daughton james (10 Ergebnisse)

Zustand: Good. Inscription on the inside cover. Scuff on the covers and page edge. Pages have yellowed. Spine has cracked. Book is still holding nicely and is presentable.

Paperback. Zustand: Brand New. 230 pages. 9.00x6.00x0.52 inches. In Stock.

16 x 24 cm. XXIV, 198 S. XXIV, 198 p. Hardcover. Versand aus Deutschland / We dispatch from Germany via Air Mail. Einband bestoßen, daher Mängelexemplar gestempelt, sonst sehr guter Zustand. Imperfect copy due to slightly bumped cover, apart from this in very good condition. Stamped. Sprache: Englisch.

Zustand: New. In.

Zustand: New. In.

Paperback. Zustand: Brand New. 245 pages. 9.00x6.00x0.51 inches. In Stock.

Taschenbuch. Zustand: Neu. Spin Electronics | David D. Awschalom (u. a.) | Taschenbuch | xxiv | Englisch | 2010 | Springer | EAN 9789048165131 | Verantwortliche Person für die EU: Springer Verlag GmbH, Tiergartenstr. 17, 69121 Heidelberg, juergen[dot]hartmann[at]springer[dot]com | Anbieter: preigu.

Zustand: New. Offers a comparative review of spin electronics ("spintronics") research and development activities in the US, Japan, and Western Europe. This book covers materials, fabrication and characterization of magnetic nanostructures, magnetism and spin control in magnetic nanostructures, magneto-optical properties of semiconductors, and magneto devices. Editor(s): Awschalom, David D.; Buhrman, Robert A. (Cornell University, Ithaca, NY, USA); Daughton, James M. (NVE Corporation, Eden prairie, MN, USA); Molnar, Stephan von (Center for Materials Research and Technology, Florida State University); Roukes, Michael Lee (Condensed Matter Physics, California Institute of Technology, Pasadena, USA). Num Pages: 222 pages, biography. BIC Classification: RBP; RBX; TJF. Category: (P) Professional & Vocational. Dimension: 235 x 155 x 14. Weight in Grams: 564. . 2003. Hardback. . . . . Books ship from the US and Ireland.

Taschenbuch. Zustand: Neu. Druck auf Anfrage Neuware - Printed after ordering - The history of scientific research and technological development is replete with examples of breakthroughs that have advanced the frontiers of knowledge, but seldom does it record events that constitute paradigm shifts in broad areas of intellectual pursuit. One notable exception, however, is that of spin electronics (also called spintronics, magnetoelectronics or magnetronics), wherein information is carried by electron spin in addition to, or in place of, electron charge. It is now well established in scientific and engineering communities that Moore's Law, having been an excellent predictor of integrated circuit density and computer performance since the 1970s, now faces great challenges as the scale of electronic devices has been reduced to the level where quantum effects become significant factors in device operation. Electron spin is one such effect that offers the opportunity to continue the gains predicted by Moore's Law, by taking advantage of the confluence of magnetics and semiconductor electronics in the newly emerging discipline of spin electronics. From a fundamental viewpoine, spin-polarization transport in a material occurs when there is an imbalance of spin populations at the Fermi energy. In ferromagnetic metals this imbalance results from a shift in the energy states available to spin-up and spin-down electrons. In practical applications, a ferromagnetic metal may be used as a source of spin-polarized electronics to be injected into a semiconductor, a superconductor or a normal metal, or to tunnel through an insulating barrier.

Buch. Zustand: Neu. Druck auf Anfrage Neuware - Printed after ordering - The history of scientific research and technological development is replete with examples of breakthroughs that have advanced the frontiers of knowledge, but seldom does it record events that constitute paradigm shifts in broad areas of intellectual pursuit. One notable exception, however, is that of spin electronics (also called spintronics, magnetoelectronics or magnetronics), wherein information is carried by electron spin in addition to, or in place of, electron charge. It is now well established in scientific and engineering communities that Moore's Law, having been an excellent predictor of integrated circuit density and computer performance since the 1970s, now faces great challenges as the scale of electronic devices has been reduced to the level where quantum effects become significant factors in device operation. Electron spin is one such effect that offers the opportunity to continue the gains predicted by Moore's Law, by taking advantage of the confluence of magnetics and semiconductor electronics in the newly emerging discipline of spin electronics. From a fundamental viewpoine, spin-polarization transport in a material occurs when there is an imbalance of spin populations at the Fermi energy. In ferromagnetic metals this imbalance results from a shift in the energy states available to spin-up and spin-down electrons. In practical applications, a ferromagnetic metal may be used as a source of spin-polarized electronics to be injected into a semiconductor, a superconductor or a normal metal, or to tunnel through an insulating barrier.