Abstract: A heterojunction semiconductor device utilizing a quantum-mechanical effect comprises a first compound semiconductor (e.g., AlGaAs) layer and a second compound semiconductor (e.g., GaAs) layer having an electron affinity different from that of the first semiconductor layer, and the first and second compound semiconductor layers forming a heterojunction interface therebetween, the first layer having an energy at the conduction band bottom thereof higher than that of the second layer and doped with donor impurities, wherein at least one concave or convex portion of the first semiconductor layer is formed at the heterojunction interface and both sides of the concave or convex portion serve as a potential well or potential barriers against electrons accumulated in the second semiconductor layer close to the vicinity of the heterojunction interface.

Abstract: A method and device are disclosed for converting electronic signals into magnetic signals in DMS materials by generating carriers in selected regions of the materials. The carriers comprise either holes or electrons and the concentration of the carriers in the DMS device is electronically and consequently reversibly controlled by varying the voltage supplied to the device. A carrier concentration-induced conversion of the DMS device is obtained in an area defined by an electrode so that the device of a selected area of the device is changed from one magnetic state to another magnetic state. A superexchange interaction through the carriers in the host DMS material causes a transition from one magnetic phase to another when the carrier concentration exceeds a critical value.

Abstract: A Hall generator includes a substrate body of single crystalline semi-insulating gallium arsenide having a surface. A thin layer, no greater than about 5 micrometers in thickness, of single crystalline indium arsenide is on the surface of the body and is in the form of four arms joined at a common point to form a cross. A separate metal contact is on each of the arms at the free end thereof. An accumulation layer is adjacent the outer surface of the indium arsenide layer and extends along the entire surface of the indium arsenide layer between the contacts. The accumulation layer is effective to provide a magnetic sensitivity and range of operating temperatures as if the indium arsenide layer was much thinner and had a much higher electron density and electron mobility. Electrical devices, such as field effect transistors, may be formed in the body and the surface and electrically connected to the contacts of the Hall generator in a desired circuit.