000 07663cam a2200553Ii 4500
001 on1046990439
003 OCoLC
005 20220711203437.0
006 m o d
007 cr cnu|||unuuu
008 180802s2018 njua ob 001 0 eng d
040 _aN$T
_beng
_erda
_epn
_cN$T
_dN$T
_dEBLCP
_dOCLCF
_dDG1
_dYDX
_dDG1
_dRECBK
020 _a9781119423744
_q(electronic bk.)
020 _a1119423740
_q(electronic bk.)
020 _a9781119423775
_q(electronic bk.)
020 _a1119423775
_q(electronic bk.)
020 _z9781119423683
035 _a(OCoLC)1046990439
050 4 _aTS513
072 7 _aTEC
_x040000
_2bisacsh
082 0 4 _a681.4
_223
049 _aMAIN
100 1 _aSuratwala, Tayyab,
_d1970-
_eauthor.
_97727
245 1 0 _aMaterials science and technology of optical fabrication /
_cTayyab I. Suratwala.
264 1 _aHoboken, NJ, USA :
_bJohn Wiley and Sons, Inc.,
_c2018.
300 _a1 online resource :
_billustrations (some color).
336 _atext
_btxt
_2rdacontent
337 _acomputer
_bc
_2rdamedia
338 _aonline resource
_bcr
_2rdacarrier
504 _aIncludes bibliographical references and index.
588 _aOnline resource; title from PDF title page (EBSCO, viewed August 6, 2018).
505 0 _aCover; Title Page; Copyright; Contents; Preface; Acknowledgments; Glossary of Symbols and Abbreviations; Part I Fundamental Interactions - Materials Science; Chapter 1 Introduction; 1.1 Optical-Fabrication Processes; 1.2 Major Characteristics of the Optical-Fabrication Process; 1.3 Material Removal Mechanisms; References; Chapter 2 Surface Figure; 2.1 The Preston Equation; 2.2 The Preston Coefficient; 2.3 Friction at Interface; 2.4 Kinematics and Relative Velocity; 2.5 Pressure Distribution; 2.5.1 Applied Pressure Distribution; 2.5.2 Elastic Lap Response; 2.5.3 Hydrodynamic Forces
505 8 _a2.5.4 Moment Forces2.5.5 Viscoelastic and Viscoplastic Lap Properties; 2.5.5.1 Viscoelastic Lap; 2.5.5.2 Viscoplastic Lap; 2.5.6 Workpiece-Lap Mismatch; 2.5.6.1 Workpiece Shape; 2.5.6.2 Pad Wear/Deformation; 2.5.6.3 Workpiece Bending; 2.5.6.4 Residual Grinding Stress; 2.5.6.5 Temperature; 2.5.6.6 Global Pad Properties; 2.5.6.7 Slurry Spatial Distribution; 2.5.6.8 Local Nonlinear Material Deposits; 2.6 Deterministic Surface Figure; References; Chapter 3 Surface Quality; 3.1 Subsurface Mechanical Damage; 3.1.1 Indentation Fracture Mechanics; 3.1.1.1 Static Indentation
505 8 _a3.1.1.2 Edge Chipping and Bevels3.1.1.3 Sliding Indentation; 3.1.1.4 Impact Indentation Fracture; 3.1.2 SSD During Grinding; 3.1.2.1 Subsurface Mechanical Depth Distributions; 3.1.2.2 Relationship of Roughness and Average Crack Length to the Maximum SSD Depth; 3.1.2.3 Fraction of Abrasive Particles Mechanically Loaded; 3.1.2.4 Relationship Between the Crack Length and Depth; 3.1.2.5 SSD Depth-distribution Shape; 3.1.2.6 Effect of Various Grinding Parameters on SSD Depth Distributions; 3.1.2.7 Rogue Particles During Grinding; 3.1.2.8 Conclusions on Grinding SSD; 3.1.3 SSD During Polishing
505 8 _a3.1.4 Effect of Etching on SSD3.1.4.1 Topographical Changes of SSD During Etching; 3.1.4.2 Influence of SDD Distribution on Etch Rate and Roughness; 3.1.5 Strategies to Minimize SSD; 3.2 Debris Particles and Residue; 3.2.1 Particles; 3.2.2 Residue; 3.2.3 Cleaning Strategies and Methods; 3.3 The Beilby Layer; 3.3.1 K Penetration by Two-step Diffusion; 3.3.2 Ce Penetration by Chemical Reactivity; 3.3.3 Chemical-Structural-Mechanical Model of the Beilby Layer and Polishing Process; References; Chapter 4 Surface Roughness; 4.1 Single-Particle Removal Function; 4.2 Beilby Layer Properties
505 8 _a4.3 Slurry PSD4.4 Pad Mechanical Properties and Topography; 4.5 Slurry Interface Interactions; 4.5.1 Slurry Islands and -roughness; 4.5.2 Colloidal Stability of Particles in Slurry; 4.5.3 Glass Reaction Product Buildup at Polishing Interface; 4.5.4 Three-Body Forces at Polishing Interface; 4.6 Slurry Redeposition; 4.7 Predicting Roughness; 4.7.1 EHMG - The Ensemble Hertzian Multi-gap Model; 4.7.1.1 Pad Deflection and Fraction of Pad Area Making Contact; 4.7.1.2 Asperity Stress, Interface Gap, Load/Particle Distribution, and Fraction of Active Particles
