Focusing only on the Einstein relation in compound semiconductors and their nanostructures, this book deals with open research problems from carbon nanotubes to quantum wire superlattices with different band structures, and other field assisted systems.
In recent years, with the advent of ?ne line lithographical methods, molecular beam epitaxy, organometallic vapour phase epitaxy and other experimental techniques, low dimensional structures having quantum con nement in one, two and three dimensions (such as inversion layers, ultrathin ?lms, nipis, quantum well superlattices, quantum wires, quantum wire superlattices, and quantum dots together with quantum con ned structures aided by various other ?elds) have attracted much attention, not only for their potential in uncovering new phenomena in nanoscience, but also for their interesting applications in the realm of quantum e ect devices. In ultrathin ?lms, due to the reduction of symmetry in the wavevector space, the motion of the carriers in the direction normal to the ?lm becomes quantized leading to the quantum size e ect. Such systems ?nd extensive applications in quantum well lasers, ?eld e ect transistors, high speed digital networks and also in other low dimensional systems. In quantum wires, the carriers are quantized in two transverse directions and only one-dimensional motion of the carriers is allowed. The transport properties of charge carriers in quantum wires, which may be studied by utilizing the similarities with optical and microwave waveguides, are currently being investigated. Knowledge regarding these quantized structures may be gained from original research contributions in scienti c journals, proceedings of international conferences and various - view articles.
