In this research, we aim to achieve sub-mK effective electron measurements to better analyze effects that occur at these very low temperatures. We do this by using a Faraday cage, through which we...Show moreIn this research, we aim to achieve sub-mK effective electron measurements to better analyze effects that occur at these very low temperatures. We do this by using a Faraday cage, through which we send a signal using sets of inductors. In order to test this, we define an effective frequency range for our signal by analyzing the theoretical electrical side effects that occur in our system. We perform multiple room temperature tests on our system within the defined frequency range, and work towards testing the effectiveness of our system at millikelvin temperatures as well.Show less
In this study we investigate if we can change the interfacial conductivity in LaAlO3/SrTiO3 heterostructures by adding some oxygen to the argon sputter gas. We vary the deposition parameters to...Show moreIn this study we investigate if we can change the interfacial conductivity in LaAlO3/SrTiO3 heterostructures by adding some oxygen to the argon sputter gas. We vary the deposition parameters to minimise the effect of the oxygen. We find that an increase in oxygen partial pressure increases the surface roughness. We also find that an increase in argon flow increases surface roughness. The optimised parameters, which minimise surface roughness, are in agreement with previous results of growing a conducting interface in LaAlO3/SrTiO3 by sputtering. However all our samples grown with oxygen are found to be insulating. A possible explanation for the effect of oxygen in the sputter gas is that the species oxidise before reaching the sample. We conclude that even a very small amount of oxygen in the sputter gas gives an insulating interface and that we can not make a conducting interface with oxygen in the sputter gas with the experimental set-up used.Show less