Cover of: Spontaneous Ordering in Semiconductor Alloys | Angelo Mascarenhas

Spontaneous Ordering in Semiconductor Alloys

  • 473 Pages
  • 0.71 MB
  • 587 Downloads
  • English
by
Springer US, Imprint, Springer , Boston, MA
Surfaces (Physics), Physics, Optical mate
Statementedited by Angelo Mascarenhas
Classifications
LC ClassificationsQC1-75
The Physical Object
Format[electronic resource] /
Pagination1 online resource (473 pages)
ID Numbers
Open LibraryOL27088814M
ISBN 10146150631X
ISBN 139781461506317
OCLC/WorldCa840283440

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Spontaneous Ordering in Semiconductor Alloys. Title Spontaneous Ordering in Semiconductor Alloys. The various chapters of this book provide a detailed account of these efforts during the past decade.

Spontaneous Ordering in Semiconductor Alloys [Mascarenhas, Angelo] on *FREE* shipping on qualifying offers. Spontaneous Ordering in Semiconductor AlloysFormat: Paperback. Spontaneous Ordering in Semiconductor Alloys 1st Edition, Kindle Edition by Angelo Mascarenhas (Editor) › Visit Amazon's Angelo Mascarenhas Page.

Find all the books, read about the author, and more. See search results for this author. Are you an author. Manufacturer: Springer. The phenomenonofspontaneous ordering in semiconductoralloys, which can be categorized as a self-organized process, is observed to occur sponta­ neously during epitaxial growth of certain ternary alloy semiconductors and results in a modification of their structural, electronic, and optical.

"The phenomenon of spontaneous ordering in semiconductor alloys, which can be Spontaneous Ordering in Semiconductor Alloys book as a self-organized process, is observed to occur spontaneously during epitaxial growth of certain ternary alloy semiconductors and results in a modification of their structural, electronic, and optical properties.

Get this from a library. Spontaneous Ordering in Semiconductor Alloys. [Angelo Mascarenhas] -- This book presents a comprehensive account of the phenomenon of spontaneous ordering. The phenomenon, which can be categorized as a self-organized process, is observed to occur spontaneously during.

used to investigate details of the ordering mechanism. In this chapter we will provide a brief review of the various studies that have been done as regards the intrinsic and extrinsic changes to the electronic and optical properties that result from spontaneous ordering in epitaxially grown semiconductor alloys.

The phenomenonofspontaneous ordering in semiconductoralloys, which can be categorized as a self-organized process, is observed to occur sponta neously during epitaxial growth of certain ternary alloy semiconductors and results in a modification of their structural, electronic, and optical properties.

There has been a great dealofinterest in learning how to control this phenome non so that it. Download Citation | Basic Aspects of Atomic Ordering in III–V Semiconductor Alloys | Basic aspects of atomic ordering in III-V semiconductor alloys are described, with an emphasis on ordering Author: Tohru Suzuki.

As with all materials, engineering semiconductors primarily involves formation of alloys and control of defects. Defect engineering is discussed in detail in Chapter 7. This chapter considers the basics of alloying.

The objective is usually to control the optoelectronic properties of the semiconductor, primarily through its energy band structure.

Spontaneous LRO is a well-known phenomenon in semiconductor alloys which has been intensively studied in the past two decades. The layered trigonal CuPt B structure has been first predicted for InGaP by Srivastava et al.

(), and experimentally observed in the system AlGaAs by Kuan et al. Quadruple-period ordering in MBE GaAsSb alloys Iskander G. Batyrev, Andrew G.

Description Spontaneous Ordering in Semiconductor Alloys PDF

Norman, Shengbai Zhang, and Su-Huai Wei National Renewable Energy Laboratory. Mascarenhas and Y. Zhang, The physics of tunable disorder in semiconductor alloys, in Spontaneous Ordering in Semiconductor Alloys, edited by A. Mascarenhas (Kluwer Academic/Plenum Publishers, New York, ), p.

Prof. Alex Zunger of the University of Colorado, the Hume- Rothery Award on Theory of alloys, Romana “ celebrating the tradition of E. Fermi, the John Bardeen award of The Material Society on “Spontaneous Ordering in semiconductor alloys”, the.

Spontaneous Ordering 11 (a) Group-IV Semiconductor Alloy 11 (b) III–V Semiconductor Alloy 14 (c) II–VI Semiconductor Alloy 15 Lattice Constant and Related Parameters 15 CuAu Alloy: Ordered and Disordered States 15 Non-alloyed Semiconductor 16 Semiconductor Alloy 19 (a) Group-IV Semiconductor 19 (b) III–V.

Spontaneous Ordering 11 (a) Group-IV Semiconductor Alloy 11 (b) III–V Semiconductor Alloy 14 (c) II–VI Semiconductor Alloy 15 Lattice Constant and Related Parameters 15 CuAu Alloy: Ordered and Disordered States 15 Non-alloyed Semiconductor 16 Semiconductor Alloy 19 (a) Group-IV Semiconductor 19 (b) III–V File Size: KB.

