Read book An Essential Guide to Electronic Material Surfaces and Interfaces in DJV, PDF
9781119027119 English 111902711X An Essential Guide to Electronic Material Surfaces and Interfaces is a streamlined yet comprehensive introduction that covers the basic physical properties of electronic materials, the experimental techniques used to measure them, and the theoretical methods used to understand, predict, and design them. Starting with the fundamental electronic properties of semiconductors and electrical measurements of semiconductor interfaces, this text introduces students to the importance of characterizing and controlling macroscopic electrical properties by atomic-scale techniques. The chapters that follow present the full range of surface and interface techniques now being used to characterize electronic, optical, chemical, and structural properties of electronic materials, including semiconductors, insulators, nanostructures, and organics. The essential physics and chemistry underlying each technique is described in sufficient depth for students to master the fundamental principles, with numerous examples to illustrate the strengths and limitations for specific applications. As well as references to the most authoritative sources for broader discussions, the text includes internet links to additional examples, mathematical derivations, tables, and literature references for the advanced student, as well as professionals in these fields. This textbook fills a gap in the existing literature for an entry-level course that provides the physical properties, experimental techniques, and theoretical methods essential for students and professionals to understand and participate in solid-state electronics, physics, and materials science research. An Essential Guide to Electronic Material Surfaces and Interfaces is an introductory-to-intermediate level textbook suitable for students of physics, electrical engineering, materials science, and other disciplines. It is essential reading for any student or professional engaged in surface and interface research, semiconductor processing, or electronic device design., An introductory level textbook for students of physics, electrical engineering, materials science, and other disciplines who are new to the field of electronic materials, solid state devices, the measurement and control of their surfaces and interfaces at the atomic scale, and their impact on electronic properties at the macroscopic, laboratory scale. It provides a streamlined yet comprehensive introduction to surface and interfaces of electronic materials that covers all of their basic physical properties, the experimental techniques used to measure them, and the theoretical methods used to understand, predict, and design them. This information is essential for any student or professional engaged in surface and interface research, semiconductor processing, or electronic device design. It is structured to cover all aspects of electronic material properties, experimental techniques, and theoretical methods at an introductory-to-intermediate level, while providing advanced concepts for each topic online. It contains examples in the text and problem sets with solutions available to instructors. Case studies and illustrations that highlight key concepts are supplied online. Lecture slides are available to registered instructors for a semester-length course. Starting with the fundamental electronic properties of semiconductors and electrical measurements of semiconductor interfaces, it introduces students to the importance of characterizing and controlling macroscopic electrical properties by atomic-scale techniques. The chapters that follow present the full range of surface and interface techniques now being used to characterize electronic, optical, chemical, and structural properties of electronic materials, including semiconductors, insulators, nanostructures, and organics. The essential physics and chemistry underlying each technique is described in sufficient depth for students to master their fundamental principles with numerous examples to illustrate their strengths and limitations for specific applications. Besides references to the most authoritative sources for broader discussions, the text includes Internet links to additional examples, mathematical derivations, tables, and literature references for the advanced student as well as professionals in these fields. This textbook fills a gap in the existing literature for an entry-level course that provides the physical properties, experimental techniques, and theoretical methods essential for students and professionals to understand and participate in solid-state electronics, physics, and materials science research.
9781119027119 English 111902711X An Essential Guide to Electronic Material Surfaces and Interfaces is a streamlined yet comprehensive introduction that covers the basic physical properties of electronic materials, the experimental techniques used to measure them, and the theoretical methods used to understand, predict, and design them. Starting with the fundamental electronic properties of semiconductors and electrical measurements of semiconductor interfaces, this text introduces students to the importance of characterizing and controlling macroscopic electrical properties by atomic-scale techniques. The chapters that follow present the full range of surface and interface techniques now being used to characterize electronic, optical, chemical, and structural properties of electronic materials, including semiconductors, insulators, nanostructures, and organics. The essential physics and chemistry underlying each technique is described in sufficient depth for students to master the fundamental principles, with numerous examples to illustrate the strengths and limitations for specific applications. As well as references to the most authoritative sources for broader discussions, the text includes internet links to additional examples, mathematical derivations, tables, and literature references for the advanced student, as well as professionals in these fields. This textbook fills a gap in the existing literature for an entry-level course that provides the physical properties, experimental techniques, and theoretical methods essential for students and professionals to understand and participate in solid-state electronics, physics, and materials science research. An Essential Guide to Electronic Material Surfaces and Interfaces is an introductory-to-intermediate level textbook suitable for students of physics, electrical engineering, materials science, and other disciplines. It is essential reading for any student or professional engaged in surface and interface research, semiconductor processing, or electronic device design., An introductory level textbook for students of physics, electrical engineering, materials science, and other disciplines who are new to the field of electronic materials, solid state devices, the measurement and control of their surfaces and interfaces at the atomic scale, and their impact on electronic properties at the macroscopic, laboratory scale. It provides a streamlined yet comprehensive introduction to surface and interfaces of electronic materials that covers all of their basic physical properties, the experimental techniques used to measure them, and the theoretical methods used to understand, predict, and design them. This information is essential for any student or professional engaged in surface and interface research, semiconductor processing, or electronic device design. It is structured to cover all aspects of electronic material properties, experimental techniques, and theoretical methods at an introductory-to-intermediate level, while providing advanced concepts for each topic online. It contains examples in the text and problem sets with solutions available to instructors. Case studies and illustrations that highlight key concepts are supplied online. Lecture slides are available to registered instructors for a semester-length course. Starting with the fundamental electronic properties of semiconductors and electrical measurements of semiconductor interfaces, it introduces students to the importance of characterizing and controlling macroscopic electrical properties by atomic-scale techniques. The chapters that follow present the full range of surface and interface techniques now being used to characterize electronic, optical, chemical, and structural properties of electronic materials, including semiconductors, insulators, nanostructures, and organics. The essential physics and chemistry underlying each technique is described in sufficient depth for students to master their fundamental principles with numerous examples to illustrate their strengths and limitations for specific applications. Besides references to the most authoritative sources for broader discussions, the text includes Internet links to additional examples, mathematical derivations, tables, and literature references for the advanced student as well as professionals in these fields. This textbook fills a gap in the existing literature for an entry-level course that provides the physical properties, experimental techniques, and theoretical methods essential for students and professionals to understand and participate in solid-state electronics, physics, and materials science research.