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Semiconductor Laser Engineering, Reliability and Diagnostics: A Practical Approach to High Power and Single Mode Devices, by Peter W. Eppe
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This reference book provides a fully integrated novel approach to the development of high-power, single-transverse mode, edge-emitting diode lasers by addressing the complementary topics of device engineering, reliability engineering and device diagnostics in the same book, and thus closes the gap in the current book literature.
Diode laser fundamentals are discussed, followed by an elaborate discussion of problem-oriented design guidelines and techniques, and by a systematic treatment of the origins of laser degradation and a thorough exploration of the engineering means to enhance the optical strength of the laser. Stability criteria of critical laser characteristics and key laser robustness factors are discussed along with clear design considerations in the context of reliability engineering approaches and models, and typical programs for reliability tests and laser product qualifications. Novel, advanced diagnostic methods are reviewed to discuss, for the first time in detail in book literature, performance- and reliability-impacting factors such as temperature, stress and material instabilities.
Further key features include:
- practical design guidelines that consider also reliability related effects, key laser robustness factors, basic laser fabrication and packaging issues;
- detailed discussion of diagnostic investigations of diode lasers, the fundamentals of the applied approaches and techniques, many of them pioneered by the author to be fit-for-purpose and novel in the application;
- systematic insight into laser degradation modes such as catastrophic optical damage, and a wide range of technologies to increase the optical strength of diode lasers;
- coverage of basic concepts and techniques of laser reliability engineering with details on a standard commercial high power laser reliability test program.
Semiconductor Laser Engineering, Reliability and Diagnostics reflects the extensive expertise of the author in the diode laser field both as a top scientific researcher as well as a key developer of high-power highly reliable devices. With invaluable practical advice, this new reference book is suited to practising researchers in diode laser technologies, and to postgraduate engineering students.
Dr. Peter W. Epperlein is Technology Consultant with his own semiconductor technology consulting business Pwe-PhotonicsElectronics-IssueResolution in the UK. He looks back at a thirty years career in cutting edge photonics and electronics industries with focus on emerging technologies, both in global and start-up companies, including IBM, Hewlett-Packard, Agilent Technologies, Philips/NXP, Essient Photonics and IBM/JDSU Laser Enterprise. He holds Pre-Dipl. (B.Sc.), Dipl. Phys. (M.Sc.) and Dr. rer. nat. (Ph.D.) degrees in physics, magna cum laude, from the University of Stuttgart, Germany.
Dr. Epperlein is an internationally recognized expert in compound semiconductor and diode laser technologies. He has accomplished R&D in many device areas such as semiconductor lasers, LEDs, optical modulators, quantum well devices, resonant tunneling devices, FETs, and superconducting tunnel junctions and integrated circuits. His pioneering work on sophisticated diagnostic research has led to many world’s first reports and has been adopted by other researchers in academia and industry. He authored more than seventy peer-reviewed journal papers, published more than ten invention disclosures in the IBM Technical Disclosure Bulletin, has served as reviewer of numerous proposals for publication in technical journals, and has won five IBM Research Division Awards. His key achievements include the design and fabrication of high-power, highly reliable, single mode diode lasers.
Book Reviews
“Semiconductor L
- Sales Rank: #1819262 in eBooks
- Published on: 2013-01-25
- Released on: 2013-01-25
- Format: Kindle eBook
Review
“Dr. Epperlein’s book is an essential read for anyone looking to develop semiconductor lasers for anything other than pure research use, and I give it my highest recommendation.” (Robert W. Herrick, Ph.D -Senior Component Reliability Engineer, 1 May 2013)
“I can highly recommend this extremely relevant, well-structured and well-formulated book to all practising researchers in industrial and academic diode laser R&D environments and to post-graduate engineering students interested in the actual problems of designing, manufacturing, testing, characterising and qualifying diode lasers. Due to its completeness and novel approach to combine design, reliability and diagnostics in the same book, it can serve as an ideal reference book as well, and it deserves to be welcomed wordwide by the addressed audience.” (Dr. Chung-en Zah - Semiconductor Technologies Research, 1 May 2013)
“In my opinion, this book was a pleasure to read and due to its quality and relevance deserves a large audience in the power diode laser community!.” (Prof. em. Dr. Heinz Jäckel - High Speed Electronics and Photonics, 16 June 2013)
Review
This book represents a well thought description of three fundamental aspects of laser technology: the functioning principles, the reliability and the diagnostics. From this point of view, and, as far as I know, this is a unique example of a book where all these aspects are merged together resulting in a well-balanced presentation. This helps the reader to move with ease between different concepts since they are presented in a coherent manner and with the same terminology, symbols and definitions.
