Controllable nanostructures in spin coated titanium oxide (TiO2) films have been achieved by a very simple means, through change of post deposition annealing temperature. Electron beam imaging and reciprocal space analysis revealed as-deposited TiO2films to be characterized by a dominant anatase phase which converts to the rutile form at 600 °C and reverts to the anatase modification at 1,200 °C. The phase changes are also accompanied by changes in the film microstructure: from regular nanoparticles (as-deposited) to nanowires (600 °C) and finally to dendrite like shapes at 1,200 °C. Photoluminescence studies, Raman spectral results, and X-ray diffraction data also furnish evidence in support of the observed solid state phase transformations in TiO2.
Keywords:Nanostructured TiO2; Phase transformations; Photoluminescence; Spectroscopy
Nanostructured materials are of great interest due to their tunable microstructure, phase transformations and quantum confinements, required for potential usage [1-3]. Among these nano—particles, wires, rings, combs, tetrapods of materials such as ZnO [4-8], WO3[9-12], and TiO2[13-21] are most desired for various semiconducting, electrochromic, and mechanical applications. TiO2 has been reported a versatile material, required for sensors , optical devices [15,16,23,24], photocatalysis , photoelectrochemical [26-28], tribological [29,30], and bio-compatible surgical instruments [31,32]. Recently thermally evaporated TiO2 nanowires have been examined and an efficient photoluminescence was registered in the blue region . In our preliminary observations  a correlation between microstructural features of sol–gel derived TiO2 and photoluminescence has been attempted.
The applications of TiO2pertaining to engineering, semiconducting, and medicinal industries are enormous and expected to enhance by manifold times if the material is nanostructured to design fundamental nanodevices. However, detailed experimental studies on crystalline phases and the stability of microstructures of TiO2that normally are temperature dependent are imperative to enable their use for any practical device. In this context, the present report provides a systematic evaluation of phase transformations and morphological features of TiO2films by use of electron beam imaging and corresponding reciprocal space interpretations. These nano-scaled modifications upon annealing complement Raman and photoluminescence spectroscopic results.
Titanium oxide powder (Degussa, P25) was used as received. The powder was sonicated in polyethylene glycol 400 and the resulting white, homogeneous dispersion was spin coated at 3,500 rpm for 30 s on SnO2:F coated glass-substrates. Subsequently these films were subjected for annealing at different temperatures, viz., 450, 500, 600, and 700 °C for 2 h. This dispersion was heat treated in an alumina crucible at 1,100 and 1,200 °C for the same duration. The powder was then grounded for 1 h and then re-dispersed in ethanol. The resulting suspension was spin coated and the films were heat treated at 150 °C. A transmission electron microscope (TEM, model FEI CM12) was employed for microstructural imaging and phase analysis. Several samples of TiO2for TEM characterization were prepared by a careful removal of these films from the substrate using a sharp-edged surgical blade. In this process the films with 1–2 mm in dimension were possible to load on commercially available copper grids (diameter: 3.05 mm) of 200 mesh-pore size. Surface morphology was characterized with an environmental scanning electron microscope (SEM, model Hitachi TM1000). Photoluminescence investigations were performed on a Perkin Elmer LS-55 luminescence spectrometer and Raman spectra were recorded on a Perkin-Elmer GX 2000 OPTICA spectrophotometer.
Results and Discussion
Evolution of Microstructures and Phase Transformations
The bright field micrograph of an as-deposited TiO2film (Fig. 1a) shows the film to be constituted by randomly distributed particles, 2–10 nm in size. At higher magnifications, polyhedral morphologies of nanoparticles with well-defined facets were observed (Fig. 1b). A corresponding selected area electron diffraction pattern (SADP) shows the Debye rings in reciprocal space (Fig. 2a) which arise from the anatase crystal structure (body centered tetragonal and space group I41/amd) of TiO2with lattice constantsa = 0.38 nm andc = 0.95 nm. The planes of anatase (101, 004, 200, 105, 211) structure are marked on the different rings in SADP (Fig. 2a).
