Vapor-Phase Stabilization of Biomass Pyrolysis Vapors Using Mixed-Metal Oxide Catalysts

Keyphrases

• Stoichiometric Ratio 100%
• Vapor Phase 100%
• Mg-Al 100%
• Mixed Metal Oxides 100%
• Mixed Metal Oxide Catalyst 100%
• Biomass Pyrolysis Vapors 100%
• Acidity 50%
• Detrimental Effects 50%
• High Surface Area 50%
• Deactivation 50%
• Catalytic Activity 50%
• Toluene 50%
• Divalent Cations 50%
• Successful Implementation 50%
• Multivariate Statistical Techniques 50%
• Catalyst Materials 50%
• Pyrolysis Products 50%
• Behavioral Activity 50%
• Al-Mg-Si 50%
• Tunability 50%
• Catalytic Behavior 50%
• Coke Formation 50%
• Catalytic Effect 50%
• Divalent 50%
• Al-Zn 50%
• Layered Double Hydroxide 50%
• Xylene 50%
• Aromatic Hydrocarbons 50%
• Deoxygenation 50%
• Deoxygenated 50%
• Trivalent Cations 50%
• Mg-Zn 50%
• Opportunities for Improvement 50%
• Catalyst Bed 50%
• Molecular Beam Mass Spectrometer 50%
• Metal Oxide Materials 50%
• Biomass Pyrolysis 50%
• Catalytic Upgrading 50%
• Decarbonylation 50%
• Pine Wood 50%
• Pyrolysis Vapors 50%
• Reaction Formation 50%
• Cation Species 50%
• Carbon Yield 50%
• Bio-oil Upgrading 50%
• Zn-Al 50%
• Decarboxylation Reaction 50%
• Mass Data 50%

Chemical Engineering

• Pyrolysis 100%
• Oxide Catalysts 100%
• Aromatic Hydrocarbon 50%
• Coke Formation 50%
• Pyrolysis Products 50%
• Catalytic Upgrading 50%
• Pyrolysis Reactor 50%
• Catalytic Fast Pyrolysis 50%