Abstract
In this work an easy, reproducible and inexpensive technique for the production of solid state nanopores and micropores using silicon wafer substrate is proposed. The technique is based on control of pore formation, by neutralization etchant (KOH) with a strong acid (HCl). Thus, a local neutralization is produced around the nanopore, which stops the silicon etching. The etching process was performed with 7M KOH at 80°C, where 1.23µm/min etching speed was obtained, similar to those published in literature. The control of the pore formation with the braking acid method was done using 12M HCl and different extreme conditions: i) at 25°C, ii) at 80°C and iii) at 80°C applying an electric potential. In these studies, it was found that nanopores and micropores can be obtained automatically and at a low cost. Additionally, the process was optimized to obtain clean silicon wafers after the pore fabrication process. This method opens the possibility for an efficient scale-up from laboratory production.
Highlights
Nanopore-based technologies are emerging as a powerful tool for single molecule analysis
The methods to produce solid-state nanopores involve the use of advanced microscopy tools to complete the manufacturing process, namely Transmission Electron Microscopy (TEM) [10], Scanning Transmission Electron Microscopy (STEM) or Focused Ion Beam (FIB) [11]
A silicon nitride layer 50nm thick was deposited on a wafer using Plasma Enhanced chemical vapour deposition (PECVD) at 600°C
Summary
Nanopore-based technologies are emerging as a powerful tool for single molecule analysis. They can be used in different applications such as detection of ssDNA [1,2,3], dsDNA segment [4,5,6] and proteins [7,8]. The production of solid state nanopores has aroused great interest because silicon wafers are inexpensive, resistant and durable. The methods to produce solid-state nanopores involve the use of advanced microscopy tools to complete the manufacturing process, namely Transmission Electron Microscopy (TEM) [10], Scanning Transmission Electron Microscopy (STEM) or Focused Ion Beam (FIB) [11]. Nanopores and micropores were manufactured using KOH etching and subsequently chemical braking was performed with HCl, in order to automatically control the pore opening.
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