The book reads well. It presents the necessary equations and derivations to understand both the physical mechanisms and the practicalities via a set of useful formulas. In addition, there is the more important aspect of many real-life examples of how a laser is actually manufactured and which the relevant parameters that determine its behaviour are. It impresses the amounts of information that are given in the book: this would be more typical of a thick handbook on semiconductor laser than of an agile book. Dr. Epperlein was able to identify the most important concepts and to present them in a clear though concise way.
I am teaching a course on Optoelectronics and I'm going to advise students to refer to this book, because it has all the necessary concepts and derivations for a systematic understanding of semiconductor lasers with many worked-out examples, which will help the student to grasp the actual problems of designing, manufacturing, testing and using semiconductor lasers. All the various concepts are joined to very useful figures, which, if provided to instructors as files, can be a useful add-on for the use of the book as text for teaching. Concepts are always detailed with numbers to give a feeling of their practical use.
In conclusion, I do find the book suitable for my teaching duties and will refer it to my students.
— Prof. Dr. Lorenzo Pavesi, Head of the Department of Physics, University of Trento, Italy, 31 May 2013
Dr. Epperlein has done the semiconductor laser community a great service, by releasing the most complete book on the market on the practical issues of how to make reliable semiconductor lasers. …
The results are at the cutting edge of our understanding of semiconductor laser reliability today, and go well beyond the empirical “black box” approach many use of “try everything, and see what works.” The author did a fine job of pulling together material from many disparate fields.
Dr. Epperlein has particular expertise in high power single mode semiconductor lasers, and those working on those type of lasers will be especially interested in this book, as there has never been a book published on the fabrication and qualification of such lasers before. However, those in almost any field of semiconductor lasers will learn items of interest about device design, fabrication, reliability, and characterization. …
This book is written more as a “how to” manual, which should make it more accessible and useful to development engineers and researchers in the field. As with many books of this type, it is not necessary to read it from cover-to-cover, it is best skimmed, with deep diving into any areas of special interest to the reader. The book is remarkable also, for how comprehensive it is – even experts will discover something new and useful.
Dr. Epperlein’s book is an essential read for anyone looking to develop semiconductor lasers for anything other than pure research use, and I give it my highest recommendation.
—Dr. Robert W. Herrick, Senior Component Reliability Engineer, Intel Corp., Santa Clara, CA, USA. July 6, 2013.
The book closes the gap in the current book literature and is thus a unique and excellent example of how to merge design, reliability and diagnostics aspects in a very professional, profound and complete manner. …
All physical and technological principles, concepts and practical aspects required for developing and fabricating highly-reliable high-power single-mode laser products are precisely specified and skilfully formulated along with all the necessary equations, figures, tables and worked-out examples making it easy to follow through the nine chapters.
Hence, this unique book is a milestone in the diode laser literature and is an excellent reference book for not only diode laser researchers and engineers, but also diode laser users. …
The book has an elaborate table of contents and index, which are very useful, over 200 illustrative figures and tables, and extensive lists of references to all technical topics at the end of each of the nine chapters, which make it easy to follow from cover to cover or by jumping in at random areas of special interest. Moreover, experimental and theoretical concepts are always illustrated by practical examples and data. ...
I can highly recommend this extremely relevant, well-structured and well-formulated book to all practising researchers in industrial and academic diode laser R&D environments and to post-graduate engineering students interested in the actual problems of designing, manufacturing, testing, characterising and qualifying diode lasers. ...
Due to its completeness and novel approach to combine design, reliability and diagnostics in the same book, it deserves to be welcomed wordwide by the addressed audience.
