AI Article Synopsis
- The text discusses the importance of manipulating matter at the nanometre scale for advancements in electronics, chemistry, and biology, highlighting that current methods lack precision.
- A new technique called "ion-beam sculpting" is introduced, using low-energy ion beams with fine control over exposure and temperature to create nanostructures.
- This method is demonstrated by fabricating a nanopore in a solid-state membrane, which functions as a sensitive detector for single DNA molecules, mimicking the role of nanopores in living systems.
Article Abstract
Manipulating matter at the nanometre scale is important for many electronic, chemical and biological advances, but present solid-state fabrication methods do not reproducibly achieve dimensional control at the nanometre scale. Here we report a means of fashioning matter at these dimensions that uses low-energy ion beams and reveals surprising atomic transport phenomena that occur in a variety of materials and geometries. The method is implemented in a feedback-controlled sputtering system that provides fine control over ion beam exposure and sample temperature. We call the method "ion-beam sculpting", and apply it to the problem of fabricating a molecular-scale hole, or nanopore, in a thin insulating solid-state membrane. Such pores can serve to localize molecular-scale electrical junctions and switches and function as masks to create other small-scale structures. Nanopores also function as membrane channels in all living systems, where they serve as extremely sensitive electro-mechanical devices that regulate electric potential, ionic flow, and molecular transport across cellular membranes. We show that ion-beam sculpting can be used to fashion an analogous solid-state device: a robust electronic detector consisting of a single nanopore in a Si3N4 membrane, capable of registering single DNA molecules in aqueous solution.
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| http://dx.doi.org/10.1038/35084037 | DOI Listing |
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