Springer Handbook of Crystal Growth
Herausgegeben:Dhanaraj, Govindhan; Byrappa, Kullaiah; Prasad, Vishwanath
Versandkostenfrei*
Versandfertig in über 4 Wochen
Springer Handbook of Crystal Growth
Herausgegeben:Dhanaraj, Govindhan; Byrappa, Kullaiah; Prasad, Vishwanath
- Audio CD mit DVD
Over the years, many successful attempts have been chapters in this part describe the well-known processes made to describe the art and science of crystal growth, such as Czochralski, Kyropoulos, Bridgman, and o- and many review articles, monographs, symposium v- ing zone, and focus speci cally on recent advances in umes, and handbooks have been published to present improving these methodologies such as application of comprehensive reviews of the advances made in this magnetic elds, orientation of the growth axis, intro- eld. These publications are testament to the grow- duction of a pedestal,…mehr
- Tunneling Spectroscopy39,99 €
- Organic Crystals I: Characterization77,99 €
- Norman H. MarchChemical Bonds Outside Metal Surfaces152,99 €
- Advances in X-Ray Analysis39,99 €
- Advances in X-ray Analysis40,99 €
- John B. NewkirkAdvances in X-Ray Analysis38,99 €
- BenoitMicrobeam and Nanobeam Analysis79,99 €
-
-
-
Bei diesem Produkt handelt es sich um ein Bundle, bestehend aus einem Buch und einem digitalen Mehrwert.
Deshalb wird dieses Produkt auf der Rechnung mit 19% MwSt ausgewiesen.
- Produktdetails
- Springer Handbooks
- Verlag: Springer, Berlin
- 1st ed. 2010
- Seitenzahl: 1818
- Englisch
- Abmessung: 242mm x 193mm
- ISBN-13: 9783540747628
- ISBN-10: 3540747621
- Artikelnr.: 43445975
- Springer Handbooks
- Verlag: Springer, Berlin
- 1st ed. 2010
- Seitenzahl: 1818
- Englisch
- Abmessung: 242mm x 193mm
- ISBN-13: 9783540747628
- ISBN-10: 3540747621
- Artikelnr.: 43445975
Kullaiah Byrappa received his Doctorâs degree in Crystal Growth from the Moscow State University, Moscow in 1981. He is Professor of Materials Science, Head of the Crystal Growth Laboratory, and Director of the Internal Quality Assurance Cell of the University of Mysore, India. His current research is in crystal engineering of polyscale materials through novel solution processing routes, particularly covering hydrothermal, solvothermal and supercritical methods. Professor Byrappa has co-authored the Handbook of Hydrothermal Technology, and edited 4 books as well as two special editions of Journal of Materials Science, and published 180 research papers including 26 invited reviews and book chapters on various aspects of novel routes of solution processing. Professor Byrappa has delivered over 60 keynote and invited lectures at International Conferences, and several hundreds of colloquia and seminars at various institutions around the world. He has also served as chair and co-chair for numerous international conferences. He is a Fellow of the World Academy of Ceramics. Professor Byrappa is serving in several international committees and commissions related to crystallography, crystal growth, and materials science. He is the Founder Secretary of the International Solvothermal and Hydrothermal Association. Professor Byrappa is a recipient of several awards such as the Sir C.V. Raman Award, Materials Research Society of India Medal, and the Golden Jubilee Award of the University of Mysore.