Figure 1. TEM bright field micrographs of nanoparticles in as-deposited condition showingahomogeneous distribution andbdifferent shape and size
Figure 2. Selected area electron diffraction patterns recorded from samples ofaas deposited and different annealing conditions;b450 °C andc700 °C
Annealing the as-deposited TiO2film at 450 °C is accompanied by grain growth as uniformly distributed particles of 10–25 nm dimensions were observed (Fig. 3a) in the annealed film. The corresponding SADP comprises additional rings (as compared to the SADP of as-deposited film in Fig. 2a) and these new rings belong to the rutile crystal structure (primitive tetragonal; space group P42/mnm) of TiO2with lattice constantsa = 0.45 nm andc = 0.29 nm. The existence of two-phase mixture in the film annealed at 450 °C is indicative of initiation of solid-state phase transformation and this phase transformation does not get completed even at 600 °C, as even at this temperature both rutile and anatase phases were found to be co-existent in the film (SADPs not shown here). The nanoparticulate morphology does not register much change as annealing temperature was raised from 450 to 500 °C and this can be easily perceived from Fig. 3b. But particle size grows visibly when the film was annealed at 600 °C (Fig. 3c). On increasing the annealing temperature to 700 °C, a substantial transformation of crystal structure and microstructure of TiO2was registered. The film now has a smooth faceted surface and particles size lies in the range of 30–60 nm and the grain shapes are largely cubical and euhedral (Fig. 4a–c). The corresponding SADP shows a complete phase transformation from anatase to rutile crystal structure with lattice constantsa = 0.45 nm andc = 0.29 nm. The corresponding planes (110, 101, 111, 211, 002) are marked on the Debye rings in SADP (Fig. 2c) and no planes related to the anatase phase were seen. At this temperature, elongated wire type structures were also formed. One such nanowire of about 40 nm diameter with a length of about 100 nm is shown in Fig. 4c. Formation of nanowires indicates a preferred growth of certain high-density crystallographic planes of rutile phase at the lattice scale. This variation in particle shapes as a function of annealing temperature is also illustrated schematically in Fig. 5. Attempts were made to correlate the grain coarsening and annealing temperature to fit with an exponential function, to obtain a general trend of heating on such oxides. The continuous curve was drawn after data fitting (Fig. 5) with an equation of the form:y = cexp. (x/t), whereyandxare coordinate axes representing particle size and annealing temperature, respectively. The constantscandtare 5.17 and 2.34, respectively.
Figure 3. TEM bright field micrographs of nanoparticles in different annealing conditions;a450 °C,b500 °C andc600 °C
Figure 4. TEM bright field micrographs (a–c) of nanoparticles annealed at 700 °C
Figure 5. Graphical presentation of size of nanoparticles with annealing temperature. A corresponding data fitted polynomialy = cexp. (x/t) showing a good agreement between theory and experiment
The mechanism for the solid state phase transformation from anatase to rutile at high temperatures is not clear, especially when the particle size is of the order of tens of nanometers. We conjecture that on annealing as-deposited TiO2, the rearrangement of Ti and O atoms is such that the unit cell of TiO2 tries to be more uniform in all three axes (a,b,c) to attain a more stable and defect-free configuration. This phenomenon reduces the value of c/a from 2.51 (anatase) to 0.65 (rutile) significantly and hence the volumes of basic unit cell as well. The unit cell of rutile is more dense (ρ = 4.25 g cm−3) compared to anatase (ρ = 3.894 g cm−3). Although both anatase and rutile phases are tetragonal, but the rutile structure is close to cubic. The cubic structure is known to be the most symmetrical lattice (c/a = 1) and thermodynamically most stable. During the crystallographic transition, the movement of atoms is such that the highest atomically dense plane (101) of the anatase phase becomes the second most intense plane of the rutile structure. Moreover the (110) plane evolves as the highest atomically dense plane in the rutile structure, which is not a preferred plane for atomic sites in the anatase form. Recently the transformation from anatase to rutile on annealing at the temperature about 800 °C has been investigated by Wu et al. . Figure 6 represents a schematic, delineating these two planes: 110 and 101 in anatase and rutile unit cells, respectively, of TiO2. This is remarkable as the 110 plane of rutile has also been found to be responsible for the growth of TiO2 nanowires  with a single crystalline structure.