He has supervised 22 postdoctoral scientists and 3 Ph.D. students, is an author of about scientific publications, six book chapters, seven invited papers, editor of a book on Spontaneous Ordering, and has three issued patents (6 pending). He is a fellow of RASEI, a.

Spontaneous Ordering in Semiconductor Alloys Angelo Mascarenhas The phenomenonofspontaneous ordering in semiconductoralloys, which can be categorized as a self-organized process, is observed to occur sponta neously during epitaxial growth of certain ternary alloy semiconductors and results in a modification of their structural, electronic, and.

The main purpose of this book is to provide a comprehensive treatment of the materials aspects of group-IV, III−V and II−VI semiconductor alloys used in various electronic and optoelectronic devices. The topics covered in this book include the structural, thermal, mechanical, lattice vibronic, electronic, optical and carrier transport properties of such semiconductor alloys.

Spontaneous Ordering in Semiconductor Alloys Angelo Mascarenhas The phenomenonofspontaneous ordering in semiconductoralloys, which can be categorized as a self-organized process, is observed to occur sponta neously during epitaxial growth of certain ternary alloy semiconductors and results in a modification of their structural, electronic, and /5(2).

Angelo Mascarenhas, Ph.D., is a principal semiconductor alloy instabilities such as spontaneous ordering and spontaneous composition modulation for optoelectronic applications. His current research focuses on the phenomenon of isoelectronic co-doping for tailoring the optical properties of semiconductor alloys and its applications to very.

Alex Zunger is a theoretical physicist,Research Professor, at the University of Colorado Boulder. He has authored more than papers in Physical Review Letters and PRB Rapid Communication, has an h-index overnumber of citations o (Google Scholar); and authored the fifth-most cited paper ever to be published in Physical Review since Awards: Boer Medal for fundamental solar energy.

Unusual physics in III-V alloys: Spontaneous ordering and wavefunction localization. Conference Series- Institute of Physics.

; Biaxial strain-modified valence and conduction band offsets of zinc-blende GaN, GaP, GaAs, InN, InP, and InAs, and optical bowing of strained epitaxial InGaN alloys. Spontaneous Ordering in Semiconductor Alloys, p. DOI: /_15 Interplay of alloying and ordering on the electronic structure of Ga x In 1 − x P alloys journal.

He is the recipient of the year Hume-Rothery Award on Theory of alloys, the (inaugural) “Materials Theory Award” of the Materials Research Society on Inverse Design, the “Tomassoni Prize“ (Italy) and “ Medal of the Schola Physica Romana “ celebrating the tradition of E.

Fermi, the John Bardeen awardof The. Book Search tips Selecting this option will search all publications across the Scitation platform Selecting this option will search all publications for the Publisher/Society in context.

Suzuki, in Spontaneous Ordering in Semiconductor Alloys, edited by A. Mascarenhas ( Cited by: 2. The 26th International Conference on the Physics of Semiconductors was held from 29 July to 2 August at the Edinburgh International Conference Centre.

It is the premier meeting in the field of semiconductor physics and attracted over participants from leading academic, governmental and industrial institutions in some 50 countries around tAuthor: J.H Davies, A.R Long.

The topics covered in this book include the structural, thermal, mechanical, lattice vibronic, electronic, optical and carrier transport properties of such semiconductor alloys. The book reviews not only commonly known alloys (SiGe, AlGaAs, GaInPAs, and ZnCdTe) but also new alloys, such as dilute-carbon alloys (CSiGe, CSiSn, etc.), III−N.

Spontaneous Ordering in Semiconductor Alloys, p. DOI: /_11 A % efficient Ga In P/GaAs tandem solar cell journal, February Alloys Introduction p. 45 Atomic Ordering in Group III-V Antimonide Semiconductors Alloys p. 49 Nature of Ordering p. 49 Origins of Atomic Ordering in Semiconductor Alloys p.

63 CuPt-Type Atomic Ordering p. 63 Antiphase Superlattice in MBE GaAsSb Grown at High Temperature p. 85 CuAu-I Type Ordering in Layers Grown on () Substrates p.

Book chapter in "Spontaneous Ordering in Semiconductor Alloys", ed. A. Mascarenhas Book chapter in "Spontaneous Ordering in Semiconductor Alloys", ed.

A. MascarenhasTitle: Research Facilities Manager / .Ferromagnetism is the basic mechanism by which certain materials (such as iron) form permanent magnets, or are attracted to physics, several different types of magnetism are distinguished.

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Ferromagnetism (along with the similar effect ferrimagnetism) is the strongest type and is responsible for the common phenomenon of magnetism in magnets encountered in everyday life.semiconductor alloys grown by MBE. Our effort is directed toward two problems representing distinctly different facets of a common material system: InAsSb.

Project 1, undertaken jointly with Sandia National Laboratories, assesses the difference between the as–grown and intended [] antimony profile in an InAs / InAsSb strained–.