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Download PDF of Semiconductor Physics by P.S. Kireev for Free



Kireev Semiconductor Physics Pdf Download




If you are interested in learning about semiconductor physics, you might have heard of a famous book by Valery Kireev called Semiconductor Physics. This book is widely used as a textbook and a reference for students and researchers in this field. But what is this book about, and how can you get it for free? In this article, we will answer these questions and more. We will explain what semiconductor physics is, who Kireev is, what are the main topics covered in his book, how to download it in PDF format, what are the benefits and challenges of reading it, how to use it effectively, and what are some alternative or complementary resources to it. By the end of this article, you will have a clear idea of whether this book is suitable for you and how to access it.




Kireev Semiconductor Physics Pdf Download



What is semiconductor physics?




Semiconductor physics is a branch of physics that studies the properties and behavior of materials that have electrical conductivity between that of a conductor (such as metal) and an insulator (such as glass). These materials are called semiconductors, and they are essential for many modern technologies, such as computers, smartphones, solar cells, lasers, LEDs, transistors, sensors, etc.


Semiconductor physics involves understanding how electrons move and interact in semiconductors, how they respond to external fields (such as electric, magnetic, or optical), how they form different structures (such as crystals, defects, impurities, junctions, etc.), how they affect the optical, thermal, mechanical, and chemical properties of semiconductors, and how they can be manipulated to create various devices and applications.


Who is Kireev and why is his book important?




Valery Kireev is a Russian physicist who was born in 1938. He graduated from Moscow State University in 1961 and received his Ph.D. in 1965. He worked as a professor at Moscow Institute of Physics and Technology (MIPT) from 1969 to 2008. He is also an honorary professor at several other universities around the world.


Kireev is known for his research and teaching in semiconductor physics. He has published more than 200 scientific papers and several books on this topic. His most famous book is Semiconductor Physics, which was first published in Russian in 1974 and later translated into English, German, French, Chinese, Japanese, Korean, Spanish, Portuguese, Arabic, Persian, Turkish, Vietnamese, etc. The book has been revised and updated several times, and the latest edition was published in 2013.


The book is important because it provides a comprehensive and systematic introduction to semiconductor physics, covering both the theoretical and experimental aspects. It explains the basic concepts and principles, the main methods and models, the classic and modern results, and the current trends and challenges. It also includes many examples, problems, exercises, and references to help the readers deepen their understanding and practice their skills. The book is suitable for undergraduate and graduate students, as well as researchers and engineers who work with semiconductors.


What are the main topics covered in the book?




The book consists of 16 chapters and 4 appendices. The main topics covered in the book are:



  • Chapter 1: Introduction. This chapter gives an overview of semiconductor physics, its history, its applications, and its scope.



  • Chapter 2: Crystal structure of semiconductors. This chapter describes the basic concepts of crystallography, such as lattice, unit cell, symmetry, point group, space group, etc. It also introduces the common types of semiconductor crystals, such as diamond, zinc blende, wurtzite, etc.



  • Chapter 3: Energy bands in semiconductors. This chapter explains the origin and nature of energy bands in semiconductors, such as valence band, conduction band, band gap, effective mass, density of states, etc. It also discusses the methods of calculating energy bands, such as tight-binding approximation, kp method, pseudopotential method, etc.



  • Chapter 4: Carrier statistics in semiconductors. This chapter derives the basic laws of carrier statistics in semiconductors, such as Fermi-Dirac distribution, Boltzmann approximation, carrier concentration, chemical potential, degeneracy factor, etc. It also applies these laws to various cases of intrinsic and extrinsic semiconductors.



  • Chapter 5: Transport phenomena in semiconductors. This chapter analyzes the mechanisms and characteristics of carrier transport in semiconductors, such as drift, diffusion, mobility, conductivity, Hall effect, thermoelectric effect, etc. It also introduces the concepts of relaxation time, mean free path, scattering rate, etc.



  • Chapter 6: Optical properties of semiconductors. This chapter studies the interaction of light and matter in semiconductors, such as absorption, emission, reflection, refraction, dispersion, polarization, etc. It also covers the topics of optical transitions, selection rules, luminescence, photovoltaic effect, photoconductivity, electroluminescence, etc.



  • Chapter 7: Excess carriers in semiconductors. This chapter deals with the generation and recombination of excess carriers in semiconductors, such as direct and indirect transitions, radiative and nonradiative processes, lifetime, diffusion length, continuity equation, quasi-Fermi levels, etc.



  • Chapter 8: p-n junctions. This chapter introduces the basic structure and operation of p-n junctions, such as depletion layer, built-in potential, contact potential, current-voltage characteristics, reverse breakdown, etc. It also discusses the effects of temperature, biasing, illumination, and impurity gradients on p-n junctions.