—Dr. Chung-en Zah, Research Director S&T Division, Corning Inc., Corning NY, USA. June 23, 2013
This book is a landmark in the recent literature on semiconductor lasers because it fills a longstanding gap between many excellent books on laser theory and the complex and challenging endeavour to fabricate these devices reproducibly and reliably in an industrial, real world environment. …
I appreciate the competent, complete and skilful presentation of the three highly interrelated critical topics of state-of-the-art power laser research - device and mode stability engineering, reliability mechanisms/reliability assessment strategies and material/device diagnostics all treated with a strong focus on the implementation. This emphasis on the complex practical aspects for a large-scale power laser fabrication is a true highlight of the book. …
The subtle interplay between laser design, reliability strategies, advanced failure analysis and characterization techniques is elaborated in a very rigorous and scientific way using a very clear and easy to read representation of the complex interrelation of the three major topics. I will concentrate on the numerous highlights. … The completeness of the presentation on power laser diode design based on basic physical and plausible arguments is mainly based on analytic mathematical relations as well as experiments providing a new and well-balanced addition for the power diode laser literature in particular. …
The novel and really original, “gap-filling” bulk of the book is elaborated in a very clear way in the four chapters in part 2 “Laser Reliability” on laser degradation physics and mirror design and passivation at high power, followed then by two very application oriented chapters on reliability design engineering and practical reliability strategies and implementation procedures. This original combination of integral design and reliability aspects, which are mostly neglected in standard literature, is certainly a major plus of this book. I liked part 2 as a whole, because it provides excellent insights in degradation physics on a high level and combines it in an interesting and skilful way with the highly relevant reliability science and testing strategies, which is particularly important for devices operating at extreme optical stresses with challenging lifetime requirements in a real word environment. …
Part 3 “Laser Diagnostics” … is devoted to advanced experimental diagnostics techniques for material integrity, mechanical stress, deep level defects, various dynamic laser degradation effects, surface- and interface quality, and most importantly heating and disordering of mirrors and mirror coatings. The topics of these techniques … have been pioneered by the author for the specific applications over many years guaranteeing many competent and well- represented insights. These techniques are brilliantly discussed and the information distributed in many articles by the author has been successfully unified in this book.
I consider the parts 2 and 3 on reliability and diagnostics as the most valuable and true novel contribution of the book, which in combination with the extremely well covered laser design of part 1 clearly fill the gap in the current diode laser literature, which in this detail has certainly been neglected in the past.
In summary, I can highly recommend this excellent, well-organized and clearly written book to readers who are already familiar with basic diode laser theory and who are active in the academic and industrial fabrication and characterization of semiconductor lasers. Due to its completeness, it also serves as an excellent reference of the current state-of-the-art in reliability engineering and device and material diagnostics.
Needless to mention that the quality of the book, its representations and methodical structure meet the highest expectation and are certainly a tribute from the long and broad experience of the author in academic laser science and the industrial commercialization of high power diode lasers.
This book was a pleasure to read and due to its quality and relevance deserves a large audience in the power diode laser community!
—Prof. em. Dr. Heinz Jäckel, Swiss Federal Institute of Technology ETH Zürich, Switzerland. June 16, 2013
From the Back Cover
This reference book provides a fully integrated novel approach to the development of high-power, single-transverse mode, edge-emitting diode lasers by addressing the complementary topics of device engineering, reliability engineering and device diagnostics in the same book, and thus closes the gap in the current book literature.
Diode laser fundamentals are discussed, followed by an elaborate discussion of problemoriented design guidelines and techniques, and by a systematic treatment of the origins of laser degradation and a thorough exploration of the engineering means to enhance the optical strength of the laser. Stability criteria of critical laser characteristics and key laser robustness factors are discussed along with clear design considerations in the context of reliability engineering approaches and models, and typical programs for reliability tests and laser product qualifications. Novel, advanced diagnostic methods are reviewed to discuss, for the first time in detail in book literature, performance- and reliability-impacting factors such as temperature, stress and material instabilities.
Further key features include:
- practical design guidelines that consider also reliability related effects, key laser robustness factors, basic laser fabrication and packaging issues;
- detailed discussion of diagnostic investigations of diode lasers, the fundamentals of the applied approaches and techniques, many of them pioneered by the author to be fit-for-purpose and novel in the application;
- systematic insight into laser degradation modes such as catastrophic optical damage, and a wide range of technologies to increase the optical strength of diode lasers;
- coverage of basic concepts and techniques of laser reliability engineering with details on a standard commercial high power laser reliability test program.
Semiconductor Laser Engineering, Reliability and Diagnostics reflects the extensive expertise of the author in the diode laser field both as a top scientific researcher as well as a key developer of high-power highly reliable devices. With invaluable practical advice, this new reference book is suited to practising researchers in diode laser technologies, and to postgraduate engineering students.
Most helpful customer reviews
1 of 1 people found the following review helpful.
An inexhaustible source of extremely valuable practical information
By Luigi Raffaele
Dr. Ing. Luigi Raffaele, M.Sc., Ph.D.
Former Scientist at Corning Research Centre
Optoelectronic Device Design and Fabrication Group
Science and Technology Division
Corning Ltd
United Kingdom.