Vishwanath "Vish†Prasad is the Vice President for Research and Economic Development and Professor of Mechanical and Energy Engineering at the University of North Texas (UNT), one of the largest university in the state of Texas. He received his PhD from the University of Delaware (USA), his Masters of Technology from the Indian Institute of Technology, Kanpur, and his bachelorâs from Patna University in India all in Mechanical Engineering. Prior to joining UNT in 2007, Dr. Prasad served as the Dean at Florida International University (FIU) in Miami, where he also held the position of Distinguished Professor of Engineering. Previously, he has served as a Leading Professor of Mechanical Engineering at Stony Brook University of New York, as an Associate Professor and Assistant Professor at Columbia University. He has received many special recognitions for his contributions to engineering education. Dr. Prasadâs research interests include thermo-fluid sciences, energy systems, electronic materials, and computational materials processing. He has published over 200 articles, edited/coedited several books and organized numerous conferences, symposia, and workshops. He serves as the lead editor of the Annual Review of Heat Transfer. In the past, he has served as an Associate Editor of the ASME Journal of Heat. Dr. Prasad is an elected Fellow of the American Society of Mechanical Engineers (ASME), and has served as a member of the USRA Microgravity Research Council. Dr. Prasadâs research has focused on bulk growth of silicon, III-V compounds, and silicon carbide; growth of large diameter Si tube; design of crystal growth systems; and sputtering and chemical vapor deposition of thin films. He is also credited to initiate research on wire saw cutting of large crystals to produce wafers with much reduced material loss. Dr. Prasadâs research has been well funded by US National Science Foundation (NSF), US Department of Defense, US Department of Energy, and industry.
Michael Dudley received his Doctorâs Degree in Engineering from Warwick University, UK, in 1982. He is Professor and Chair of the Materials Science and Engineering Department at Stony Brook University, New York, USA. He is director of the Stony Brook Synchrotron Topography Facility at the National Synchrotron Light Source at Brookhaven National Laboratory, Upton New York. His current research focuses on crystal growth and characterization of defect structures in single crystals with a view to determining their origins. The primary technique used is synchrotron topography which enables analysis of defects and generalized strain fields in single crystals in general, with particular emphasis on semiconductor, optoelectronic, and optical crystals. Establishing the relationship between crystal growth conditions and resulting defect distributions is a particular thrust area of interest to Dudley, as is the correlation between electronic/optoelectronic device performance and defect distribution. Other techniques routinely used in such analysis include transmission electron microscopy, high resolution triple-axis x-ray diffraction, atomic force microscopy, scanning electron microscopy, Nomarski optical microscopy, conventional optical microscopy, IR microscopy and fluorescent laser scanning confocal microscopy. Dudleyâs group has played a prominent role in the development of SiC and AlN growth, characterizing crystals grown by many of the academic and commercial entities involved enabling optimization of crystal quality. He has co-authored some 315 refereed articles and 12 book chapters and edited 5 books. He is currently a member of the Editorial Board of Journal of Applied Physics and Applied Physics Letters and has served as Chair or Co-Chair for numerous international conferences.
