Keyphrases
FeMn
100%
Metal Molybdate
100%
Alkali Metals
100%
Perovskite Oxide
100%
Thin Film Preparation
100%
Thin Film Surfaces
100%
Chemical Looping
100%
Chemical Looping Oxidative Dehydrogenation
100%
Surface Characterization
50%
Molybdate
33%
La0.8Sr0.2FeO3
33%
La0.7Ca0.3MnO3
33%
Redox Catalyst
33%
Na2MoO4
16%
Core-shell Structure
16%
Oxygen Storage
16%
Fe-containing
16%
Thin Film Model
16%
Catalyst Materials
16%
Model Catalyst
16%
Low Carbon Emission
16%
SrTiO3
16%
Catalyst Optimization
16%
Dehydrogenation Catalyst
16%
Mn-Fe
16%
Surface Science
16%
Na-K
16%
Active Lattice Oxygen
16%
Core-shell
16%
Core Species
16%
Ethane Dehydrogenation
16%
Oxidative Conversion
16%
Chemical Sector
16%
C-H Bond Activation
16%
Molybdenum Trioxide
16%
Na2Mo2O7
16%
Propylene
16%
Polymer-assisted Deposition
16%
Industry Practice
16%
Oxidative Dehydrogenation
16%
Light Olefin Production
16%
Catalyst System
16%
K2MoO4
16%
Catalyst Design
16%
Perovskite Thin Film
16%
Oxidative Dehydrogenation of Propane
16%
STEM Careers
8%
Review Criteria
8%
Epitaxially Grown
8%
Energy Efficiency
8%
Carbon Dioxide
8%
Mechanistic Investigation
8%
STEM Interest
8%
Commercially Available
8%
High School Teachers
8%
Mechanistic Aspects
8%
Energy Solutions
8%
In Situ
8%
Olefins
8%
State Universities
8%
Polymeric Materials
8%
Active Species
8%
Ethylene
8%
Natural Gas
8%
Fellowship Program
8%
North Carolina
8%
Student Interest
8%
Impact Review
8%
Material Science
Oxidative Dehydrogenation
100%
Catalysis
100%
Thin Film Processing Method
100%
Alkali Metal
100%
Molybdate
100%
Oxide Compound
50%
Surface Characterization
50%
Thin Films
33%
Natural Gas
16%
Surface Science
16%
Molecular Beam Epitaxy
16%
Carbon Dioxide
8%
Polymer
8%
Chemical Engineering
Dehydrogenation
100%
Alkali Metal
100%
Perovskite
50%
Olefin
33%
Ethylene
16%
Molecular Beam Epitaxy
16%
Propylene
16%
C-H Bond Activation
16%
Carbon Dioxide
8%