%·ppb–1), and applicability for the low-concentration detection of up to 400 μmol·L–1 (8 ppm) ammonia in aqueous solutions both directly and indirectly with a response rate of up to 0.43%·s–1 and a recovery rate of 0.31%·s–1 and show selectivity to oxidizing species. Thus, we demonstrate that the use of semiconductor nanowires in adsorption sensorics does not require the fabrication of ohmic contacts and present a simple fabrication protocol perspective for the development of highly sensitive room-temperature multi-environment sensors. [ABSTRACT FROM AUTHOR]

Published

2022

2. A Modernized Bosch Etching Process for the Formation of Tapered Structures on a Silicon Surface.

Author

Rudy, A. S., Morozov, O. V., and Kurbatov, S. V.

Abstract

A method to form tapered structures via the cyclic plasma-chemical etching of silicon using a spherical photoresist mask is described. The method is based on the possibility of controlling the structure profile by adjusting the silicon and photoresist etching selectivity. In this study, to control the selectivity value, each cycle of the well-known two-stage Bosch silicon etching process is supplemented with a third stage, namely, photoresist etching in oxygen-containing plasma. A model of transformation of the photoresist-mask contour during etching is developed using the experimental results. The parameters of the additional stage are calculated for each silicon etching cycle in terms of model concepts. The result is the formation of tapered structures with a sidewall taper angle close to the target value. [ABSTRACT FROM AUTHOR]

Published

2021

3. Effect of Cryogenic Dry Etching on Minority Charge Carrier Lifetime in Silicon.

Author

Kudryashov, Dmitry A., Gudovskikh, Alexander S., Baranov, Artem I., Morozov, Ivan A., and Monastyrenko, Anatoly O.

Subjects

*CHARGE carrier lifetime, *PLASMA etching, *NANOSILICON, *SOLAR cells, *SILICON, *NANOFABRICATION, *OPEN-circuit voltage

Abstract

Micro‐ and nanostructured silicon surface application is a promising way of photovoltaic development. An enhancement of optical absorption in solar cells can be achieved, for example, using vertically aligned silicon nanostructures with high aspect ratios. Cryogenic plasma etching is a suitable method for such structures' formation; however, there is still lack of data describing an effect of cryogenic inductively coupled plasma (ICP) etching on defect formation in silicon (Si). The defects may act as recombination centers, leading to solar cell characteristics degradation. Herein, the cryogenic dry etching effects on defect formation in float‐zone (FZ) n‐type silicon substrates and on the photovoltaic properties of solar cells made of plasma‐etched silicon substrate are presented. The decrease in low‐injection minority carrier lifetime in silicon from 0.85 to 0.55 ms is observed by photoluminescence decay after the ICP dry etching at −140 °C. This leads to an open‐circuit voltage drop for the (p)a‐Si:H/(n)c‐Si/(n)a‐Si:H heterojunction structure from 680 to 630 mV. A detailed study of the defect properties by deep‐level transient spectroscopy (DLTS), numerical simulation, and its behavior after wet etching and thermal annealing is presented. [ABSTRACT FROM AUTHOR]

Published

2020

4. RESEARCH PROCESS PLASMA ETCHING SIO2 MEMBRANE

Author

T. A. Ismailov, P. R. Zakharova, B. A. Shangereeva, and A. R. Shakhmaeva

Subjects

substrate, ion-plasma treatment, plasma chemical etching, Technology

Abstract

The article discusses the results of plasma chemical etching of silicon dioxide in the fluorine-containing medium in the manufacture of semiconductor devices. Delivered and processed to obtain the solution of the smoothed microrelief contact windows in SiO2 other materials. The solution of the problem is closely connected with the problem of an isotropic plasma chemical etching, when the rate of lateral (horizontal) equal to the speed of the vertical etching, which allows to obtain smooth wall structures with maximum care dimensions on the border with photoresist or other masking coating.

Published

2016

5. Research of Constructive and Technological Methods for Forming a Silicon Disk Resonator with Whispering Gallery Modes

Author

Anastasia Yakuhina, Alexey Kadochkin, Vladimir Amelichev, Dmitry Gorelov, and Sergey Generalov

Subjects

whispering gallery mode, microresonator, silicon disk resonator, wedge-shaped profile, silicon-on-isolator, plasma chemical etching, Applied optics. Photonics, TA1501-1820

Abstract

This article presents the results of a computer simulation of whispering gallery modes in the structure of a silicon disk resonator with a wedge-shaped profile made on a silicon-on-isolator base (SOI). The rationale for the choice of silicon as a material for its manufacturing is given. The results of the study of the influence of the wedge angle on the whispering gallery mode parameters (WGM) are presented. The optimum wedge angle of a silicon disk resonator is determined, which ensures the minimum loss and maximum mode stability. The technological aspects of plasma-chemical etching processes for forming a wedge-shaped profile of the edge of a silicon disk resonator are studied.