Part A: Fundamentals of Crystal Growth and Defect Formation
Chap. 1. Crystal Growth Techniques and Characterization (G. Dhanaraj, K. Byrappa, V. Prasad, M. Dudley)
Chap. 2. Nucleation at Surfaces, (I. Markov)
Chap. 3. Morphology of Crystals Grown from Solution (F. Abbona, D. Aquilano)
Chap. 4. Generation and Propagation of Defects During Crystal Growth (H. Klapper)
Chap. 5. Single Crystals Grown Under Unconstrained Conditions (I. Sunagawa)
Part B: Crystal Growth from Melt Techniques
Chap. 6. Defect Formation During Crystal Growth from the Melt (P. Rudolph)
Chap. 7. Indium Phosphide: Crystal Growth and Defect Control by Applying Steady Magnetic Fields (D. Bliss)
Chap. 8.Czochralski Silicon Single Crystals for Semiconductor and Solar Cell Applications (K. Kakimoto)
Chap. 9.Czochralski Growth of Oxide Photorefractive Crystals (E. Dieguez, J.L.Plaza, M. D. Aggarwal, A. K. Batra)
Chap. 10. Bulk Crystal Growth of Ternary III-V Semiconductors (P.S. Dutta)
Chap. 11. Growth/Characterization of Antimony-Based Narrow-Bandgap III-V Semiconductor Crystals (V.K. Dixit, H. L. Bhat)
Chap. 12. Crystal Growth of Oxides by Optical Floating Zone Technique (H. Dabkowska, A. Dabkowski)
Chap. 13. Laser-Heated Pedestal Growth of Oxide Fibers (M.R.B. Andreeta, C. Hernandes)
Chap. 14. Synthesis of Refractory Materials by Skull Melting Technique (V.V. Osiko, M.A. Borik, E.E. Lomonova)
Chap. 15. Crystal Growth of Laser Host Fluorides and Oxides (J. Xu, H. Li)
Chap. 16. Shaped Crystal Growth (V. Tatartchenko)
Part C: Solution Growth of Crystals
Chap. 17. Bulk Single Crystals Grown from Solution on Earth and in Microgravity (M. Aggarwal, A. Batra, R. Lal, B. Penn, D. Frazier)
Chap. 18. Hydrothermal Growth of Polyscale Crystals (K. Byrappa)Chap. 19. Hydrothermal and Ammonothermal Growth of ZnO and GaN (M.Callahan, Q.S. Chen)
Chap. 20. Stoichiometry and Domain Structure of KTP-Type Nonlinear Optical Crystals (M. Roth)
Chap. 21. High-Temperature Solution Growth: Application to Laser and NL Optical Crystals (J.J. Carvajal, M.C. Pujol, F. Díaz)
Chap. 22. Growth and Characterization of KDP and its Analogs (S.-L. Wang, X. Sun, X.-T. Tao)
Part D: Crystal Growth from Vapor
Chap. 23. Growth and Characterization of Silicon Carbide Crystals (G. Dhanaraj, B. Raghothamachar, M. Dudley)
Chap. 24. AlN Bulk Crystal Growth by Physical Vapor Transport (R. Dalmau, Z. Sitar)
Chap. 25. Growth of Single-Crystal Organic Semiconductors (C. Kloc, T. Siegrist, J. Pflaum)
Chap. 26. Growth of III-Nitrides with HVPE (C. Hemmingsson, B. Monemar, Y. Kumagai, A. Koukitu)
Chap. 27. Growth of Semiconductor Single Crystals from Vapor Phase (R. Dhanasekaran)
Part E: Epitaxial Growth and Thin Films
Chap. 28. Epitaxial Growth of Silicon Carbide by Chemical Vapor Deposition (I.B. Bhat)
Chap. 29. Liquid-Phase Electroepitaxy of Semiconductors (S. Dost)
Chap. 30. Epitaxial Lateral Overgrowth of Semiconductors (Z. R. Zytkiewicz)
Chap. 31. Liquid-Phase Epitaxy of Advanced Materials (C.F. Klemenz Rivenbark)
Chap. 32. Molecular-Beam Epitaxial Growth of HgCdTe (J.W. Garland, S. Sivananthan)
Chap. 33. Metalorganic Vapor-Phase Epitaxy of Diluted Nitrides and Arsenide Quantum Dots (U. Pohl)
Chap. 34. Formation of SiGe Heterostructures and Their Properties (Y. Shiraki, A. Sakai)
Chap. 35. Plasma Energetics in Pulsed Laser and Pulsed Electron Deposition (M. Strikovski, J. Kim, S. Kolagani)
Part F: Modeling of Crystal Growth and Defects
Chap. 36. Convection and Control in Melt Growth of Bulk Crystals (C.-W. Lan)
Chap. 37. Vapor Growth of III Nitrides (D. Cai, L. Zheng, H. Zhang)Chap. 38. Continuum-Scale Quantitative Defect Dynamics in Growing Czochralski Silicon
