Science and Technology of Crystal Growth: Lectures given at the Ninth International Summer School on Crystal Growth, June 11-15, 1995 by J.P. van der EerdenScience and Technology of Crystal Growth: Lectures given at the Ninth International Summer School on Crystal Growth, June 11-15, 1995 by J.P. van der Eerden

Science and Technology of Crystal Growth: Lectures given at the Ninth International Summer School…

byJ.P. van der EerdenEditorO.S.L. Bruinsma

Paperback | October 9, 2012

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1. The ninth International Summer School on Crystal Growth. ISSCG IX A complete theory of crystal growth establishes the full dependence of crystal size, shape and structure on external parameters like temperature, pressure, composition, purity, growth rate and stirring of the mother phase, implicitly establishing how the corresponding fields vary in space and time. Such a theory does not exist, however. Therefore equipment to grow crystals is developed on the basis of partial knowledge. Skill, experience and creativity still are of central importance for the success o<_20_a20_crystal20_growth20_system.20_in20_this20_book20_we20_collected20_contributions20_from20_the20_teachers20_of20_the20_ninth20_international20_summer20_school20_on20_crystal20_growth20_isscg20_ix2c_20_held20_11-1620_june20_199520_at20_papendal2c_20_the20_national20_sports20_centre20_of20_the20_netherlands.20_these20_contributions20_were20_used20_during20_the20_lectures.20_the20_authors20_have20_tried20_to20_present20_their20_work20_in20_such20_a20_way20_that20_only20_basic20_physical20_knowledge20_is20_required20_to20_understand20_the20_papers.20_the20_book20_can20_be20_used20_as20_an20_introduction20_to20_various20_important20_sub20_disciplines20_of20_the20_science20_and20_technology20_of20_crystal20_growth.20_since2c_20_however20_the20_information20_content20_considerably20_exceeds20_a20_lecture20_note20_level20_and20_touches20_the20_present20_limits20_of20_understanding2c_20_it20_is20_an20_up20_to20_date20_handbook20_as20_well. a="" crystal="" growth="" system.="" in="" this="" book="" we="" collected="" contributions="" from="" the="" teachers="" of="" ninth="" international="" summer="" school="" on="" isscg="" _ix2c_="" held="" 11-16="" june="" 1995="" at="" _papendal2c_="" national="" sports="" centre="" netherlands.="" these="" were="" used="" during="" lectures.="" authors="" have="" tried="" to="" present="" their="" work="" such="" way="" that="" only="" basic="" physical="" knowledge="" is="" required="" understand="" papers.="" can="" be="" as="" an="" introduction="" various="" important="" sub="" disciplines="" science="" and="" technology="" growth.="" _since2c_="" however="" information="" content="" considerably="" exceeds="" lecture="" note="" level="" touches="" limits="" _understanding2c_="" it="" up="" date="" handbook="">
Title:Science and Technology of Crystal Growth: Lectures given at the Ninth International Summer School…Format:PaperbackDimensions:391 pagesPublished:October 9, 2012Publisher:Springer-Verlag/Sci-Tech/TradeLanguage:English

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ISBN - 10:9401040621

ISBN - 13:9789401040624

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Table of Contents

Science and Technology of Crystal Growth: An Introduction; J. P. van der Eerden, O. S. L. Bruinsma. 1: Classical and Statistical Thermodynamics. 1.1. Thermodynamics and Phase Diagrams - Fundamentals and Tools for Crystal Growth; G. Krabbes. 1.2. Atomic Models for Crystal Growth; J. P. van der Eerden. 1.3. The Syncrystallization of Thianaphthene and Naphthalene, an Exercise in Thermodynamic Phase Diagram Analysis; H. A. J. Oonk. 1.4. From Thermoelasticity to Surface Melting; T. H. M. van den Berg, J. P. van der Eerden. 2: Crystallization Concepts. 2.1. Nucleation; D. Kashchiev. 2.2. Topics in Crystal Growth Kinetics; A. A. Chernov, H. Komatsu. 2.3. Lattice Growth Models; J. I. D. Alexander. 2.4. Macroscopic Transport Processes during the Growth of Single Crystals from the Melt; J. J. Derby. 3: Single Crystals and Epitaxy. 3.1. Large-Scale Numerical Modeling of the Bulk Crystal Growth from the Melt and Solution; J. J. Derby, S. Kuppurao, Q. Xiao, A. Yeckel, Y. Zhou. 3.2. Vapour Growth; G. Krabbes. 3.3. Advanced Epitaxial Growth Techniques for III-V Materials; I. Moerman, P. Demeester. 4: Crystal Shape. 4.1. Morphology of Crystals: Past and Future; P. Bennema. 4.2. Modulated and Quasicrystals; H. Meekes. 4.3. Modelling the Habit Modification of Molecular Crystals by the Action of `Tailor-Made' Additives; G. Clydesdale, K. J. Roberts. 4.4. Morphological Instability: Dendrites, Seaweed and Fractals; K. Kassner. 5: Mass Crystallization. 5.1. Mass Crystallization, Number Balances and Size Distributions; J. Garside. 5.2. Crystallizers; G. Hofmann. 5.3. Melt Suspension Crystallization; M. Matsuoka. 5.4. Melt Layer Crystallization; J. Ulrich, J. Bierwirth. 5.5. Secondary Nucleation; G. M. van Rosmalen, A. E. van der Heyden. 6: Crystals Grown from Large Growth Units. 6.1. Crystallization in Colloidal Suspensions; J. S. van Duijneveldt, H. N. W. Lekkerkerker. 6.2. Polytopism and Inorganic Crystal Growth and Reactivity; A. Baronnet. 6.3. Polymer Crystallization; G. Goldbeck-Wood. 6.4. Principles of Crystal Growth in Protein Crystallization; A. A. Chernov, H. Komatsu. 7: Surface Structure. 7.1. Some Common Pathologies in Step Growth: Impurities and Surface Reconstruction; W. J. P. van Enckevort. 7.2. Characterization of Crystal Growth Processes Using Synchrotron X-Ray Techniques; K. J. Roberts. 7.3. Optical and Scanning Probe Microscopy; K. Tsukamoto. Subject Index.