Fractional quantum Hall effect measures at zero g factor

Fractional quantum Hall effect energy gaps have been measured as a function of Zeeman energy. The gap at ν = 1/3 decreases as the g factor is reduced by hydrostatic pressure. This behavior is similar to that at ν = 1 and shows that the excitations are spinlike. At small Zeeman energy, the excitation is consistent with the reversal of 3 spins and may be interpreted as a small composite Skyrmion. At 20 kbar, where g has changed sign, the 1/3 gap appears to increase again

Novel GaN-based vertical heterostructure field effect transistor structures using crystallographic KOH etching and overgrowth

A novel V-groove vertical heterostructure field effect transistor structure is proposed using semi-polar (11-22) GaN. A crystallographic potassium hydroxide self-limiting wet etching technique was developed to enable a damage-free V-groove etching process. An AlGaN/GaN HFET structure was successfully regrown by molecular beam epitaxy on the V-groove surface. A smooth AlGaN/GaN interface was achieved which is an essential requirement for the formation of a high mobility channel.This work was funded by the Engineering and Physical Sciences Research Council (EPSRC), United Kingdom, under EP/K014471/1 (Silicon Compatible GaN Power Electronics)

Characterization of p-GaN1−x_{1−x} Asx_{x}/n-GaN PN junction diodes

The structural properties and electrical conduction mechanisms of p-type amorphous GaN$_{1−x}$ As$_{x}$ /n-type crystalline GaN PN junction diodes are presented. A hole concentration of 8.5 × 10$^{19}$ cm$^{-3}$ is achieved which allows a specific contact resistance of 1.3 × 10$^{-4}$ Ω cm$^{2}$. An increased gallium beam equivalent pressure during growth produces reduced resistivity but can result in the formation of a polycrystalline structure. The conduction mechanism is found to be influenced by the crystallinity of the structure. Temperature dependent current voltage characteristics at low forward bias (<0.35 V) show that conduction is recombination dominated in the amorphous structure whereas a transition from tunneling to recombination is observed in the polycrystalline structure. At higher bias, the currents are space charge limited due to the low carrier density in the n-type region. In reverse bias, tunneling current dominates at low bias (<0.3 V) and recombination current becomes dominant at higher reverse bias.This work was undertaken with support from the EPSRC (EP/K014471/1)

Low-temperature magnetization of (Ga,Mn) As semiconductors

Journals published by the American Physical Society can be found at http://journals.aps.org/We report on a comprehensive study of the ferromagnetic moment per Mn atom in (Ga,Mn)As ferromagnetic semiconductors. Theoretical discussion is based on microscopic calculations and on an effective model of Mn local moments antiferromagnetically coupled to valence band hole spins. The validity of the effective model over the range of doping studied is assessed by comparing with microscopic tight-binding/coherent-potential approximation calculations. Using the virtual crystal k center dot p model for hole states, we evaluate the zero-temperature mean-field contributions to the magnetization from the hole kinetic and exchange energies, and magnetization suppression due to quantum fluctuations of Mn moment orientations around their mean-field ground state values. Experimental low-temperature ferromagnetic moments per Mn are obtained by superconducting quantum interference device and x-ray magnetic circular dichroism measurements in a series of (Ga,Mn)As semiconductors with nominal Mn doping ranging from similar to 2 to 8%. Hall measurements in as-grown and annealed samples are used to estimate the number of uncompensated substitutional Mn moments. Based on our comparison between experiment and theory we conclude that all these Mn moments in high quality (Ga,Mn)As materials have nearly parallel ground state alignment

Femtosecond optical absorption measurements of electron-phonon scattering in GaAs quantum wells

The results of a combined experimental and theoretical analysis of time-resolved optical absorption in a GaAs quantum well which allowed for the first time a detailed test of the theoretically predicted scattering rates were presented. The results provided a strong verification of the electron-optical phonon scattering rates in quantum well structures predicted by dielectric continuum theory. Intrasubband rates were determined to be intermediate between those of the bulk constituent materials, GaAs and AlAs. The n=2 population quantified were consistent with that measured by time-resolved Raman spectroscopy. Thus, it can be deduced that the intersubband rate depended weakly on subband separation in a broad range of quantum well width