Figure 6. Schematics of anatase- and rutile- unit cells marked with 101 and 110 planes and lattice points
In a similar fashion, here annealing at 700 °C steers the preferred growth under specific crystallographic directions, which in turn initiates the formation of nanowires. For the film grown from the sample annealed at 1,100 °C, nanoparticles and nanowires/fibers ensconcing a granular morphology were seen. The SEM micrograph of this film reveals this unique fibrous and particulate morphology for TiO2(Fig. 7a, b). Figure 7a shows overlapping regions of nanograins and wires and Fig. 7b shows a few aggregated nanowires (region marked as A) that appear to originate from a porous nano-grained structure (region marked as B). A set of intermingled nanowires, abutting each other, are further elucidated as inset in Fig. 7b. The TEM image of this film (Fig. 8a) shows short length porous nanowires as the principal component in the sample annealed at 1,100 °C. The inset of Fig. 8a shows two parallel single crystalline nanowires of same diameter (~10 nm) and length (~500 nm). A SADP recorded on this nanowire along the  zone axis of rutile–tetragonal has been displayed as inset in Fig. 8a. However, further annealing at 1,200 °C causes the collapse of the nanowires to yield a dendrite like shape of a main stem consisted with fine branches of nanoparticles (Fig. 8b). At this stage, it was observed that the main stem (primary branch) of the dendrite continues to have a rutile structure, whereas the grains associated with secondary branches have an anatase structure. The inset of Fig. 8b shows the SADP recorded from one of these secondary branches, along the  zone axis of anatase crystal structure with 110 and 10 planes marked therein.
Figure 8. TEM bright field micrographs of different annealing conditions;a1,100 °C—nanowires and fibrous grains and (b) 1200 °C—dendritic growth. Insets are SADPs fromarutile along  andbanatase along [001 zone axes
The overall microstructural transformation can be summarized as follows: from faceted granular (up to 700 °C, Figs. 1–4) structure to fibrous grains/wires (at 1100 °C, Fig. 8a) and finally to dendrites (at 1,200 °C, Fig. 8b). The schematic in Fig. 9shows the transformation from nano-grained microstructure below 700 °C (Fig. 9a), initiation of nanowire formation at 700 °C (Fig. 9b), growth of nanowires at 1,100 °C (Fig. 9c), and collapse of nanowires to ensue in dendrite like shapes at 1,200 °C (Fig. 9d). It appears that the fibrous features (at 700 °C) evolve due to solid-state phase transition, which is accompanied by lessening of strain and reduction of defects prevalent at the lattice scale in the material. The mottled contrast in the micrograph of the film annealed at 700 °C arises due to the strain present at lattice scale. Annealing allows the formation of a more thermodynamically stable microstructure and therefore wire like shapes with effective surface are higher than that of regular particles are formed at 1,100 °C. It is evident that the rutile phase triggers the growth of nanowire as at 1,200 °C when the anatase phase re-appears, the wire morphology gives way to a fibrous structure encompassing a regular granular phase.
