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Lieferstatus:	i.d.R. innert 7-14 Tagen versandfertig
Veröffentlichung:	November 2016
Genre:	Naturwissensch., Medizin, Technik
	B / Electricity, electromagnetism & magnetism / Electronic devices & materials / Electronic materials / Magnetic materials / Magnetism / Magnetism, Magnetic Materials / Microsystems and MEMS / Nanophysics / Nanoscale science / Nanoscale Science and Technology / Nanoscience / Nanostructures / Nanotechnology / Nanotechnology and Microengineering / Optical and Electronic Materials / Optical Materials / Other manufacturing technologies / Physics and Astronomy / Semiconductors
ISBN:	9783319398310
EAN-Code:	9783319398310
Verlag:	Springer International Publishing
Einband:	Kartoniert
Sprache:	English
Serie:	#927 - Lecture Notes in Physics
Dimensionen:	H 235 mm / B 155 mm / D 15 mm
Gewicht:	406 gr
Seiten:	264
Zus. Info:	Paperback
Bewertung:	Titel bewerten / Meinung schreiben

Inhalt:

In this book the coherent quantum transport of electrons through two-dimensional mesoscopic structures is explored in dependence of the interplay between the confining geometry and the impact of applied magnetic fields, aiming at conductance controllability. After a top-down, insightful presentation of the elements of mesoscopic devices and transport theory, a computational technique which treats multiterminal structures of arbitrary geometry and topology is developed. The method relies on the modular assembly of the electronic propagators of subsystems which are inter- or intra-connected providing large flexibility in system setups combined with high computational efficiency. Conductance control is first demonstrated for elongated quantum billiards and arrays thereof where a weak magnetic field tunes the current by phase modulation of interfering lead-coupled states geometrically separated from confined states. Soft-wall potentials are then employed for efficient and robust conductance switching by isolating energy persistent, collimated or magnetically deflected electron paths from Fano resonances. In a multiterminal configuration, the guiding and focusing property of curved boundary sections enables magnetically controlled directional transport with input electron waves flowing exclusively to selected outputs. Together with a comprehensive analysis of characteristic transport features and spatial distributions of scattering states, the results demonstrate the geometrically assisted design of magnetoconductance control elements in the linear response regime.