Published

2020

6. Fabrication of Superconducting Nb–AlN–NbN Tunnel Junctions Using Electron-Beam Lithography

Author

Artem Chekushkin, Pavel N. Dmitriev, Lyudmila V. Filippenko, Valery P. Koshelets, and M. Fominsky

Subjects

Fabrication, Materials science, TK7800-8360, Computer Networks and Communications, Terahertz radiation, electron-beam lithography, negative electronic resists, plasma chemical etching, magnetron sputter deposition, superconducting tunnel structures, niobium-based high-quality tunnel junctions, Substrate (electronics), Noise (electronics), Electrical and Electronic Engineering, Lithography, Superconductivity, business.industry, Isotropic etching, Hardware and Architecture, Control and Systems Engineering, Signal Processing, Optoelectronics, Electronics, business, Electron-beam lithography

Abstract

Mixers based on superconductor–insulator–superconductor (SIS) tunnel junctions are the best input devices at frequencies from 0.1 to 1.2 THz. This is explained by both the extremely high nonlinearity of such elements and their extremely low intrinsic noise. Submicron tunnel junctions are necessary to realize the ultimate parameters of SIS receivers, which are used as standard devices on both ground and space radio telescopes around the world. The technology for manufacturing submicron Nb–AlN–NbN tunnel junctions using electron-beam lithography was developed and optimized. This article presents the results on the selection of the exposure dose, development time, and plasma chemical etching parameters to obtain high-quality junctions (the ratio of the resistances below and above the gap Rj/Rn). The use of a negative-resist ma-N 2400 with lower sensitivity and better contrast in comparison with a negative-resist UVN 2300-0.5 improved the reproducibility of the structure fabrication process. Submicron (area from 2.0 to 0.2 µm2) Nb–AlN–NbN tunnel junctions with high current densities and quality parameters Rj/Rn > 15 were fabricated. The spread of parameters of submicron tunnel structures across the substrate and the reproducibility of the cycle-to-cycle process of tunnel structure fabrication were measured.

Published

2021

7. Growth of Highly Aligned Vertical Si-Nanorods and Random Si-Nanowires by ICP-Plasma Chemical Etching of c-Si Wafers.

Author

Das, Debajyoti and Karmakar, Laxmikanta

Subjects

*SILICON nanowires, *CRYSTAL growth, *NANORODS, *PLASMA etching, *SILICON wafers

Abstract

Systematic development of both aligned silicon nanorods (Si-NR) and random silicon nanowires (Si-NW) are evident separately from the same plasma chemical etching of c-Si wafers at controllably different parameters of the (H2 + Ar)-plasma. By virtue of vigorous etching initiated by Ar-ions and oriented etching at increased gas pressure remarkable growth of highly aligned closely similar vertical Si-NRs are evident. At elevated RF power and high pressure, high density of etched atomic Si in the plasma combined with available atomic H, produces SiHn-like precursors that in turn induce re-growth on the etched surface and initiates growth of Si-NWs. [ABSTRACT FROM AUTHOR]

Published

2017

8. Structuring of DLC:Ag nanocomposite thin films employing plasma chemical etching and ion sputtering.

Author

Tamulevičius, Tomas, Tamulevičienė, Asta, Virganavičius, Dainius, Vasiliauskas, Andrius, Kopustinskas, Vitoldas, Meškinis, Šarūnas, and Tamulevičius, Sigitas

Subjects

*DIAMOND-like carbon, *MAGNETRON sputtering, *THIN films, *ACETYLENE, *ULTRAVIOLET radiation

