While ion-beam techniques have been used to create thin films in the semiconductor industry for several decades, these methods have been too costly for other surface treatment applications. However, as manufacturing devices become increasingly smaller, the use of a directed-energy ion beam is finding novel industrial applications that require the custom tailoring of new materials and devices, including magnetic storage devices, photonics, opto-electronics, and molecular transport. Engineering Thin Films and Nanostructures with Ion Beams offers a thorough narrative of the recent advances that make this technology relevant to current and future applications.
Featuring internationally recognized researchers, the book compiles their expertise in a multidimensional source that:
Highlights the mechanisms and visual evidence of the effects of single-ion impacts on metallic surfaces
Considers how ion-beam techniques can help achieve higher disk-drive densities
Introduces gas-cluster ion-beam technology and reviews its precedents
Explains how ion beams are used to aggregate metals and semiconductors into nanoclusters with nonlinear optical properties
Addresses current challenges in building equipment needed to produce nanostructures in an industrial setting
Examines the combination of ion-beam techniques, particularly with physical vapor deposition
Delineates the fabrication of nanopillars, nanoflowers, and interconnected nanochannels in three dimensions by using atomic shadowing techniques
Illustrates the production of nanopores of varying dimensions in polymer films, alloys, and superconductors using ion-beam irradiation
Shows how fingerprints can be made more reliable as forensic evidence by recoil-mixing them into the substrate using ion beams
From the basics of the ion-beam modification of materials to state-of-the-art applications, Engineering Th
