Introduction to Light Trapping in Solar Cell and Photo-detector Devices

Informationen zum Autor Dr. Stephen Fonash is Bayard D. Kunkle Chair Professor Emeritus of Engineering Sciences at Penn State University and Chief Technology Officer of Solarity LCCM, LLC. His activities at Penn State include serving as the director of Penn State's Center for Nanotechnology Education and Utilization (CNEU), director of the National Science Foundation Advanced Technology Education Center, and director of the Pennsylvania Nanofabrication Manufacturing Technology Partnership. Prof. Fonash's education contributions focus on nanotechnology post-secondary education and workforce development. His research activities encompass the processing and device physics of micro- and nanostructures including solar cells, sensors, and transistors. He has published over 300 refereed papers in the areas of education, nanotechnology, photovoltaics, microelectronics devices and processing, sensors, and thin film transistors. His book Solar Cell Device Physics? has been termed the bible of solar cell physics? and his solar cell computer modeling code AMPS is used by almost 800 groups around the world. Dr. Fonash holds 29 patents in his research areas, many of which are licensed to industry. He is on multiple journal boards, serves as an advisor to university and government groups, has consulted for a variety of firms, and has co-founded two companies. Prof. Fonash received his Ph.D. from the University of Pennsylvania. He is a Fellow of the Institute of Electrical and Electronics Engineers and a Fellow of the Electrochemical Society Klappentext Nonequilibrium Thermodynamics! Third Edition explores the unifying role of thermodynamics in natural phenomena. Natural phenomena consist of simultaneously occurring transport processes and chemical reactions! and these processes may interact with each other! leading to instabilities! fluctuations! and evolutionary systems. This book analyzes the transport processes of energy! mass! and momentum transfer processes! as well as chemical reactions. It considers various processes occurring simultaneously and provides you with more realistic analysis and modeling by accounting for possible interactions between them.This third edition is fully updated and revised! expanding on previous editions by adding new chapters on fluctuation theory! extended nonequilibrium thermodynamics! mesoscopic nonequilibrium thermodynamics! and nonequilibrium thermodynamics modeling of coupled biochemical cycles. More examples and practice problems have been added as well! making this book a valuable resource for graduate students in areas such as chemical! biological! mechanical! biomedical! environmental! and systems engineering programs. ...

Autorentext

Nonequilibrium Thermodynamics, Third Edition explores the unifying role of thermodynamics in natural phenomena. Natural phenomena consist of simultaneously occurring transport processes and chemical reactions, and these processes may interact with each other, leading to instabilities, fluctuations, and evolutionary systems. This book analyzes the transport processes of energy, mass, and momentum transfer processes, as well as chemical reactions. It considers various processes occurring simultaneously and provides you with more realistic analysis and modeling by accounting for possible interactions between them.

This third edition is fully updated and revised, expanding on previous editions by adding new chapters on fluctuation theory, extended nonequilibrium thermodynamics, mesoscopic nonequilibrium thermodynamics, and nonequilibrium thermodynamics modeling of coupled biochemical cycles. More examples and practice problems have been added as well, making this book a valuable resource for graduate students in areas such as chemical, biological, mechanical, biomedical, environmental, and systems engineering programs.

Inhalt

• Dedication
• Preface

• Chapter 1: A Brief Overview of Phenomena Involved in Light Trapping

  • Abstract
  • 1.1. Interference
  • 1.2. Scattering
  • 1.3. Reflection
  • 1.4. Diffraction
  • 1.5. Plasmonics
  • 1.6. Refraction

• Chapter 2: Modes and Hybridization

  • Abstract
  • 2.1. Introductory comments
  • 2.2. Radiation modes
  • 2.3. Trapped traveling modes: guided modes
  • 2.4. Trapped traveling modes: Bloch modes
  • 2.5. Trapped localized modes: Mie modes and plasma modes

• Chapter 3: Light-Trapping Structures

  • Abstract
  • 3.1. Introduction
  • 3.2. Planar structures with ARCs
  • 3.3. Planar structures with randomly textured surfaces
  • 3.4. Structures with nanoelement arrays
  • 3.5. Structures with plasmonic effects

• Chapter 4: Summary

  • Abstract
  • 4.1. The current picture
  • 4.2. Some future directions?
  • 4.3. Overview
• Appendix A: Yablonovitch Limit Derivation
• Appendix B: Fresnel Equations for the Situation of Section 2.2
• Appendix C: Index of Refraction, Permittivity, and Absorption Coefficient
• References