Abstract

We analyze structuring effects of diamond like carbon based silver nanocomposite (DLC:Ag) thin films by CF 4 /O 2 plasma chemical etching and Ar + sputtering. DLC:Ag films were deposited employing unbalanced reactive magnetron sputtering of silver target with Ar + in C 2 H 2 gas atmosphere. Films with different silver content (0.6–12.9 at.%) were analyzed. The films (as deposited and exposed to plasma chemical etching) were characterized employing scanning electron microscopy and energy dispersive X-ray analysis (SEM/EDS), optical microscopy, ultraviolet–visible light (UV–VIS) spectroscopy and Fourier transform infrared (FTIR) spectroscopy. After deposition, the films were plasma chemically etched in CF 4 /O 2 mixture plasma for 2–6 min. It is shown that optical properties of thin films and silver nano particle size distribution can be tailored during deposition changing the magnetron current and C 2 H 2 /Ar ratio or during following plasma chemical etching. The plasma etching enabled to reveal the silver filler particle size distribution and to control silver content on the surface that was found to be dependent on Ostwald ripening process of silver nano-clusters. Employing contact lithography and 4 μm period mask in photoresist or aluminum the films were patterned employing CF 4 /O 2 mixture plasma chemical etching, direct Ar + sputtering or combined etching processes. It is shown that different processing recipes result in different final grating structures. Selective carbon etching in CF 4 /O 2 gas mixture with photoresist mask revealed micrometer range lines of silver nanoparticles, while Ar + sputtering and combined processing employing aluminum mask resulted in nanocomposite material (DLC:Ag) micropatterns. [ABSTRACT FROM AUTHOR]

Published

2014

9. Research of Constructive and Technological Methods for Forming a Silicon Disk Resonator with Whispering Gallery Modes

Author

Vladimir Amelichev, Anastasia Yakuhina, Dmitry Gorelov, A. S. Kadochkin, and Sergey Generalov

Subjects

lcsh:Applied optics. Photonics, Materials science, Silicon, silicon disk resonator, Base (geometry), chemistry.chemical_element, Silicon on insulator, 02 engineering and technology, Edge (geometry), wedge-shaped profile, 01 natural sciences, Constructive, 010309 optics, Resonator, Optics, Etching (microfabrication), plasma chemical etching, 0103 physical sciences, Radiology, Nuclear Medicine and imaging, microresonator, Instrumentation, mode stability, business.industry, lcsh:TA1501-1820, 021001 nanoscience & nanotechnology, Atomic and Molecular Physics, and Optics, chemistry, Whispering-gallery wave, 0210 nano-technology, business, silicon-on-isolator, whispering gallery mode

Abstract

This article presents the results of a computer simulation of whispering gallery modes in the structure of a silicon disk resonator with a wedge-shaped profile made on a silicon-on-isolator base (SOI). The rationale for the choice of silicon as a material for its manufacturing is given. The results of the study of the influence of the wedge angle on the whispering gallery mode parameters (WGM) are presented. The optimum wedge angle of a silicon disk resonator is determined, which ensures the minimum loss and maximum mode stability. The technological aspects of plasma-chemical etching processes for forming a wedge-shaped profile of the edge of a silicon disk resonator are studied.

Published

2020

10. Fabrication of Superconducting Nb–AlN–NbN Tunnel Junctions Using Electron-Beam Lithography.

Author

Fominsky, Mikhail Yu., Filippenko, Lyudmila V., Chekushkin, Artem M., Dmitriev, Pavel N., and Koshelets, Valery P.

Subjects

TUNNELS, LITHOGRAPHY, ELECTRON beams, RADIO telescopes, PLASMA etching, MAGNETRON sputtering

Abstract

Mixers based on superconductor–insulator–superconductor (SIS) tunnel junctions are the best input devices at frequencies from 0.1 to 1.2 THz. This is explained by both the extremely high nonlinearity of such elements and their extremely low intrinsic noise. Submicron tunnel junctions are necessary to realize the ultimate parameters of SIS receivers, which are used as standard devices on both ground and space radio telescopes around the world. The technology for manufacturing submicron Nb–AlN–NbN tunnel junctions using electron-beam lithography was developed and optimized. This article presents the results on the selection of the exposure dose, development time, and plasma chemical etching parameters to obtain high-quality junctions (the ratio of the resistances below and above the gap Rj/Rn). The use of a negative-resist ma-N 2400 with lower sensitivity and better contrast in comparison with a negative-resist UVN 2300-0.5 improved the reproducibility of the structure fabrication process. Submicron (area from 2.0 to 0.2 µm2) Nb–AlN–NbN tunnel junctions with high current densities and quality parameters Rj/Rn > 15 were fabricated. The spread of parameters of submicron tunnel structures across the substrate and the reproducibility of the cycle-to-cycle process of tunnel structure fabrication were measured. [ABSTRACT FROM AUTHOR]

Published

2021

11. [Untitled]

Author

Klimin, V.S.

