posted on 2014-05-27, 00:00authored byTimothy E. Kidd, Aaron O’Shea, Benjamin Beck, Rui He, Conor Delaney, Paul M. Shand, Laura H. Strauss, Andrew Stollenwerk, Noah Hurley, Kyle Spurgeon, Genda Gu
The ability to form patterned surface
nanostructures has revolutionized
the miniaturization of electronics and led to the discovery of emergent
behaviors unseen in macroscopic systems. However, the creation of
such nanostructures typically requires multiple processing steps,
a high level of technical expertise, and highly sophisticated equipment.
In this work, we have discovered a simple method to create nanostructures
with control size and positioning in a single processing step using
a standard scanning electron microscope. The technique can be applied
to a wide range of systems and was successful in every layered material
tested. Patterned nanostructures were formed on graphite, topological
insulators, novel superconductors, and layered transition metal dichalcogenides.
The nanostructures were formed via the incorporation of carbon nanoparticles
into the samples in a novel form of intercalation. It appears that
the electron beam interacts with residual organic molecules available
on the sample surface, making it possible for them to intercalate
between the layers in their crystal structure and break down into
carbon. These carbon nanoparticles have strong broad-wavelength interactions
in the visible light range, making these nanostructures easily detectable
in an optical microscope and of interest for a range of nanoscale
electro-optical devices.