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Demand for advanced X-ray scattering techniques has increased tremendously in recent years with the development of new functional materials. These characterizations have a huge impact on evaluating the microstructure and structure–property relation in functional materials. Thanks to its non-destructive character and adaptability to various environments, the X-ray is a powerful tool, being irreplaceable for novel in situ and operando studies. This book is dedicated to the latest advances in X-ray diffraction using both synchrotron radiation as well as laboratory sources for analyzing the microstructure and morphology in a broad range (organic, inorganic, hybrid, etc.) of functional materials.
Technology: general issues --- History of engineering & technology --- Materials science --- lead-free ceramic --- sol–gel process --- barium zirconate titanate --- dielectric property --- conjugated polymer and blends --- in situ GIXD --- additive --- structure --- strain --- X-ray diffraction --- piezoelectric properties --- lanthanum-modified lead zirconate titanate (PLZT) --- zeolite-W --- cation form --- synchrotron X-ray diffraction --- Rietveld refinement --- high-pressure --- smectite --- bulk moduli --- anhydrous and hydrous environments --- synchrotron X-ray powder diffraction --- pressure-transmitting media --- metallic composites --- Ni --- Ni-W alloys --- silver-exchanged natrolite --- pressure-induced insertion --- high energy-density materials --- high pressure and temperature --- Raman spectroscopy --- ammonium azide --- polynitrogen compounds --- superalloys --- low-angle boundaries --- X-ray topography --- turbine blades --- crystal growth --- nano-perovskite (CaTiO3) --- Young’s modulus --- ultrasonic-pulse echo --- planar density --- residual stress --- laser cavitation peening --- pulse laser --- wedge-shaped amphiphile --- double gyroid phase --- grazing-incidence X-ray scattering --- environmental atomic force microscopy --- vapor annealing --- Williamson-Hall (W-H) --- uniform stress deformation model (USDM) --- hydroxyapatite --- ultrasonic pulse-echo --- thermoplastic polyurethane ureas --- shape memory materials --- synchrotron SAXS/WAXS --- polymer deformation --- lamellar morphology --- poly-ε-caprolactone --- poly(1,4-butylene adipate) --- lead-free ceramic --- sol–gel process --- barium zirconate titanate --- dielectric property --- conjugated polymer and blends --- in situ GIXD --- additive --- structure --- strain --- X-ray diffraction --- piezoelectric properties --- lanthanum-modified lead zirconate titanate (PLZT) --- zeolite-W --- cation form --- synchrotron X-ray diffraction --- Rietveld refinement --- high-pressure --- smectite --- bulk moduli --- anhydrous and hydrous environments --- synchrotron X-ray powder diffraction --- pressure-transmitting media --- metallic composites --- Ni --- Ni-W alloys --- silver-exchanged natrolite --- pressure-induced insertion --- high energy-density materials --- high pressure and temperature --- Raman spectroscopy --- ammonium azide --- polynitrogen compounds --- superalloys --- low-angle boundaries --- X-ray topography --- turbine blades --- crystal growth --- nano-perovskite (CaTiO3) --- Young’s modulus --- ultrasonic-pulse echo --- planar density --- residual stress --- laser cavitation peening --- pulse laser --- wedge-shaped amphiphile --- double gyroid phase --- grazing-incidence X-ray scattering --- environmental atomic force microscopy --- vapor annealing --- Williamson-Hall (W-H) --- uniform stress deformation model (USDM) --- hydroxyapatite --- ultrasonic pulse-echo --- thermoplastic polyurethane ureas --- shape memory materials --- synchrotron SAXS/WAXS --- polymer deformation --- lamellar morphology --- poly-ε-caprolactone --- poly(1,4-butylene adipate)
Choose an application
Demand for advanced X-ray scattering techniques has increased tremendously in recent years with the development of new functional materials. These characterizations have a huge impact on evaluating the microstructure and structure–property relation in functional materials. Thanks to its non-destructive character and adaptability to various environments, the X-ray is a powerful tool, being irreplaceable for novel in situ and operando studies. This book is dedicated to the latest advances in X-ray diffraction using both synchrotron radiation as well as laboratory sources for analyzing the microstructure and morphology in a broad range (organic, inorganic, hybrid, etc.) of functional materials.
