Fabrication of multiple nanopores in a SiNx membrane via controlled breakdown

Yunlong Wang,Wenyuan Zhou,Zhibo Liu,Jianguo Tian,Lennart De Vreede,Cuifeng Ying

doi:10.1038/s41598-018-19450-7

Yunlong Wang, Wenyuan Zhou + Show 4 more

Open Access

https://doi.org/10.1038/s41598-018-19450-7

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Abstract

This paper reports a controlled breakdown (CBD) method to fabricate multiple nanopores in a silicon nitride (SiNx) membrane with control over both nanopore count and nanopore diameter. Despite the stochastic process of the breakdown, we found that the nanopores created via CBD, tend to be of the same diameter. We propose a membrane resistance model to explain and control the multiple nanopores forming in the membrane. We prove that the membrane resistance can reflect the number of nanopores in the membrane and that the diameter of the nanopores is controlled by the exposure time and strength of the electric field. This controllable multiple nanopore formation via CBD avoids the utilization of complicated instruments and time-intensive manufacturing. We anticipate CBD has the potential to become a nanopore fabrication technique which, integrated into an optical setup, could be used as a high-throughput and multichannel characterization technique.

Highlights

When we apply a voltage across a nanopore in a thin insulating membrane, the ionic current through the nanopore relates to the characteristics of particles passing through the nanopore
To breakdown a 50 nm SiNx membrane, the electric field strength should be larger than 0.75 V/nm
We have shown control of the nanopore count and nanopore diameter created in a SiNx membrane via controlled breakdown (CBD) by adjusting the electric field strength and the total resistance

Summary

Introduction

When we apply a voltage across a nanopore in a thin insulating membrane, the ionic current through the nanopore relates to the characteristics of particles passing through the nanopore. The nanopores formed at the same electric field strength tend to stop growing at the same diameter, based on which, we control the number and diameter of nanopores in a SiNx membrane. The breakdown process depends on the material and the thickness of the membrane, as well as the time and the strength of the applied electric field[39,49,50,51].

Results

Conclusion