The book “Semiconductor Laser Engineering, Reliability and Diagnostics. A Practical Approach to High Power and Single Mode Devices” is a milestone in the diode laser literature, reflecting the high-level of competence and experience of the author. It is the only textbook on the market that comprehensively furnishes a set of theory and practical problem-oriented guidelines on the design, fabrication and overall engineering of semiconductor lasers, with a unique in-depth and breadth treatise on the crucial topics of high-power, single spatial mode, ultimate reliability and sophisticated novel laser diagnostics not covered in any other textbooks on diode lasers. The book contains hundreds of useful figures and informative tables as well as an extensive list of references.
The author, Dr. Epperlein, is a world-renowned semiconductor laser industry veteran and consultant with an extensive experience spanning all the main topics and issues in diode laser research, development, engineering, reliability and diagnostics and with an excellent reputation as a top-level scientist and manager in cutting-edge optoelectronics industries, where for decades he developed state-of-the-art solutions. I especially know him as a pioneer in the field of 980nm pump laser technology where his work contributed to the successful commercialization of market-leading high-performance reliable devices for applications in optical communication networks.
All the topics addressed in the book are clearly and comprehensively described from the basis in a well-structured way. The book is therefore suitable for a broad audience within both academia and industry, including researchers, engineers, managers and professionals working in the field of optoelectronics. I also strongly suggest professors and post-graduate students to adopt this as a textbook, being an invaluable source of essential information that will allow students to gain a first insight into the main aspects of semiconductor laser engineering and to understand the practical real-life issues that a device designer need to know, approach and resolve.
As a former semiconductor laser designer, I can say that by writing this impressive publication, Dr. Epperlein has also made a greatly appreciated gift to the community of semiconductor laser designers that will surely find it an inexhaustible source of vital information and an excellent vade mecum. I hope, Dr. Epperlein will issue further editions of his remarkable book, which I can highly recommend.
0 of 0 people found the following review helpful.
Even experts will discover something new and useful
By Robert Herrick
Dr. Epperlein has done the semiconductor laser community a great service, by releasing the most complete book on the market on the practical issues of how to make reliable semiconductor lasers.
While dozens of books have been written over the past couple of decades on semiconductor laser design, only a handful have been written on semiconductor laser reliability. Prior to the release of this book, perhaps 40% of the material could be obtained elsewhere by combining five books: one on laser design, one on laser reliability, one on reliability calculations, and a couple of laser review books. Another 40% could be pieced together by collecting 50 -100 papers on the subjects of laser design, laser fabrication, characterization, and reliability. The remaining 20% have not previously been covered in any comprehensive way. Only the introductory material in the first half of the first chapter has good coverage elsewhere. The large majority of the knowledge in this book is generally held as "trade secret" by those with the expertise in the field, and most of those in the know are not free to discuss. The author was fortunate enough to work for the first half of his career in the IBM research labs, with access to unparalleled resources, and the ability to publish his work without trade secret restrictions. The results are still at the cutting edge of our understanding of semiconductor laser reliability today, and go well beyond the empirical "black box" approach many use of "try everything, and see what works." The author did a fine job of pulling together material from many disparate fields.
Dr. Epperlein has particular expertise in high power single mode semiconductor lasers, and those working on those type of lasers will be especially interested in this book, as there has never been a book published on the fabrication and qualification of such lasers before. But those in almost any field of semiconductor lasers will learn items of interest about device design, fabrication, reliability, and characterization. Unlike most other books, which intend to convey the scientific findings or past work of the author, this one is written more as a "how to" manual, which should make it more accessible and useful to development engineers and researchers in the field. It also has over 200 figures, which make it easier to follow. As with many books of this type, it is not necessary to read it from cover-to-cover; it is best skimmed, with deep diving into any areas of special interest to the reader. The book is remarkable also for how comprehensive it is - even experts will discover something new and useful.
Dr. Epperlein's book is an essential read for anyone looking to develop semiconductor lasers for anything other than pure research use, and I give it my highest recommendation.
0 of 0 people found the following review helpful.