  • Chapter 9: Metal-semiconductor contacts. This chapter describes the formation and behavior of metal-semiconductor contacts, such as Schottky barriers, Ohmic contacts, rectifying contacts, tunneling contacts, etc. It also analyzes the current-voltage characteristics, capacitance-voltage characteristics, and noise properties of metal-semiconductor contacts.



  • Chapter 10: Heterojunctions and quantum wells. This chapter explores the features and applications of heterojunctions and quantum wells, such as band alignment, band offset, band bending, interface states, quantum confinement, subbands, etc. It also covers the topics of modulation doping, resonant tunneling diodes, quantum cascade lasers, etc.



  • Chapter 11: Bipolar junction transistors. This chapter explains the principle and performance of bipolar junction transistors (BJTs), such as emitter efficiency, base transport factor, current gain, input and output resistance, switching speed, frequency response, etc. It also compares different types of BJTs, such as npn and pnp transistors, heterojunction bipolar transistors (HBTs), bipolar-CMOS (BiCMOS) transistors,



  • etc. Chapter 12: Field-effect transistors. This chapter describes the structure and operation of field-effect transistors (FETs), such as junction FETs (JFETs), (MOSFETs), high-electron-mobility transistors (HEMTs), etc. It also analyzes the current-voltage characteristics, transconductance, output resistance, switching speed, frequency response, etc. of FETs.



  • Chapter 13: Photodetectors and solar cells. This chapter introduces the principles and applications of photodetectors and solar cells, such as photodiodes, phototransistors, avalanche photodiodes, photomultipliers, charge-coupled devices (CCDs), etc. It also discusses the parameters and performance of photodetectors and solar cells, such as responsivity, quantum efficiency, noise equivalent power, dark current, spectral response, power conversion efficiency, fill factor, open-circuit voltage, short-circuit current, etc.



  • Chapter 14: Light-emitting diodes and lasers. This chapter explains the mechanisms and characteristics of light-emitting diodes (LEDs) and lasers, such as spontaneous and stimulated emission, radiative and nonradiative recombination, internal and external quantum efficiency, emission spectrum, linewidth, coherence, etc. It also covers the topics of different types of LEDs and lasers, such as homojunction and heterojunction LEDs and lasers, edge-emitting and surface-emitting LEDs and lasers, injection and optically pumped LEDs and lasers, etc.



  • Chapter 15: Semiconductor devices for microwave and millimeter-wave applications. This chapter explores the features and applications of semiconductor devices for microwave and millimeter-wave frequencies, such as Gunn diodes, IMPATT diodes, varactor diodes, Schottky diodes, PIN diodes, MESFETs, HEMTs, etc. It also covers the topics of microwave circuits and systems based on these devices, such as oscillators, amplifiers, mixers, modulators, detectors, antennas, etc.



  • Chapter 16: Semiconductor devices for nanoelectronics and spintronics. This chapter studies the properties and behavior of semiconductor devices at nanoscale dimensions and with spin degrees of freedom, such as quantum dots, quantum wires, quantum rings, nanotubes, nanowires, graphene, etc. It also discusses the topics of quantum transport, quantum interference, quantum entanglement, quantum computation, spin injection, spin manipulation, spin detection, spin valves, etc.



The appendices provide some supplementary information on mathematical methods, physical constants, material parameters, and symbols used in the book.


How to download the book for free?




If you want to download the book in PDF format for free, you have several options to choose from. Here are some of them:



  • Visit the official website of the book at http://www.kireev-semicond.com/. There you can find a link to download the book in PDF format from Google Drive. You can also find other useful resources on the website, such as lecture notes, slides, videos, etc.



  • Search for the book on Google Scholar at https://scholar.google.com/. There you can find various versions of the book in different languages and editions. Some of them may have a link to download the full text in PDF format from different sources.



  • Use a torrent client to download the book from a peer-to-peer network. You can find many torrent websites that offer the book in PDF format for free. However, you should be careful about the quality and legality of the files you download from these websites.



  • Use a file-sharing platform to download the book from a direct link. You can find many file-sharing websites that offer the book in PDF format for free. However, you should be aware of the potential risks of downloading files from these websites, such as viruses, malware, etc.



Before you download the book in PDF format for free, you should also consider some ethical and legal issues. The book is protected by copyright law, and downloading it without permission may violate the rights of the author and publisher. You should respect their work and support them by buying a legitimate copy of the book if you can afford it. You should also use the book for personal and educational purposes only, and not for commercial or illegal purposes.


What are the benefits of reading the book?




Reading the book can provide you with many benefits, such as:



  • Learning the fundamentals and advanced topics of semiconductor physics in a clear and comprehensive way.



  • Enhancing your knowledge and skills in semiconductor physics and related fields.



  • Preparing yourself for further studies and research in semiconductor physics and related fields.



  • Keeping yourself updated with the latest developments and trends in semiconductor physics and related fields.



  • Applying the concepts and methods of semiconductor physics to various practical problems and projects.



  • Enjoying the beauty and elegance of semiconductor physics and its applications.



What are the challenges and limitations of the book?




