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Keywords for progress in solid state chemistry
Prog. Solid St. Chem. Vol. 27. l-P- 1 11, 1999 Elsevier Science Ltd Printed in Great Britain
Pergamon
K E Y W O R D S FOR P R O G R E S S I N S O L I D S T A T E C H E M I S T R Y Authors should select a maximum of five keywords. Each keywords should be accompanied by the capital letter denoting the category from which the keyword has been selected. A. TYPES OF MATERIAL multilayers nanostructures non-crystalline materials optical materials organic compounds organometallic compounds oxides polymers quantum wells quasicrystals semiconductors surfaces superconductors thin films
alloys amorphous materials ceramics chalcogenides electronic materials elements fullerenes glasses inorganic compounds interfaces intermetallic compounds magnetic materials metals microporous materials
B. PREPARATION AND PROCESSING chemical synthesis crystal growth epitaxial growth laser annealing
plasma deposition sol-gel growth vapour deposition C. TECHNIQUES
ab initio calculations
differential scanning calorimetry (DSC) electron diffraction electron energy loss spectroscopy (EELS) electron microscopy high pressure infrared spectroscopy M6ssbauer spectroscopy neutron scattering
photoelectron spectroscopy positron annihilation spectroscopy Raman spectroscopy scanning tunnelling microscopy (STIVl) thermogravimetric analysis (TGA) ultrasonic measurements XAFS (EXAFS and XANES) X-ray diffraction
D. PROPERTIES AND PHENOMENA acoustical properties anelasticity anharmonicity charge-density waves colour centres critical phenomena crystal fields
crystal structure defects dielectric properties diffusion elastic properties electrical conductivity electrical properties contmued over~af
II
Keywords for Progress in Solid State Chemistry
D. PROPERTIES AND P H E N O M E N A - - c o n t i n u e d electrochemical properties electron paramagnetic resonance (EPR) electronic structure equations-of-state Fermi surface ferroelectricity fracture lattice dynamics luminescence magnetic properties magnetic structure mechanical properties microstructure M6ssbauer effect muon spin resonance ("#" USR) nuclear magnetic resonance (NMR) nuclear quadrupole resonance (NQR)
optical properties phase equilibria phase transitions phonons piezoelectricity radiation damage semiconductivity specific heat spin-density waves superconductivity superlattices surface properties thermal conductivity thermal expansion thermodynamic properties transport properties
Pergamon
K E Y W O R D S FOR P R O G R E S S I N S O L I D S T A T E C H E M I S T R Y Authors should select a maximum of five keywords. Each keywords should be accompanied by the capital letter denoting the category from which the keyword has been selected. A. TYPES OF MATERIAL multilayers nanostructures non-crystalline materials optical materials organic compounds organometallic compounds oxides polymers quantum wells quasicrystals semiconductors surfaces superconductors thin films
alloys amorphous materials ceramics chalcogenides electronic materials elements fullerenes glasses inorganic compounds interfaces intermetallic compounds magnetic materials metals microporous materials
B. PREPARATION AND PROCESSING chemical synthesis crystal growth epitaxial growth laser annealing
plasma deposition sol-gel growth vapour deposition C. TECHNIQUES
ab initio calculations
differential scanning calorimetry (DSC) electron diffraction electron energy loss spectroscopy (EELS) electron microscopy high pressure infrared spectroscopy M6ssbauer spectroscopy neutron scattering
photoelectron spectroscopy positron annihilation spectroscopy Raman spectroscopy scanning tunnelling microscopy (STIVl) thermogravimetric analysis (TGA) ultrasonic measurements XAFS (EXAFS and XANES) X-ray diffraction
D. PROPERTIES AND PHENOMENA acoustical properties anelasticity anharmonicity charge-density waves colour centres critical phenomena crystal fields
crystal structure defects dielectric properties diffusion elastic properties electrical conductivity electrical properties contmued over~af
II
Keywords for Progress in Solid State Chemistry
D. PROPERTIES AND P H E N O M E N A - - c o n t i n u e d electrochemical properties electron paramagnetic resonance (EPR) electronic structure equations-of-state Fermi surface ferroelectricity fracture lattice dynamics luminescence magnetic properties magnetic structure mechanical properties microstructure M6ssbauer effect muon spin resonance ("#" USR) nuclear magnetic resonance (NMR) nuclear quadrupole resonance (NQR)
optical properties phase equilibria phase transitions phonons piezoelectricity radiation damage semiconductivity specific heat spin-density waves superconductivity superlattices surface properties thermal conductivity thermal expansion thermodynamic properties transport properties