Solvent induced interfacial precipitation
301–304Solvent-based polymer pilot plant
348fSolvent-based polymeric binders
343–347Solvent-based resin pilot plants
346–347Spherical hollow silica (SHS) containers
320fSpherical hollow silica (SHS) nanoparticles
293fSpherical mesoporous silica (SMS) nanoparticles
293fspiro[1H-isoindole-1,9-[9H]xanthen]-3(2H)-one, 3,6-bis(diethylamino)-2-[(1-methylethylidene)amino](FDI)
27–28Standard anodization process
66–67Stannate conversion coatings
mitigation of corrosion using
acidic pickling surface modification in
549f,
551falkaline etching surface modification in
550f,
551fcompact protective coatings formation in
550f,
551fhydrogen evolution in
551tlocalized corrosion in
549fporous nonprotective coatings formation in
549fself-healing coatings formation in
550f,
551fself-healing functionality in
553Steel corrosion sensors
615fSteel substrates, in ZRPs
Stern-Volmer equation
620Stress corrosion cracking (SCC)
Stressed aluminum-coated optical fiber corrosion sensor
611,
612fStructural health monitoring (SHM)
603–604Styrene butylacrylate latex
358tSubstance of very high concern (SVHC)
68–69culturally significant works
649–650high performance protective coating
649–650Sulfate transport mechanism
68–69chemical composition of
39tCr content influencing
41under type-I corrosion conditions
37,
38f,
39funder type-II corrosion conditions
38fSuperhydrophobic coatings
Superhydrophobic conducting polymers, as anticorrosion coatings
424–427Surface coating technologies
engineering techniques
44–45overlay coatings as
42–44Surface engineering techniques
thermal spraying processes as
44–45electrolytic deposition for
591–592plasma electrolytic oxidation for
591pretreatment coating
65–66plasma electrolytic oxidation
591Surface plasmon resonances (SPRs)
basic structure of optical fiber sensor for
609fmetal corrosion detected by
616,
616fSurface-enhanced Raman spectroscopy (SERS)
678
T
Tetrakis(diethyl)-aminometal
115,
115tThermal spraying processes
detonation gun spraying as
45EB-PVD processes compared with
46tThermogravimetric test
51crystallographic forms of
593fTransgranular stress corrosion cracking (transgranular SCC)
546Transition temperature
466Transmission Electron Microscopy (TEM)
382Transmission spectra
626fTransmission switching
482fTransmittance switching
472fTransparent, Reversible, Applied, Commercially available, Environment (TRACE) criteria
642Trivalent chromium pretreatment (TCP) coatings
71–72Tuneable metamaterial devices
474–476Turn-on corrosion detector
27–28Type-II hot corrosion
34,
38f
U
Ultraviolet (UV) light exposure test
402Ultraviolet-induced chemical vapor deposition (UVCVD)
99,
99fUniversity of Illinois
24
V
Vacuum plasma spraying (VPS)
45hybrid metamaterial devices
473–476crystalline structure of
462felectrical resistivity of
470finfrared transmittance during
462fmicrowave switch design based on
482fatomic oxygen irradiation's effects on
466pump-probe result summary
472tRF-microwave switches based on
481–483valence band diagrams
463ftrend of luminescent properties
275–280trend of protective properties
261–275VO
2-based hybrid metamaterial devices
473–476VO
2-based RF-microwave switches
481–483
W
Warm spray process, as thermal spraying process
45Waterborne nanocomposites coatings
654–657Waterborne PVDF-clay nanocomposites
666–667Weathered coated substrates
651–654Weight fraction of microcapsules
516fWettability conversion
427fWide angle X-ray diffraction (WAXD)
660–661
X
Xanthosoma sagittifolium leaves
575–580
Y
Yttria precursors, CVD precursors as
110–112
Z
low carbon steel substrates
203–205