Andere Kunden interessierten sich auch für
![The Physics of Microfabrication]( "The Physics of Microfabrication")
The Physics of Microfabrication154,99 €![The Physics of Thin Film Optical Spectra]( "The Physics of Thin Film Optical Spectra")
The Physics of Thin Film Optical Spectra125,99 €![Electrical Conductive Adhesives with Nanotechnologies]( "Electrical Conductive Adhesives with Nanotechnologies")
Electrical Conductive Adhesives with Nanotechnologies125,99 €![Thin Film Ferroelectric Materials and Devices]( "Thin Film Ferroelectric Materials and Devices")
Thin Film Ferroelectric Materials and Devices116,99 €![NASSAU 2006]( "NASSAU 2006")
NASSAU 2006110,99 €![Modeling and Simulation for RF System Design]( "Modeling and Simulation for RF System Design")
Modeling and Simulation for RF System Design110,99 €![Multi-Standard CMOS Wireless Receivers: Analysis and Design]( "Multi-Standard CMOS Wireless Receivers: Analysis and Design")
Multi-Standard CMOS Wireless Receivers: Analysis and Design74,99 €
Present-day scienceand technology have become increasingly based on studies and applications of thin films. This is especiallytrue of solid-state physics, semiconduc tor electronics, integrated optics, computer science, and the like. In these fields, it is necessary to use filmswith an ordered structure, especiallysingle-crystallinefilms, because physical phenomena and effects in such films are most reproducible. Also, active parts of semiconductor and other devices and circuits are created, as a rule, in single-crystal bodies. To date, single-crystallinefilms have been mainly epitaxial (or heteroepitaxial); i.e., they have been grown on a single-crystalline substrate, and principal trends, e.g., in the evolution of integrated circuits (lCs), have been based on continuing reduction in feature size and increase in the number of components per chip. However, as the size decreases into the submicrometer range, technological and physical limitations in integrated electronics become more and more severe. It is generally believed that a feature size of about 0.1um will have a crucial character. In other words, the present two-dimensional ICs are anticipated to reach their limit of minimization in the near future, and it is realized that further increase of packing density and/or functions might depend on three-dimensional integration. To solve the problem, techniques for preparation of single-crystalline films on arbitrary (including amorphous) substrates are essential.