Subjects

FOS: Nanotechnology, local anodic oxidation, planar technology, atomic force microscopy, plasma chemical etching, nanostructures, Nanotechnology, low-temperature plasma, gallium arsenide, nanomaterials

Abstract

The main goal of the work was to study the modes of processing and profiling structures based on gallium arsenide by a combination of local anodic oxidation methods and the combined plasma chemical etching method taking into account the formation voltage of the oxide masking layer and the etching time. In this paper, a combination of local anodic oxidation and plasma-chemical etching was used to treat near-surface structures based on gallium arsenide. Local anod-ic oxidation was carried out by means of scanning probe microscopy using a silicon probe. Plas-ma chemical treatment was carried out in a discharge by a combined plasma using two types of capacitive and inductively coupled discharge. This technology allows you to combine the ad-vantages of two types of categories. The high concentration of electrons and ions provides a high etching rate, and the capacitive discharge allows the ions to be guided along the field and directed perpendicular to the substrate to be treated, allows to reduce energy costs for production, and alsoto increase the yield of suitable products, which leads to a reduction in the cost of devices based on this technology. Eliminating the operations associated with liquid lithography reduces the rela-tive toxicity of processes. Local anodic oxidation was used to obtain an oxide layer of thickness 6.6 ± 0.2 nm, which serves as a masking coating for subsequent plasma chemical etching. The surface roughness after removal of the oxide layer was 0.51 ± 0.09 nm. The application of a com-bined plasma discharge for nano sized profiling with the use of two types of discharge - capacitive and inductively coupled, which allows combining the advantages of both types of discharges is considered. A high concentration of electrons and ions ensures a high etching rate, and a capaci-tive discharge allows you to orient the ions obtained along the field and direct them perpendicular to the surface being treated. The influence of etching modes on surface morphology and parame-ters of nanoscale structures is studied. Dependences of the height of oxide structures on the for-mation stress and the thickness of the oxide layer are obtained.

Published

2018

12. Research of Constructive and Technological Methods for Forming a Silicon Disk Resonator with Whispering Gallery Modes.

Author

Yakuhina, Anastasia, Kadochkin, Alexey, Amelichev, Vladimir, Gorelov, Dmitry, and Generalov, Sergey

Subjects

WHISPERING gallery modes, MICRORESONATORS (Optoelectronics), RESONATORS, HARD disks, SILICON, COMPUTER simulation

Abstract

This article presents the results of a computer simulation of whispering gallery modes in the structure of a silicon disk resonator with a wedge-shaped profile made on a silicon-on-isolator base (SOI). The rationale for the choice of silicon as a material for its manufacturing is given. The results of the study of the influence of the wedge angle on the whispering gallery mode parameters (WGM) are presented. The optimum wedge angle of a silicon disk resonator is determined, which ensures the minimum loss and maximum mode stability. The technological aspects of plasma-chemical etching processes for forming a wedge-shaped profile of the edge of a silicon disk resonator are studied. [ABSTRACT FROM AUTHOR]

Published

2020

13. Implementation plasma chemical etching in submicron technology wsi structure

Subjects

плазмохімічне травлення, осадження, боро–фосфоро силікатне скло, фоторезист, реактор, УДК 621.794.4, плазмохимическое травление, осаждение, боро–фосфоро силикатное стекло, plasma chemical etching, deposition, boron phosphorus silicate glass, photoresist, reactor

Abstract

При освоєнні діапазону суб– і наномікронних елементів інтегральних схем виникає ряд проблем, яких або взагалі не було при розробці технології виготовлення з мінімальними розмірами елементів більше , або вони не представлялись значними. Дана стаття розкриває саме перспективу та альтернативу використання субмікронної технології плазмохімічного травлення та впровадження її у виробництво, При освоении диапазона суб– и наномикронных элементов интегральных схем возникает ряд проблем, которых либо вообще не было при разработке технологии изготовления с минимальными размерами элементов больше , или они не представлялись значительными. Данная статья раскрывает именно перспективу и альтернативу использования субмикронной технологии плазмохимического травления и внедрения ее в производство., With the development of a range of sub–micron devices elements inthralnyh large schemes, a number of problems, which either did not exist in the development of technology of integrated circuits with minimum dimensions of elements, or they did not identify significant. Thus reducing the geometric dimensions topology structures LSI, accompanied by a decrease in the thickness of the functional layers of multilayer structures used to represent a theoretical requirements for selectivity and anisotropy etching layers introduced defects and radiation damage to the surface of the processed wafers of silicon or gallium arsenide structures of integrated circuits. To determine the optimal technological regimes digestion ranged basic operating parameters of the process – the composition and working gas pressure, bias voltage and holder, holder distance to the source plasma. This article reveals the same perspective and alternative use of submicron technology of plasma chemical etching.

Published

2015