Sawafta Furat, Carlsen Autumn T, Hall Adam R
Joint School of Nanoscience and Nanoengineering, University of North Carolina Greensboro, Greensboro, NC 27401, USA.
Department of Biomedical Engineering, Wake Forest University School of Medicine, Winston-Salem, NC 27101, USA.
Sensors (Basel). 2014 May 6;14(5):8150-61. doi: 10.3390/s140508150.
Solid-state nanopores are emerging as a valuable tool for the detection and characterization of individual biomolecules. Central to their success is the realization of fabrication strategies that are both rapid and flexible in their ability to achieve diverse device dimensions. In this paper, we demonstrate the membrane thickness dependence of solid-state nanopore formation with a focused helium ion beam. We vary membrane thickness in situ and show that the rate of pore expansion follows a reproducible trend under all investigated membrane conditions. We show that this trend shifts to lower ion dose for thin membranes in a manner that can be described quantitatively, allowing devices of arbitrary dimension to be realized. Finally, we demonstrate that thin, small-diameter nanopores formed with our approach can be utilized for high signal-to-noise ratio resistive pulse sensing of DNA.
固态纳米孔正逐渐成为检测和表征单个生物分子的一种有价值的工具。其成功的关键在于实现制造策略,这些策略在实现不同器件尺寸方面既快速又灵活。在本文中,我们展示了聚焦氦离子束形成固态纳米孔时膜厚度的依赖性。我们原位改变膜厚度,并表明在所有研究的膜条件下,孔扩展速率遵循可重复的趋势。我们表明,这种趋势在薄膜中以可定量描述的方式转变为较低的离子剂量,从而能够实现任意尺寸的器件。最后,我们证明了用我们的方法形成的薄的、小直径纳米孔可用于DNA的高信噪比电阻脉冲传感。