Principles of Chemical Vapor Deposition

Acknowledgements. Preface.1: Introduction.1. What's behind the facade? 2. Generic reactors and process considerations. 3. Tube and showerhead reactor examples.2: Reactors without transport.1. What goes in must go somewhere: Measuring gases. 2. Review: Kinetic theory. 3. The zero-dimensional reactor. 4. Zero-dimensional tube and showerhead examples.3: Mass transport.1. Introduction to transport. 2. Convection and diffusion. 3. Diffusion: Physics and math. 4. Fluid flow and convective transport. 5. When flows matter: The Knudsen number. 6. Tube and showerhead examples. 7. On to photons.4: Heat transport.1. What is heat (energy) transport? 2. Heat conduction and diffusion. 3. Convective heat transfer made (very) simple. 4. Natural convection. 5. Radiative heat transfer. 6. Temperature measurement. 7. Tube and showerhead examples.5: Chemistry for CVD.1. What does the C stand for anyway? 2. Volatility, the V in CVD. 3. Equilibrium: Where things are going. 4. Kinetics: The slowest stepwins. 5. Real precursors for real films. 6. Tube reactor example. 7. A few final remarks.6: Gas discharge plasmas for CVD.1. Plasma discharges: An instant review. 2. The low-pressure cold-plasma state. 3. Key parameters for capacitive plasma state. 4. Alternative excitation methods. 5. Plasmas for deposition. 6. Plasma damage. 7. Technical details. 8. Ongoing example: Parallel plate reactor. 9. A remark on computational tools.7: CVD films.1. Why CVD? 2. Silicon dioxide. 3. Silicon nitride. 4. Tantalum pentoxide. 5. Metal deposition by CVD. 6. Concluding remarks.8: CVD reactors.1. CVD reactor configurations. 2. Tube reactors. 3. Showerhead reactors. 4. High density plasma reactors. 5. Injector-based atmospheric pressure reactors. 6. Reactor conclusions.Index.

Daniel Dobkin has been involved in the development, manufacturing, and marketing of communications devices, components, and systems for over 28 years. He holds a BS from the California Institute of Technology, and MS and PhD degrees from Stanford University, all in Applied Physics. He is the author of three books and 30 technical publications, and holds 7 US patents as inventor or co-inventor. He has given numerous talks and classes on radio-frequency identification in the US and Asia. He specializes in physical-layer issues: radios and signal generation, antennas, and signal propagation.