Electrochemical Micromachining of p-Type Silicon

Allongue, P.; Jiang, Peng; Kirchner, Viola; Trimmer, Andrew L.; Schuster, Rolf

doi:10.1021/jp0497312

Cited by 55 publications

(53 citation statements)

References 24 publications

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“…The step value of 0.32 nm is identical with the thickness of one layer. This result agrees the experimental observation (8) . The etching depth against time plot of the (110) plane is almost linear as shown in Fig.9.…”

Section: Time Dependence Of Etching Rate and Roughnesssupporting

confidence: 93%

Simulation of Anisotropic Chemical Etching of Single Crystalline Silicon using Cellular-Automata

et al. 2004

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We propose a new concept for anisotropic single crystalline silicon (Si) etching simulation. Our approach combines three calculation modules, a molecular dynamics calculation module to define chemical reaction probability, a Cellular-Automaton module to calculate etching rate, and a Wulff-Jaccodine graphical method module to predict an etched shape. This configuration allows mm scale process simulation based on atomic scale physical chemistry of anisotropic Si etching. In this paper, the performance of a newly developed Cellular-Automata module, called CAES (Cellular-Automata Etching simulator), is presented as a first step towards the realization of our simulation concept.

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Section: Time Dependence Of Etching Rate and Roughnesssupporting

confidence: 93%

Simulation of Anisotropic Chemical Etching of Single Crystalline Silicon using Cellular-Automata

et al. 2004

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“…As a consequence for the machining of stainless steel, highly corrosive electrolytes like HCl/HF mixtures have to be applied, thus keeping the passivation layer presumably very thin due to chemical etching. [23,24] Similarly, the machining of highly doped silicon is possible in the presence of HF, which dissolves silicon oxides formed during the electrochemical reaction. [23,24] In cases of transpassive dissolution in the presence of a thick oxide layer, for example, upon machining stainless steel in H 2 SO 4 , the application of short pulses does not suffice to confine electrochemical reactions and additional means, such as partial insulation of the electrodes, have to be applied for local confinement of the electrode reactions.…”

Section: Machinable Materialsmentioning

confidence: 99%

Electrochemical Microstructuring with Short Voltage Pulses

Schuster¹

2006

ChemPhysChem

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The application of short (nanosecond) voltage pulses between a tool electrode and a work piece immersed in an electrolyte solution allows the three-dimensional machining of electrochemically active materials with submicrometer resolution. The method is based on the finite charging time constant of the double-layer capacitance, which varies approximately linearly with the local separation between the electrode surfaces. Hence, the polarization of the electrodes during short pulses and subsequent electrochemical reactions are confined to regions where the electrodes are in sufficiently close proximity. This Minireview describes the principles behind electrochemical micro-structuring with short voltage pulses, and its current achievements and limitations.

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“…They used nanosecond pulses to confine the EC reactions to electrode regions in close proximity. This technique allowed holes and trenches to be etched with the tip of a tungsten wire (2 µm) in HF under anodic bias of Si vs. tungsten [2]. The machining precision (~10 µm) and process speed were, however, not suitable for the design of submicrometer structures in low doped Si.…”

Section: Introductionmentioning

confidence: 99%

3D patterning of silicon by contact etching with anodically biased nanoporous gold electrodes

Torralba

Halbwax

Assimi

et al. 2017

Electrochemistry Communications

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, 3D patterning of silicon by contact etching with anodically biased nanoporous gold electrodes, Electrochemistry Communications (2017Communications ( ), doi:10.1016Communications ( /j.elecom.2017 This is a PDF file of an unedited manuscript that has been accepted for publication. As a service to our customers we are providing this early version of the manuscript. The manuscript will undergo copyediting, typesetting, and review of the resulting proof before it is published in its final form. Please note that during the production process errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain. A C C E P T E D M A N U S C R I P T ABSTRACTA novel strategy to achieve 3D pattern transfer into silicon in a single step without using lithography is presented. Etching is performed electrochemically in HF media by contacting silicon with a positively biased, patterned, metal electrode. Dissolution is localized at the Si/metal contacts and patterning is obtained as the electrode digs into the substrate. Previous attempts at imprinting Si using bulk metal electrodes have been limited by electrolyte blockage. Here, the problem is solved by using, for the first time, a nanoporous metal electrode that allows the electrolyte to access the entire Si/metal interface, irrespective of the electrode dimensions. As a proof of concept, imprinting of well-defined arrays of inverted pyramids has been performed with sub-micrometer spatial resolution over 1 mm 2 using a nanoporous gold electrode of the complementary shape. Under a polarization of +0.3 V/SME in 5M HF, the etch rate is ~0.5 µm/min. The pyramidal pattern is imprinted independently of the Si crystallographic orientation. This maskless imprinting technique opens new opportunities in the fabrication of Si microstructures.

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Electrochemical Micromachining of p-Type Silicon

Cited by 55 publications

References 24 publications

Simulation of Anisotropic Chemical Etching of Single Crystalline Silicon using Cellular-Automata

Simulation of Anisotropic Chemical Etching of Single Crystalline Silicon using Cellular-Automata

Electrochemical Microstructuring with Short Voltage Pulses

3D patterning of silicon by contact etching with anodically biased nanoporous gold electrodes

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