An in situ counted
ion implantation experiment improving the error
on the number of ions required to form a single optically active silicon
vacancy (SiV) defect in diamond 7-fold compared to timed implantation
is presented. Traditional timed implantation relies on a beam current
measurement followed by implantation with a preset pulse duration.
It is dominated by Poisson statistics, resulting in large errors for
low ion numbers. Instead, our in situ detection, measuring the ion
number arriving at the substrate, results in a 2-fold improvement
of the error on the ion number required to generate a single SiV compared
to timed implantation. Through postimplantation analysis, the error
is improved 7-fold compared to timed implantation. SiVs are detected
by photoluminescence spectroscopy, and the yield of 2.98% is calculated
through the photoluminescence count rate. Hanbury–Brown–Twiss
interferometry is performed on locations potentially hosting single-photon
emitters, confirming that 82% of the locations exhibit single photon
emission statistics.
Using a home-made aerosol nebulizer, we developed a new aerosol-assisted chemical vapor deposition (AACVD) process that made it possible to synthesize vertically-aligned carbon nanotube (VACNT) arrays with heights over a few millimeters routinely. An essential part of this technique was in-situ formation of metal catalyst nanoparticles via pyrolysis of ferrocene-ethanol aerosol right before CNT synthesis. Through the optimization of aerosol supply and CVD process parameters, we were able to synthesize clean VACNT arrays as long as 4.38 mm with very low metal contents in 20 min. Furthermore, it is worthy noting that such an outstanding height is achieved very quickly without supporting materials and water-assistance. By taking advantage of almost complete inhibition of CNT growth on low melting-temperature metals, we were able to fabricate patterned VACNT arrays by combining AACVD process with a conventional photolithograpic patterning of gold lines. Characterizations of as-grown nanotubes such as morphology, purity, and metal contents are presented.
We report on an unconventional macroscopic field effect transistor composed of electrons floating above the surface of superfluid helium. With this device unique transport regimes are realized in which the charge density of the electron layer can be controlled in a manner not possible in other material systems. In particular, we are able to manipulate the collective behavior of the electrons to produce a highly non-uniform, but precisely controlled, charge density to reveal a negative source-drain current. This behavior can be understood by considering the propagation of damped charge oscillations along a transmission line formed by the inhomogeneous sheet of twodimensional electrons above, and between, the source and drain electrodes of the transistor.
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