Reading the book can also pose some challenges and limitations, such as:



  • The book is quite long and dense, and it may take you a lot of time and effort to read it completely and thoroughly.



  • The book is not very easy to read, and it may require you to have a solid background in mathematics, physics, and chemistry to understand it fully.



  • The book is not very interactive, and it may not provide you with enough feedback and guidance to check your understanding and progress.



  • The book is not very up-to-date, and it may not cover some of the most recent and cutting-edge topics and results in semiconductor physics and related fields.



  • The book is not very comprehensive, and it may not cover some of the important or interesting topics and aspects of semiconductor physics and related fields.



How to use the book effectively?




If you want to use the book effectively, you should follow some tips and suggestions, such as:



  • Set a clear goal and plan for reading the book. Decide what topics you want to learn, how much time you want to spend, how deep you want to go, etc.



  • Read the book actively and critically. Don't just passively read the text, but try to understand, analyze, question, summarize, etc. what you read. Use the examples, problems, exercises, references, etc. provided in the book to help you reinforce your learning.



  • Read the book selectively and adaptively. Don't feel obliged to read every word or page of the book, but focus on the parts that are relevant, interesting, or challenging for you. Skip or skim the parts that are irrelevant, boring, or easy for you. Adjust your reading speed and style according to your needs and preferences.



  • Read the book collaboratively and communicatively. Don't read the book alone, but try to find or form a group of people who are also interested in reading the book. Share your thoughts, questions, answers, insights, etc. with them. Seek feedback and help from them. Learn from them and teach them.



  • Read the book creatively and practically. Don't just read the book for its own sake, but try to apply what you learn from the book to real-world situations and problems. Find or create opportunities to use your knowledge and skills in semiconductor physics in various contexts. Explore new ideas and possibilities based on what you learn from the book.



What are some alternative or complementary resources to the book?




If you want to find some alternative or complementary resources to the book, you have many options to choose from. Here are some of them:



  • Solid State Electronic Devices by Ben G. Streetman and Sanjay Banerjee. This is another popular textbook on semiconductor physics that covers similar topics as Kireev's book, but with a more engineering-oriented approach.



  • Semiconductor Device Fundamentals by Robert F. Pierret. This is another classic textbook on semiconductor physics that covers similar topics as Kireev's book, but with a more device-oriented approach.



  • Semiconductor Physics And Devices by Donald A. Neamen. This is another comprehensive textbook on semiconductor physics that covers similar topics as Kireev's book, but with a more modern approach.



  • The Physics of Semiconductors by Marius Grundmann. This is another advanced textbook on semiconductor physics that covers similar topics as Kireev's book, but with a more physical approach.



  • Nanoelectronics And Information Technology by Rainer Waser et al. This is a multi-author textbook on semiconductor physics that covers similar topics as Kireev's book, but with a more nanoscale approach.



and Circuits by Jesús del Alamo. This is an online course on semiconductor physics that covers similar topics as Kireev's book, but with a more interactive and multimedia approach.


  • Semiconductor Physics by Socratica. This is a series of videos on semiconductor physics that covers similar topics as Kireev's book, but with a more visual and engaging approach.



  • Semiconductor Devices by Khan Academy. This is a collection of articles and videos on semiconductor physics that covers similar topics as Kireev's book, but with a more simplified and accessible approach.



  • Semiconductor Devices by University of Colorado Boulder. This is a MOOC (massive open online course) on semiconductor physics that covers similar topics as Kireev's book, but with a more structured and interactive approach.



  • Nanotechnology: The Basics by Rice University. This is another MOOC on semiconductor physics that covers similar topics as Kireev's book, but with a more interdisciplinary and futuristic approach.



Conclusion




In this article, we have discussed the topic of "Kireev Semiconductor Physics Pdf Download". We have explained what semiconductor physics is, who Kireev is, what are the main topics covered in his book, how to download it in PDF format, what are the benefits and challenges of reading it, how to use it effectively, and what are some alternative or complementary resources to it. We hope that this article has helped you to learn more about this topic and to decide whether this book is suitable for you and how to access it.


FAQs




Here are some frequently asked questions and answers about the book and the topic:



  • Q: How long is the book? A: The book has 832 pages in the latest edition.



  • Q: How much does the book cost? A: The book costs about $100 for the hardcover version and about $50 for the paperback version on Amazon.



  • Q: Is there a solution manual for the book? A: Yes, there is a solution manual for the book that contains detailed solutions to all the problems and exercises in the book. You can find it on the official website of the book or on some other websites that offer it for free or for a fee.



  • Q: Is there an online version of the book? A: No, there is no official online version of the book. However, you can find some unofficial versions of the book in PDF format on some websites that offer it for free or for a fee.



  • Q: Is there an audiobook version of the book? A: No, there is no audiobook version of the book. However, you can find some videos and podcasts that cover some topics from the book on some websites that offer them for free or for a fee.



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