Type of Document Dissertation Author Gonzalez, Reinaldo J. URN etd-55691079662221 Title Raman, Infrared, X-ray, and EELS Studies of Nanophase Titania Degree PhD Department Physics Advisory Committee
Advisor Name Title Richard Zallen Committee Chair Alfred Ritter none Guy Indebetouw none James R. Heflin none Richey M. Davis none Keywords
- phase transitions
- nanocrystals
- infrared
- raman
- titania
- anatase
Date of Defense 1998-07-13 Availability unrestricted Abstract Sol-gel titania particles were investigated, primarily by optical techniques, by systematically varyingsynthesis, sample handling, and annealing variables. The material phases investigated were amorphous
titania, anatase TiO2, and rutile TiO2. Annealing-induced phase transformations from amorphous TiO2
to anatase to rutile were studied by Raman scattering, infrared reflectivity, infrared absorption, x-ray
diffraction, and electron energy-loss spectroscopy (EELS). Detailed experiments were carried out on
the effects of annealing on the Raman and infrared spectra of anatase nanocrystals. The frequencies of
the zone-center transverse optical (TO) and longitudinal-optical (LO) phonons of anatase were
determined and were used in analyzing the results obtained on composites consisting of annealed sol-
gel particles
The TO and LO frequencies of anatase were obtained from polarization-dependent far-infrared
reflectivity measurements on single crystals. These results, which determined the dielectric functions
of anatase, were used to explain infrared (IR) reflectivity spectra of titania nanoparticles pressed into
pellets, as well as the grazing-incidence IR reflectivity observed for titania thin films. Because of the
polycrystalline character of the titania nanoparticles, the surface roughness of the pressed pellets, and
the island-structure character of the thin films, effective-medium theories (appropriate for composites)
were used, along with the anatase dielectric functions, to interpret the experimental results.
The titania nanoparticles were prepared by the hydrolysis/condensation of Ti(OC2H5)4. A polymeric
steric stabilizer was used in the sol-gel synthesis in order to prevent continued agglomeration during
the condensation process. This yielded particles with a relatively narrow size distribution. The amount
of water used in the reaction determines the final particle size. Particles as small as 80 nm and as large
as 300 nm were used throughout this work. From the colloidal suspension, loose powders, pressed
pellets, and thin films were formed. These samples were subjected to different annealing processes at
temperatures ranging from room temperature up to 1000 C. Two different annealing atmospheres were
used: air (oxygen-containing) and argon (no oxygen).
The amorphous to anatase transformation was followed by in-situ IR transmission measurements
carried out during annealing. The particles as prepared are amorphous and the anatase phase could be
detected, using this sensitive IR technique, at temperatures as low as 150 C. This phase transition was
shown to be particle size dependent. It was also shown that introducing the stabilizer by means of the
alkoxide flask instead of the water flask (during the sol-gel synthesis) decreases the anatase to rutile
transformation temperature. Loose powders were found to transform more readily than dense pellets,
while island-structure films were found to be the hardest to transform. Even at 1000 C, most of these
films did not transform to rutile.
X-ray diffraction experiments were used to determine nanocrystal sizes in anatase samples obtained by
air and argon anneals at temperatures from 300 to 800 C. A correlation was found between Raman
band shape (peak position and linewidth) and crystallite size, but this correlation was different for air
anneals and for argon anneals. These experiments called for an interpretation based on a stoichiometric
effect rather than a finite size effect. Based on this interpretation, the as-prepared particles are slightly
oxygen-deficient, with a stoichiometry corresponding to TiO1.98.
In the electron energy-loss experiments, a special data-analysis technique was used to extract the EELS
spectrum of the titania nanoparticles from the observed substrate-plus-particles signal. This technique
successfully resolved the titania absorption-edge peak. Which was found to be momentum
independent. For low electron momentum, the results were consistent with the reported optical
absorption edge.
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