Figure 9. Mechanism showing different microstructural transformations on annealing at temperatures:aas deposited,b700 °C,c1,100 °C, andd1,200 °C
XRD patterns of TiO2films annealed at different temperatures are shown in Fig. 10. For the as-deposited film, the intense peaks due to the planes (hkl): 101, 103, 004, 200, 105, 211, 204, 116, 220, 215, 303, 312 of the anatase phase of TiO2in accordance with PDF number 21-1272 corresponding to the interplanar spacings (d): 0.35, 0.242, 0.237, 0.187, 0.169, 0.166, 0.148, 0.136, 0.134, 0.126, 0.12, 0.117 nm, respectively, are marked on the diffractogram (Fig. 10a). At 1,100 °C, the phase transformation from anatase to rutile structure is complete as peaks corresponding to single phase rutile crystal structure with the planes (hkl): 110, 101, 200, 111, 210, 211, 220, 310, 221, 301, 112, 321, corresponding to interplanar spacings (d): 0.323, 0.247, 0.229, 0.218, 0.205, 0.166, 0.162, 0.148, 0.145, 0.136, 0.134, 0.117 nm, are seen in the diffractogram (Fig. 10b) as per PDF number 21-1276 from the JCPDS library of spectra. The partial transformation of rutile phase into anatase (as seen from TEM in Fig. 8b) on annealing the sample at 1,200 °C is also supplemented by the XRD data, as an extra peak at interplanar spacing of 0.35 nm corresponding tohkl:101 of anatase phase is seen in the diffractogram of this sample (Fig. 10c). All other peaks in the XRD pattern at this temperature (1,200 °C) still belong to the rutile phase.
Figure 10. XRD patterns from TiO2in different conditions;aas deposited,bandcannealed at 1,100 and 1,200 °C, respectively. an: anatase, ru: rutile
Photoluminescence and Spectroscopy Measurements
Photoluminescence (PL) spectra recorded at room temperature from the different annealed samples (at 700, 1,100 and 1,200 °C) are depicted in Fig. 11. The emission of the samples was recorded at excitation wavelength of 200 nm, under similar excitation conditions. In all three samples, three peaks corresponding to UV, blue, and green are observed. The different emissions observed in present work can be seen from Fig. 12. EUVEb, and Eg are energies corresponding to the emission bands maxima for the UV (414–422 nm), blue (470–483 nm), and green (518–526 nm), respectively. The UV emission originates from interband transition of electrons and the visible emission is due to transition of electrons from shallow donor level of the oxygen vacancies in the valence band. The oxygen vacancies evolved during growth of the material, trap electrons and thus become paramagnetic and give the characteristic electron spin resonance signal. When the material gets exposed to ultraviolet, these vacancies then become susceptible to trap holes generated by the UV exposure. The recombination of hole with the electron already trapped at the oxygen vacancies emits light, which is generally in the visible region. A net energy-peak shifts in all these samples, showed that the blue shift is significant (∆E = 0.072 eV, Table 1) with the annealing temperature. However, we did not observe considerable change in intensity of various bands with annealing at these temperatures (700, 1100, and 1,200 °C). In our previous study , the emission bands recorded up to maximum annealing temperature of 700 °C showed a trend of decreasing PL intensity with increasing temperature and the observations were understood on the basis of the various processes such as self-trapped excitons recombination which is a combined effect of defect centres generated from oxygen vacancies and particle size variation. In the present case, a dominant blue shift with increasing annealing temperature with considerable variation in PL intensity may be attributed to structural transformation from anatase to rutile and then partial transformation of rutile to anatase on increasing annealing temperature.
