We determined the spatial resolution of the new very low energy transmission electron microscopy technique called eV-TEM [1] and used it to image gold nanoparticles deposited on graphene in order...Show moreWe determined the spatial resolution of the new very low energy transmission electron microscopy technique called eV-TEM [1] and used it to image gold nanoparticles deposited on graphene in order to determine whether it is possible to image for example DNA and proteins with low energy electrons. By transferring graphene to a flat grid with small circular holes in it we created new samples with flatter, less wrinkled graphene that make performing eV-TEM easurements on graphene easier and increase their quality. We improved the alignment of the imaging system of the microscope and determined the resolution of eV-TEM using the new samples to image graphene. We found a method to deposit 10nm gold nanoparticles on graphene suitable for eV-TEM measurements and a method to deposit ferritin on graphene that we should be able to image as well. We conclude that the spatial resolution of the current set-up of eV-TEM is 10nm and that it is possible to image gold nanoparticles deposited on graphene with eV-TEM.Show less
To sense the movement or piling up of single charges, a system interacting strongly with these charges is required. An available system, having these properties, is a single electron transistor ...Show moreTo sense the movement or piling up of single charges, a system interacting strongly with these charges is required. An available system, having these properties, is a single electron transistor (SET). The electric fi eld caused by the charge, strongly changes the resistance of the SET. Yet experiments opt for a less invasive charge sensor. Such a proposed charge sensor is a single fluorescent dye molecule. The distinguishable zero phonon lines (ZPL's) of the fluorescence of the molecules shifts strongly by the Stark e ffect. The lineshift of each molecule can be tracked with an excitation laser, allowing to observe the change in charging. Tracking the ZPL's of multiple molecules allows the observation of slow charge movement. The optical charge sensing method needs to be tested on devices fabricated on a glass substrate. In particular devices, which exhibit single electron charging. These devices have been constructed with electron beam lithography (EBL). Nanoparticles, representing an island to hold the charge, have been trapped between nano-electrodes using dielectrophoresis. The nanogaps have been created by electromigration or by EBL. Eventually, nano-electrodes were also fabricated on glass by coating the glass with a 1,5 nm Cr layer. This coating was removed afterwards with plasma etching. The project focused on the fabrication of the devices. The deposition of fluorescent dye molecules and tracking the lineshifts was left for subsequent experiments. A fluorescence microscope, also necessary for the lineshift measurements, was used to observe quantum dots. Proposed experiments with quantum dots are the tracking of the movement of quantum dots in a strong alternating electric fi eld or the eff ect of a high electric field on the fluorescence of a quantum dot in a nano-electrode junction.Show less