product iamge

Handbook of Industrial Diamonds: Volume 1, Superabrasives and Diamond Syntheses

This document was uploaded by one of our users. The uploader already confirmed that they had the permission to publish it. If you are author/publisher or own the copyright of this documents, please report to us by using this DMCA report form.

Download
Search on Amazon

Simply click on the Download Book button.

Yes, Book downloads on Ebookily are 100% Free.

Sometimes the book is free on Amazon As well, so go ahead and hit "Search on Amazon"

Every year, the world consumes more than 10,000 tons of diamond superabrasives, which are indispensable for fields such as construction, metals, ceramics, automobiles, semiconductors, computers, and cellular phones. In fact, the per capita consumption of superabrasives may be used as an indicator of a country's industrial activities.

This volume presents several aspects of superhard materials, especially diamond superabrasives and their manufacture, properties, and applications, and introduces several new designs of ultrahard materials that may be harder than diamond. It discusses diamond’s connection with the origin of life, in particular, the origin of the first RNA. In addition, it throws light on the concept of diamond quantum computers with neutrons of the carbon-13 isotope as quantum bits. This innovation may maintain quantum coherence with minimal interference without using complicated cryogenic cooling. Hence, it can be a robust design for future quantum computers. For those interested in the depth of the quantum mechanical world, a chapter elaborates the history of life and humanity in light of the evolution of quantum universes.

Author(s): James Sung
Publisher: Jenny Stanford Publishing
Year: 2021

Language: English
Pages: 438
City: Burlington

Cover
Half Title
Title Page
Copyright Page
Table of Contents
Preface
Chapter 1: High-Pressure Synthesis of Saw Diamond
1.1: The Technology Barrier for Growing Saw Diamond
1.2: The Belt Apparatus
1.3: The Production Scale
1.4: The Construction of Belt Apparatus
1.5: Stress in a Die
1.6: Gasket Material
1.7: The Design of Reaction Cell
1.8: The Russian Toroidal Apparatus
1.9: The Chinese Cubic Presses
1.10: China as the Volume Leader
1.11: Layered Cell versus Powdered Cell
1.12: Positive Nucleation Control by Seeding
1.13: The Optimization of Graphite
1.14: The Selection of Catalyst
Chapter 2: Diamond Grit
2.1: Diamond Attributes
2.2: Diamond’s Facets
2.3: Diamond’s Hardness
2.4: Grit Size
2.5: Diamond Shape
2.6: Impact Strength
2.7: Compression Strength
2.8: Thermal Softening of Diamond
2.9: Graphitization of Diamond
2.10: Oxidation of Diamond
2.11: Catalytic Etching
2.12: Diamond Grades
2.13: Diamond Separation
2.14: Magnetic Susceptibility
2.15: Matrix Metal
Chapter 3: Diamond Saws
3.1: Revived Stone Age
3.2: Circular Diamond Saws
3.3: Straight Frame Saws
3.4: Metal Coating of Diamond
3.5: Diamond Granulation
3.6: Wire Saws
3.7: Brazed Wire Saw Beads
3.8: Diamond Cuting Optimization
3.9: Cuting Performance of Circular Saws
3.10: Diamond Saw Performance
3.11: Diamond Saw Segments
3.12:
Sintering Processes
3.13: Diamond Array in 3D
Chapter 4: Micron and Nanom Diamond
4.1: Explosive Diamond
4.2: High Surface Areas
4.3: Dynamite Diamond
4.4: Nanom Diamond Applications
4.5: Shock Wave Diamond
4.6: Micron Diamond Applications
4.7: Conventional Micron Diamonds
4.8: Diamond Pulverization
4.9:
The Classification of Micron Diamond
4.10: The Polishing by Micron Diamond
4.11: Sintering of Micron and Nanom Diamonds
Chapter 5: Active Braze-Coated Diamond
5.1: Diamond Brazes
5.2: Diamond Bonding Strength
5.3: Diamond Coating
5.4: Molten Braze Coating
5.5: Diamond Needles and Plates
5.6: Trans-Granular Fracture of ABCD
5.7: ABCD Saw Segments
5.8: Porous Metal Matrix
5.9: Frame Saw for Cutting Granite
5.10: Porous ABCD Frame Saw Segment
5.11: Frame Saw with Elastic Blades
5.12: Mini-Wire Saws
5.13: ABCD Wire Saw to Slice Silicon Ingot
Chapter 6: Diamond Grinders
6.1: The Applications of Diamond Grinders
6.2: The Performance of Diamond Grinders
6.3: The Design of Diamond Grinders
6.4: Diamond Selection
6.5: Diamond Wear Mechanism
6.6: Diamond and Matrix Material
6.7: Diamond Coatings
6.8: Novel Concept Friable Diamond
Chapter 7: Cubic Boron Nitride
7.1: ABCD of Abrasives
7.2: Cubic Boron Nitride
7.3: Synthesis of cBN
7.4: Crystal Morphology
7.5: Matrix of cBN Grinder
7.6: Applications of cBN Grinders
7.7: Polycrystalline cBN Grits
7.8: Polycrystalline cBN Blanks
Chapter 8: Diamond Pad Dresser
8.1: Diamond Distribution and Diamond Adherence
8.2: Chemical Mechanical Planarization
8.3: Diamond Pad Dresser
8.4: The Dressing of Polishing Pad
8.5: The Dressing Rate of a Pad
8.6: The Texture of the Pad Surface
8.7: Harmonic Dressing versus Noisy Dressing
8.8: Mathematical Models for Dressing
8.9: Diamond Dresser Life
8.10: Diamond Selection
8.11: Diamond Dresser Design
8.12: Conventional Diamond Dressers
8.13: Diamond Separation
8.14: Diamond Leveling
8.15: Diamond Shield Protection
8.16: Diamond Grid Performance
Chapter 9: Polycrystalline Diamond
9.1: Sintering of Polycrystalline Diamond
9.2: The Infiltration of Cobalt
9.3: PCD Interface
9.4: PCD Structures
9.5: PCD Properties
9.6: Thermal Stability of PCD
9.7: PCD Brazing
9.8: Thermally Stable PCD
9.9: DiaPore PCD’s Manufacture
9.10: High-Pressure DiaMet
9.11: DiaSiC PCD
9.12: DiaSil PCD
9.13: Utility-Grade PCD
9.14: PCD Cuting Tools
9.15: PCD Drill Bits
9.16: PCD Wire-Drawing Die
9.17: PCD Dressers
9.18: PCD Wear Resistant Parts
Appendix
Index