520 _aCovers the fundamental science of grinding and polishing by examining the chemical and mechanical interactions over many scale lengths Manufacturing next generation optics has been, and will continue to be, enablers for enhancing the performance of advanced laser, imaging, and spectroscopy systems. This book reexamines the age-old field of optical fabrication from a materials-science perspective, specifically the multiple, complex interactions between the workpiece (optic), slurry, and lap. It also describes novel characterization and fabrication techniques to improve and better understand the optical fabrication process, ultimately leading to higher quality optics with higher yield. Materials Science and Technology of Optical Fabrication is divided into two major parts. The first part describes the phenomena and corresponding process parameters affecting both the grinding and polishing processes during optical fabrication. It then relates them to the critical resulting properties of the optic (surface quality, surface figure, surface roughness, and material removal rate). The second part of the book covers a number of related topics including: developed forensic tools used to increase yield of optics with respect to surface quality (scratch/dig) and fracture loss; novel characterization and fabrication techniques used to understand/quantify the fundamental phenomena described in the first part of the book; novel and recent optical fabrication processes and their connection with the fundamental interactions; and finally, special techniques utilized to fabricate optics with high damage resistance. -Focuses on the fundamentals of grinding and polishing, from a materials science viewpoint, by studying the chemical and mechanical interactions/phenomena over many scale lengths between the workpiece, slurry, and lap -Explains how these phenomena affect the major characteristics of the optic workpiece-namely surface figure, surface quality, surface roughness, and material removal rate -Describes methods to improve the major characteristics of the workpiece as well as improve process yield, such as through fractography and scratch forensics -Covers novel characterization and fabrication techniques used to understand and quantify the fundamental phenomena of various aspects of the workpiece or fabrication process -Details novel and recent optical fabrication processes and their connection with the fundamental interactions Materials Science and Technology of Optical Fabrication is an excellent guidebook for process engineers, fabrication engineers, manufacturing engineers, optical scientists, and opticians in the optical fabrication industry. It will also be helpful for students studying material science and applied optics/photonics.
650 0 _aOptical instruments
_xDesign and construction.
_97728
650 0 _aOptical materials.
_97729
650 0 _aOptical engineering.
_93620
650 7 _aTECHNOLOGY & ENGINEERING / Technical & Manufacturing Industries & Trades.
_2bisacsh
_95059
650 7 _aOptical engineering.
_2fast
_0(OCoLC)fst01740023
_93620
650 7 _aOptical instruments
_xDesign and construction.
_2fast
_0(OCoLC)fst01046741
_97728
650 7 _aOptical materials.
_2fast
_0(OCoLC)fst01046768
_97729
655 4 _aElectronic books.
_93294
856 4 0 _uhttps://doi.org/10.1002/9781119423775
_zWiley Online Library
942 _cEBK
994 _a92
_bDG1
999 _c68938
_d68938