Magneto Luminous Chemical Vapor Deposition

The magneto luminous chemical vapor deposition (MLCVD) method is the perfect example of the "front-end green process." It employs an entirely new process that expends the minimum amount of materials in gas phase, yields virtually no effluent, and therefore requires no environmental remediation. Unlike the "back-end green process," which calls for add-on processes to deal with effluent problems, the newer MLCVD approach is a completely different phenomenon that has never been adequately described, until now.

Dispelling previous misconceptions and revealing new areas for investigation, Magneto Luminous Chemical Vapor Deposition describes the key process of dielectric breakdown of gas molecules under the influence of a magnetic field. It emphasizes behavioral distinctions between molecular gasses that cause plasma polymerization (such as methane and trimethylsilane) and mono-atomic gases (e.g., helium and argon) when dealing with the dielectric breakdown of the gas phase under low pressure. The author also reveals his minimum perturbation theory of biocompatibility. This is based on the realization that nanofilms prepared using MLCVD have unique, stable interfacial characteristics necessary to achieve a surface that can be tolerated in various biological environments.

The author presents alternating views based on NASA’s recent discovery that a magnetic field burst from the earth triggers the inception of the aurora borealis. Detailing similarities between this phenomenon and the inception of the magneto luminous gas phase described in this book, the author proposes that proof of the one occurrence could shed light on the other. Expanding on the author’s previous works, this book introduces new discoveries, highlights the newfound errors of previous assumptions, and juxtaposes many cutting-edge alternative views and anomalies associated with the field.

IntroductionContext of Term Used and NotionPlasmaElectric Discharge of GasGas PhasePolymerization & Material FormationSurface & InterfaceBio-CompatibilityGreen Deposition Coating of Nano FilmsFront-End Approach & Rear-End Approach in Green ProcessingLow Pressure MLCVD CoatiLayer-By-Layer (LBL) CoatingCost of Coating ProcessesSystem Approach Interface Engineering with Green Processes System Approach Interface Engineering for Corrosion ProtectionGreen System Approach Interface Engineering by Magneto-Luminous CVDPlasma Phase and Luminous Gas PhasePlasma PhaseLuminous Gas PhaseDielectric Breakdown of Gas PhaseSignificance of Dielectric Breakdown of Gas on Luminous Chemical Vapor DepositionBreakdown of Non-Deposition Gas & Deposition GasSource of Electrons for Electron Avalanche to Cause Gas Phase BreakdownInterfacial Electron TransferExperimental Examination of Gas Phase BreakdownFactors That Control the Transformation of Gas Phase Electron Negativity of Atoms & EFFICIENCY OF ELECTRON-IMPACT REACTIONSGas Phase Breakdown as Functions of the System ParametersInfluence of Magnetic Field on Luminous Gas PhaseInfluence of Magnetic Field on Roles of ElectronsShaping of Negative Glow near The Magnetron AnodeInfluence of Magnetic Field on the Dielectric Breakdown ProcessElectrons in Electric Field and in Magnetic FieldImplications of Magnetron Gas Phase BreakdownMagnetic Field Initiation of Luminous Gas PhasePolymer Formation Mechanism in Luminous GasFree-Radical Polymerization & Free-Radical Polymer Formation in Luminous Gas Phase Repeating Step Growth Polymerization (RSGP) MechanismCompetitive Ablation & Polymerization (CAP) PrincipleInfluence of Un-Accounted FactorsDissociation of Monomer MoleculesDependence of Polymer Formation on Operation ParametersOperation Parameters & Deposition KineticsOperation Parameters & Plasma Polymerization ProcessesDeposition KineticsProperties of Plasma Polymers and Domains of Plasma PolymerizationPartition of Deposition on Electrode and Deposition on Surface in GasMagneto-Luminous Chemical Vapor DepositionDomain of MLCVDToroidal Glow Surface without DepositionConfined Luminous Gas Phase in Low-Pressure Polymer Formation and Deposition in Low-Pressure Applications of Magneto Luminous Chemical Vapor DepositionImplantation of Imperturbable Surface State on Substrate MLCVD Nano Film for Bio-CompatibilityInterface Engineering for Adhesion of Coating