Quantum Materials, Lateral Semiconductor Nanostructures, Hybrid Systems and Nanocrystals, Softcover reprint of the original 1st ed. 2010 Lateral Semiconductor Nanostructures, Hybrid Systems and Nanocrystals NanoScience and Technology Series

Semiconductor nanostructures are ideal systems to tailor the physical properties via quantum effects, utilizing special growth techniques, self-assembling, wet chemical processes or lithographic tools in combination with tuneable external electric and magnetic fields. Such systems are called "Quantum Materials".The electronic, photonic, and phononic properties of these systems are governed by size quantization and discrete energy levels. The charging is controlled by the Coulomb blockade. The spin can be manipulated by the geometrical structure, external gates and by integrating hybrid ferromagnetic emitters.This book reviews sophisticated preparation methods for quantum materials based on III-V and II-VI semiconductors and a wide variety of experimental techniques for the investigation of these interesting systems. It highlights selected experiments and theoretical concepts and gives such a state-of-the-art overview about the wide field of physics and chemistry that can be studied in these systems.

Self-Assembly of Quantum Dots and Rings on Semiconductor Surfaces.- Curved Two-Dimensional Electron Systems in Semiconductor Nanoscrolls.- Capacitance Spectroscopy on Self-Assembled Quantum Dots.- The Different Faces of Coulomb Interaction in Transport Through Quantum Dot Systems.- Far-Infrared Spectroscopy of Low-Dimensional Electron Systems.- Electronic Raman Spectroscopy of Quantum Dots.- Light Confinement in Microtubes.- Scanning Tunneling Spectroscopy of Semiconductor Quantum Dots and Nanocrystals.- Scanning Tunneling Spectroscopy on III–V Materials: Effects of Dimensionality, Magnetic Field, and Magnetic Impurities.- Magnetization of Interacting Electrons in Low-Dimensional Systems.- Spin Polarized Transport and Spin Relaxation in Quantum Wires.- InAs Spin Filters Based on the Spin-Hall Effect.- Spin Injection and Detection in Spin Valves with Integrated Tunnel Barriers.- Growth and Characterization of Ferromagnetic Alloys for Spin Injection.- Charge and Spin Noise in Magnetic Tunnel Junctions.- Nanostructured Ferromagnetic Systems for the Fabrication of Short-Period Magnetic Superlattices.- How X-Ray Methods Probe Chemically Prepared Nanoparticles from the Atomic- to the Nano-Scale.

Detlef Heitmann is a Full Professor at the Institute of Applied Physics of the University of Hamburg and Head of the Semiconductor Group. After research on Cerenkov radiation, surface plasmons and Integrated Optics he entered the field of low-dimensional semiconductor systems. His interest was devoted in particular to the fabrication of quantum structures and its investigation with far infrared, Raman and photoluminescence spectroscopy. In recent years his group also used the tools of the semiconductor technology to prepare ferromagnetic nanostructures and study the spin dynamics in these systems, and to fabricate and investigate optical metamaterials. From 1997 to 2009 he was Speaker of the DFG Collaborative Research Center SFB 508 "Quantum Materials".

State-of-the-art report of semiconductor nanotechnology Presents the basic physics, realization of new nanoeffects and potential applications of quantum materials Provides some research basis for spintronic materials Important book for researchers and graduate students of nanomaterials