Electron energy loss spectrometry of interstellar diamonds

Keyphrases

• Diamond 100%
• High-resolution Electron Energy Loss Spectroscopy (HREELS) 100%
• Effective Medium Theory 23%
• Spectral Features 11%
• Diamond Particles 11%
• Diamond Surface 11%
• Acid Dissolution 11%
• Physical Properties 5%
• Ion Effect 5%
• Deuterium 5%
• Isotopic Variation 5%
• Volume Fraction 5%
• Valence Electrons 5%
• Carbon Atom 5%
• Scattering Spectra 5%
• Analytical Error 5%
• Ion-molecule Reactions 5%
• Loss Data 5%
• Theory Calculation 5%
• Transmission Electron Microscope 5%
• Hydrogen-rich 5%
• Isotopic Anomalies 5%
• Endmember 5%
• Carbon Phase 5%
• Bearing Phases 5%
• Inelastic Scattering 5%
• R-process 5%
• Low Energy Loss 5%
• Allende 5%
• Solar Abundances 5%
• Carbonaceous Meteorites 5%
• Electronic Energy Loss 5%
• P-process 5%
• Ionization Edge 5%
• Large Specific Surface Area 5%
• Plasmon Peak 5%
• Lorentz Oscillator 5%
• Interstellar Space 5%
• Hydrogenated Amorphous Carbon 5%
• Mass-weighted Mean Diameter 5%
• Composite Dielectric 5%

Earth and Planetary Sciences

• Electron Energy 100%
• Energy Dissipation 100%
• Media Theory 66%
• Deuterium 16%
• Inelastic Scattering 16%
• Surface Area 16%
• Plasmon 16%
• Nitrogen 15 16%
• Dielectric Material 16%
• Carbonaceous Meteorite 16%
• Interstellar Space 16%

Physics

• Electron Energy 100%
• Deuterium 20%
• Inelastic Scattering 20%
• Plasmon 20%
• Electron Microscope 20%
• Dielectric Material 20%
• Solar Abundances 20%
• Carbonaceous Meteorite 20%
• Nitrogen Isotopes 20%