Figure 11. Photoluminescence spectra of TiO2in different annealed conditions: 700, 1100, and 1,200 °C. Symbols: excitation at 205 nm (- - -); 700 °C (—); 1100 °C (…); 1200 °C (– · –)
Figure 12. Schematic showing a general energy band diagram describing the photoluminescence of nanostructured TiO2
Table 1. Effect of annealing conditions on different photoluminescent emission peaks of TiO2
Raman spectra of TiO2 films are shown in Fig. 13. Raman bands in anatase phase (in as-deposited condition) exist at Raman shifts corresponding to 398 (B1g), 515 (A1g) and 640 (Eg) cm−1 of vibrational modes. In contrast, the Raman bands in rutile phase (annealing at 1,100 °C) reveals frequencies at 448 (Eg) and 612 (A1g) cm−1 of corresponding vibrational modes. However, the prior studies have further been confirmed by studying the samples annealed at 1,200 °C. A weak Raman shift (515 cm−1, A1g of anatase phase) in addition to strong peaks (448, 612 cm−1:Eg and A1g of rutile phase) shows that there is a partial phase transition of rutile to anatase at 1,200 °C. The peak shifts arise due to different influences on change in the polarizability of electronic structures of rutile and anatase (although both are tetragonal with the same group: D194h). The corresponding energy level diagram for Raman scattering (Fig. 14) in the present work shows the peak due to anatase at high temperatures (1,200 °C) although this phase is not a thermodynamically stable phase and is not revealed between 700 and 1,100 °C. The optical phonon energies corresponding to different vibrational modes in anatase and rutile phases are very small, but the fine structural changes at lattice scale are significantly visible in the energy band diagram. The fine energy shifts in UV, blue, and green emissions in photoluminescence are also dependent on these vibrational states upon photoexcitation. For example the energy-shifts in photoluminescence at different annealing conditions in UV, blue, and green as plotted in Fig. 4, 0.048, 0.072, and 0.038 eV, respectively, (Table 1) are of the order of Raman active vibrations (Fig. 14) in different anatase and rutile structures of TiO2. This implies that the Raman active optical phonons are excited due to external energy and subsequently assist the band-to-band recombination (UV region) and transitions due to different surface states and defects (blue and green region). It has been stated  that the band-to-band recombination (anatase phase) can be considered as a two phonons (Eg(ν5):0.017 eV + Eg(ν6):0.024 eV = 0.041 eV)−one photon (0.04 eV) coupling course. The kinetics of the conversion of anatase to rutile has been studied in the past  by Raman spectroscopy. Authors in  observed a sequential change in intensity of the anatase form were observed with laser irradiation time and it was noticed that there is a rise of 236 cm−1 (rutile) and fall of 515 cm−1 (anatase). But in the present work at high temperature (1,200 °C) the initiation of 515 cm−1 (anatase) and a sharp decrease in intensity of 44 and 612 cm−1 (rutile) bands has been observed for the first time. This is possible only if the TiO6 octahedra (rutile at 1,100 °C) is distorted at 1,200 °C in such a way that it tends to achieve anatase-crystallographic symmetry and in this process a vibrational mode of anatase at 515 cm−1 is seen in the Raman spectrum. Since the transformation of rutile to anatase is not complete at this temperature (1,200 °C), bands at 448 and 612 cm−1 of rutile phase continue to exist in the spectrum.
Nano-scaled morphological and crystallographic transformations in a sol–gel derived TiO2have been studied employing highly precise and complementary techniques like TEM, XRD, and Raman spectroscopy. The nanostructural transformations from particles to wires initiate at 700 °C and significant growth of wires takes place at 1,100 °C. However, our further investigations have delineated that at 1,200 °C the wires undergo a nanostructural instability and leads to branching on nanowires. Nano-scaled features obtained on annealing at different temperatures are related with the different crystal structures of TiO2. Wire formation takes place when the anatase phase transforms to rutile structure of TiO2(annealed at 700–1100 °C). A noteworthy feature was delineated as the rutile phase partially transforms to anatase again at 1,200 °C. Moreover these different nano-objects have been further evaluated for their performance as luminescent materials.
One of the authors (MD) acknowledges the financial support from Department of Science and Technology (Grant no. 91330). S. Bhandari acknowledges University Grants Commission (UGC) for junior research fellowship. Drs. D.P. Singh, D. Gupta and D. Harnath are gratefully acknowledged for recording XRD, Raman spectroscopy, and photoluminescence data.
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