Part A: Fundamentals of Crystal Growth and Defect Formation
Chap. 1. Crystal Growth Techniques and Characterization (G. Dhanaraj, K. Byrappa, V. Prasad, M. Dudley)
Chap. 2. Nucleation at Surfaces, (I. Markov)
Chap. 3. Morphology of Crystals Grown from Solution (F. Abbona, D. Aquilano)
Chap. 4. Generation and Propagation of Defects During Crystal Growth (H. Klapper)
Chap. 5. Single Crystals Grown Under Unconstrained Conditions (I. Sunagawa)
Part B: Crystal Growth from Melt Techniques
Chap. 6. Defect Formation During Crystal Growth from the Melt (P. Rudolph)
Chap. 7. Indium Phosphide: Crystal Growth and Defect Control by Applying Steady Magnetic Fields (D. Bliss)
Chap. 8.Czochralski Silicon Single Crystals for Semiconductor and Solar Cell Applications (K. Kakimoto)
Chap. 9.Czochralski Growth of Oxide Photorefractive Crystals (E. Dieguez, J.L.Plaza, M. D. Aggarwal, A. K. Batra)
Chap. 10. Bulk Crystal Growth of Ternary III-V Semiconductors (P.S. Dutta)
Chap. 11. Growth/Characterization of Antimony-Based Narrow-Bandgap III-V Semiconductor Crystals (V.K. Dixit, H. L. Bhat)
Chap. 12. Crystal Growth of Oxides by Optical Floating Zone Technique (H. Dabkowska, A. Dabkowski)
Chap. 13. Laser-Heated Pedestal Growth of Oxide Fibers (M.R.B. Andreeta, C. Hernandes)
Chap. 14. Synthesis of Refractory Materials by Skull Melting Technique (V.V. Osiko, M.A. Borik, E.E. Lomonova)
Chap. 15. Crystal Growth of Laser Host Fluorides and Oxides (J. Xu, H. Li)
Chap. 16. Shaped Crystal Growth (V. Tatartchenko)
Part C: Solution Growth of Crystals
Chap. 17. Bulk Single Crystals Grown from Solution on Earth and in Microgravity (M. Aggarwal, A. Batra, R. Lal, B. Penn, D. Frazier)
Chap. 18. Hydrothermal Growth of Polyscale Crystals (K. Byrappa)Chap. 19. Hydrothermal and Ammonothermal Growth of ZnO and GaN (M.Callahan, Q.S. Chen)
Chap. 20. Stoichiometry and Domain Structure of KTP-Type Nonlinear Optical Crystals (M. Roth)
Chap. 21. High-Temperature Solution Growth: Application to Laser and NL Optical Crystals (J.J. Carvajal, M.C. Pujol, F. Díaz)
Chap. 22. Growth and Characterization of KDP and its Analogs (S.-L. Wang, X. Sun, X.-T. Tao)
Part D: Crystal Growth from Vapor
Chap. 23. Growth and Characterization of Silicon Carbide Crystals (G. Dhanaraj, B. Raghothamachar, M. Dudley)
Chap. 24. AlN Bulk Crystal Growth by Physical Vapor Transport (R. Dalmau, Z. Sitar)
Chap. 25. Growth of Single-Crystal Organic Semiconductors (C. Kloc, T. Siegrist, J. Pflaum)
Chap. 26. Growth of III-Nitrides with HVPE (C. Hemmingsson, B. Monemar, Y. Kumagai, A. Koukitu)
Chap. 27. Growth of Semiconductor Single Crystals from Vapor Phase (R. Dhanasekaran)
Part E: Epitaxial Growth and Thin Films
Chap. 28. Epitaxial Growth of Silicon Carbide by Chemical Vapor Deposition (I.B. Bhat)
Chap. 29. Liquid-Phase Electroepitaxy of Semiconductors (S. Dost)
Chap. 30. Epitaxial Lateral Overgrowth of Semiconductors (Z. R. Zytkiewicz)
Chap. 31. Liquid-Phase Epitaxy of Advanced Materials (C.F. Klemenz Rivenbark)
Chap. 32. Molecular-Beam Epitaxial Growth of HgCdTe (J.W. Garland, S. Sivananthan)
Chap. 33. Metalorganic Vapor-Phase Epitaxy of Diluted Nitrides and Arsenide Quantum Dots (U. Pohl)
Chap. 34. Formation of SiGe Heterostructures and Their Properties (Y. Shiraki, A. Sakai)
Chap. 35. Plasma Energetics in Pulsed Laser and Pulsed Electron Deposition (M. Strikovski, J. Kim, S. Kolagani)
Part F: Modeling of Crystal Growth and Defects
Chap. 36. Convection and Control in Melt Growth of Bulk Crystals (C.-W. Lan)
Chap. 37. Vapor Growth of III Nitrides (D. Cai, L. Zheng, H. Zhang)Chap. 38. Continuum-Scale Quantitative Defect Dynamics in Growing Czochralski Silicon