IBM T. J. Watson Research Center, 1101 Kitchawan Road, Yorktown Heights, NY 10598, USA.
Nanoscale. 2014 Aug 7;6(15):8900-6. doi: 10.1039/c3nr06723h.
We introduce a method to fabricate solid-state nanopores with sub-20 nm diameter in membranes with embedded metal electrodes across a 200 mm wafer using CMOS compatible semiconductor processes. Multi-layer (metal-dielectric) structures embedded in membranes were demonstrated to have high uniformity (± 0.5 nm) across the wafer. Arrays of nanopores were fabricated with an average size of 18 ± 2 nm in diameter using a Reactive Ion Etching (RIE) method in lieu of TEM drilling. Shorts between the membrane-embedded metals were occasionally created after pore formation, but the RIE based pores had a much better yield (99%) of unshorted electrodes compared to TEM drilled pores (<10%). A double-stranded DNA of length 1 kbp was translocated through the multi-layer structure RIE-based nanopore demonstrating that the pores were open. The ionic current through the pore can be modulated with a gain of 3 using embedded electrodes functioning as a gate in 0.1 mM KCl aqueous solution. This fabrication approach can potentially pave the way to manufacturable nanopore arrays with the ability to electrically control the movement of single or double-stranded DNA inside the pore with embedded electrodes.
我们介绍了一种在嵌入金属电极的膜中制造直径小于 20nm 的固态纳米孔的方法,该方法使用与 CMOS 兼容的半导体工艺在 200mm 晶圆上进行。证明了嵌入膜中的多层(金属-电介质)结构在晶圆上具有高度的均匀性(±0.5nm)。使用反应离子刻蚀(RIE)方法而不是 TEM 钻孔,制造了直径平均为 18±2nm 的纳米孔阵列。在形成孔之后,膜嵌入金属之间偶尔会产生短路,但与 TEM 钻孔孔相比,基于 RIE 的孔具有更好的无短路电极(99%)的产量(<10%)。长度为 1kbp 的双链 DNA 通过多层结构的 RIE 基纳米孔迁移,证明了孔是开放的。通过嵌入电极作为栅极在 0.1mM KCl 水溶液中可以将通过孔的离子电流调节增益 3。这种制造方法有可能为可制造的纳米孔阵列铺平道路,这些纳米孔阵列具有通过嵌入电极在孔内电控制单链或双链 DNA 运动的能力。