Unique diode laser book deserves high demand
By Chung-en Zah
Dr. Chung-en Zah
Research Director
Semiconductor Technologies Research, S&T Division
Corning Incorporate
Corning NY, USA
Book Review of:
"Semiconductor Laser Engineering, Reliability and Diagnostics: A Practical Approach to High Power and Single Mode Devices". By Peter W. Epperlein
This book covers for the first time the three closely interrelated key laser areas of engineering (design), reliability and diagnostics in one book, written by the well-known practitioner in cutting-edge optoelectronics industries, Dr. Peter W. Epperlein. The book closes the gap in the current book literature and is thus a unique and excellent example of how to merge design, reliability and diagnostics aspects in a very professional, profound and complete manner. All physical and technological principles, concepts and practical aspects required for developing and fabricating highly-reliable high-power single-mode laser products are precisely specified and skilfully formulated along with all the necessary equations, figures, tables and worked-out examples making it easy to follow through the nine chapters. Hence, this unique book is a milestone in the diode laser literature and is an excellent reference book not only for diode laser researchers and engineers, but also diode laser users.
The engineering part starts with a very informative and clear, well-presented account of all necessary basic diode laser types, principles, parameters and characteristics for an easy and quick understanding of laser functionality within the context of the book. Along with an elaborate and broad discussion of relevant laser material systems, applications, typical output powers, power-limiting factors and reliability tradeoffs, basic fabrication and packaging technologies, this excellent introductory section is well suited to become quickly and easily familiar with practical aspects and issues of diode laser technologies. Of special importance and high usefulness is the first analytic and quantitative discussion in a book on issues of coupling laser power into optical single mode fibers. The second section discusses in a well-balanced, competent and skilful way waveguide topics such as basic high-power design approaches, transverse vertical and lateral waveguide concepts, stability of the fundamental transverse lateral mode and fundamental mode waveguide optimization techniques by considering detrimental effects such as heating, carrier injection, spatial hole burning, lateral current spreading and gain profile variations. Less well-known approaches to force large-area lasers into a single mode operation are well-identified and carefully discussed in depth and breadth. All these topics are elaborated in a very complete, rigorous and scientific way and are clearly articulated and easy to read. In particular, the book works out the complex interaction between the many different effects to optimize high-power single-mode performance at ultimate reliability and thus is of great benefit to every researcher and engineer engaged in this diode laser field.
Another novelty and highlight is, for the first time ever in book form, a comprehensive yet concise discussion of diode laser reliability related issues. These are elaborated in four distinct chapters comprising laser degradation physics and modes, optical strength enhancement approaches including mirror passivation/coating and non-absorbing mirror technologies, followed by two highly relevant product-oriented chapters on reliability design engineering concepts and techniques and an elaborate reliability test plan for laser chip and module product qualification. This original and novel approach to link laser design to reliability aspects and requirements provides both, most useful insight into degradation processes such as catastrophic optical mirror damage on a microscopic scale, and a wide selection of effective remedial actions. These accounts, which are of highest significance for lasers operating at the optical stress limit due to extremely high output power densities and most demanding lifetime requirements are very professionally prepared and discussed in an interesting, coherent and skilful manner.
The diagnostics part, consisting of three very elaborate chapters, is most unique and novel with respect to other diode laser books. It discusses for the first time ever on a very high level and in a competent way studies on material integrity, impurity trapping effects, mirror and cavity temperatures, surface- and interface quality, mirror facet disorder effects, mechanical stress and facet coating instability, and diverse laser temperature effects, dynamic laser degradation effects and mirror temperature maps. Of highest significance to design, performance and reliability are the various correlations established between laser device and material parameters. The most different and sophisticated experiments, carried out by the author at micrometer spatial resolutions and at temperatures as low as 2K, provide highly valuable insights into laser and material quality parameters, and reveal for the first time the origins of high power limitations on an atomic scale due to local heating effects and deep level defects. It is of great benefit, that the experimental techniques such as Raman spectroscopy, various luminescence techniques, thermoreflectance and deep-level transient spectroscopy, pioneered by the author for the specific experiments on lasers, are discussed with great expertise in depth and breadth, and the numerous paper articles published by the author are now represented in this book.
The book has an elaborate table of contents and index, which are very useful, over 200 illustrative figures and tables, and extensive lists of references to all technical topics at the end of each of the nine chapters, which make it easy to follow from cover to cover or by jumping in at random areas of special interest. Moreover, experimental and theoretical concepts are always illustrated by practical examples and data.
I can highly recommend this extremely relevant, well-structured and well-formulated book to all practising researchers in industrial and academic diode laser R&D environments and to post-graduate engineering students interested in the actual problems of designing, manufacturing, testing, characterising and qualifying diode lasers. Due to its completeness and novel approach to combine design, reliability and diagnostics in the same book, it can serve as an ideal reference book as well, and it deserves to be welcomed wordwide by the addressed audience.
Dr. Chung-en Zah
Research Director
Semiconductor Technologies Research, S&T Division
Corning Incorporate
Corning NY, USA
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