Technology: general issues --- History of engineering & technology --- Materials science --- lead-free ceramic --- sol–gel process --- barium zirconate titanate --- dielectric property --- conjugated polymer and blends --- in situ GIXD --- additive --- structure --- strain --- X-ray diffraction --- piezoelectric properties --- lanthanum-modified lead zirconate titanate (PLZT) --- zeolite-W --- cation form --- synchrotron X-ray diffraction --- Rietveld refinement --- high-pressure --- smectite --- bulk moduli --- anhydrous and hydrous environments --- synchrotron X-ray powder diffraction --- pressure-transmitting media --- metallic composites --- Ni --- Ni-W alloys --- silver-exchanged natrolite --- pressure-induced insertion --- high energy-density materials --- high pressure and temperature --- Raman spectroscopy --- ammonium azide --- polynitrogen compounds --- superalloys --- low-angle boundaries --- X-ray topography --- turbine blades --- crystal growth --- nano-perovskite (CaTiO3) --- Young’s modulus --- ultrasonic-pulse echo --- planar density --- residual stress --- laser cavitation peening --- pulse laser --- wedge-shaped amphiphile --- double gyroid phase --- grazing-incidence X-ray scattering --- environmental atomic force microscopy --- vapor annealing --- Williamson-Hall (W-H) --- uniform stress deformation model (USDM) --- hydroxyapatite --- ultrasonic pulse-echo --- thermoplastic polyurethane ureas --- shape memory materials --- synchrotron SAXS/WAXS --- polymer deformation --- lamellar morphology --- poly-ε-caprolactone --- poly(1,4-butylene adipate)
Choose an application
Demand for advanced X-ray scattering techniques has increased tremendously in recent years with the development of new functional materials. These characterizations have a huge impact on evaluating the microstructure and structure–property relation in functional materials. Thanks to its non-destructive character and adaptability to various environments, the X-ray is a powerful tool, being irreplaceable for novel in situ and operando studies. This book is dedicated to the latest advances in X-ray diffraction using both synchrotron radiation as well as laboratory sources for analyzing the microstructure and morphology in a broad range (organic, inorganic, hybrid, etc.) of functional materials.
lead-free ceramic --- sol–gel process --- barium zirconate titanate --- dielectric property --- conjugated polymer and blends --- in situ GIXD --- additive --- structure --- strain --- X-ray diffraction --- piezoelectric properties --- lanthanum-modified lead zirconate titanate (PLZT) --- zeolite-W --- cation form --- synchrotron X-ray diffraction --- Rietveld refinement --- high-pressure --- smectite --- bulk moduli --- anhydrous and hydrous environments --- synchrotron X-ray powder diffraction --- pressure-transmitting media --- metallic composites --- Ni --- Ni-W alloys --- silver-exchanged natrolite --- pressure-induced insertion --- high energy-density materials --- high pressure and temperature --- Raman spectroscopy --- ammonium azide --- polynitrogen compounds --- superalloys --- low-angle boundaries --- X-ray topography --- turbine blades --- crystal growth --- nano-perovskite (CaTiO3) --- Young’s modulus --- ultrasonic-pulse echo --- planar density --- residual stress --- laser cavitation peening --- pulse laser --- wedge-shaped amphiphile --- double gyroid phase --- grazing-incidence X-ray scattering --- environmental atomic force microscopy --- vapor annealing --- Williamson-Hall (W-H) --- uniform stress deformation model (USDM) --- hydroxyapatite --- ultrasonic pulse-echo --- thermoplastic polyurethane ureas --- shape memory materials --- synchrotron SAXS/WAXS --- polymer deformation --- lamellar morphology --- poly-ε-caprolactone --- poly(1,4-butylene adipate)
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