1. Introduction

In recent years studies involving in situ X-ray diffraction using synchrotron radiation have increased tremendously and have proved to be milestones in studies of time-resolved crystallization and structural changes in several materials (Zolliker et al., 1990; Danzig et al., 1995; Morris et al., 1996; Svensson et al., 1997; Liang et al., 2003; Natter et al., 2000; Beale & Sankar, 2003). Although some studies use in situ X-ray diffraction (Danzig et al., 1995; Gualtieri et al., 1996; Natter et al., 2000) or small-angle X-ray scattering techniques (Vleeshouwers, 1997; Kranold et al., 2003) to study the kinetics of growth, crystallization and particle nucleation, such studies are conducted using only one detection system. Certainly, interest in these studies is of fundamental importance for controlling the synthesis and determining particle size and distribution as desired. Good control of theses parameters is the main reason for these materials to be used for futures applications (Jana et al., 2004).

In our previous work (Meneses et al., 2007a) we emphasized theoretical and experimental studies using X-ray absorption near-edge spectroscopy (XANES) to investigate the crystallization process of NiO nanoparticles. In this study we verified the amorphous–crystalline transitions and determined the initial temperature of the growth process of the nanoparticles. However, in the particular case of NiO nanoparticles, it was not possible to obtain via XANES spectra quantitative information on the particle growth or check nucleation rates for the growth of these particles. In this paper we have studied the crystallization process in order to obtain quantitative information on the growth of NiO nanoparticles through analysis of in situ X-ray powder diffraction (XRPD) using synchrotron radiation by two detection systems: a conventional detector for the θ–2θ linear mode, and an imaging plate using the scattering-reflection mode. The results were also analyzed for two different heating rates to study the growth rates of the particles at different temperatures.

2. Experimental

All experiments were performed using the six-circle diffractometer (Huber) with θ–2θ analyzer on beamline D10B-XPD at the Brazilian Synchrotron Light Laboratory (LNLS), Campinas, Brazil (Ferreira et al., 2006). For such experiments two sets of 1.3 mm slits were used, both located between the input and output beam in the sample. The beamline has a focused optical beam with a pre-mirror, a double-crystal Si monochromator and a cylindrical mirror focus. The wavelength used in the experiments was 1.4938 (5) Å. A schematic view of the imaging-plate system is shown in Fig. 1. Measurements obtained using the imaging-plate detector were collected in the scattering-reflection mode using a beam exposure time of 2 min. The diffracted data were collected in the 2θ range 20–70°. Therefore we only use the two most intense peaks of cubic NiO. The data were collected on a Fuji flat (20 × 40 cm) and scanned using an XXX scanner. The imaging plate was mounted perpendicular to the incoming beam at a distance of ∼20 cm from the sample (Fig. 1). The conversion from pixels to angle 2θ was carried out using parameters determined from Rietveld refinement of Al₂O₃ (SRM 676) standard sample peak positions. The full width at half-maximum for each peak of the sample was corrected for instrumental broadening for the two systems using a standard sample of Al₂O₃ (size ∼10 µm). For the other experiments a Cyberstar scintillator detector was used, continuously scanning in 2θ from 39 to 45° in steps of 0.01° at an angular speed of 0.01° s⁻¹ to obtain the most intense peak of NiO {002}.

Figure 1 Photograph and schematic view of the experimental set-up of the imaging-plate detector and components.

In all experiments fine powders of the precursor material of composition NiO/NaCl (amorphous/crystalline), prepared as described by Meneses et al. (2007b) and pre-treated at 573 K for 30 min, were synthesized (the NaCl was used to correct the angular positions of the peaks). 150 mg of the material was pressed into pellets [10 mm × 3 mm (diameter × thickness)] and placed in a ceramic sample holder, which was rotated at constant speed. The sample holder was placed in a circular furnace at ambient atmosphere and positioned at a distance of 3 mm from a temperature sensor, a type-K thermocouple. In both experiment types (imaging plate and conventional) we used two heating rates, 5 and 10 K min⁻¹, up to 773 K and diffraction patterns were collected in steps each of 15 K starting from 623 K, waiting for 1 min to stabilize at each measurement. This temperature was chosen according to the thermal analysis of the crystallization process found in XANES measurements (Meneses et al., 2007c) and the pre­liminary results of thermogravimetric analysis reported by Maia et al. (2005), where the first crystallization stage was observed. Diffractograms were collected for both systems after thermal equilibrium was reached, i.e. after about 1 min. For the experiments using the imaging-plate detector, the sample in the sample holder was placed in the furnace and the furnace kept at an angle of 16.7° relative to the incident beam, as shown in Fig. 1(b).

3. Results and discussion

All results and analysis presented here show the kinetics of the formation and growth of NiO nanoparticles through in situ XRPD studies for two heating rates, 5 and 10 K min⁻¹. Fig. 2 shows X-ray diffraction (XRD) patterns obtained from conventional θ–2θ measurements. These results show only the evolution of the reflection {002} of the face-centred-cubic NiO and a peak corresponding to the reflection {220} of NaCl. At 593 K the structure is crystalline-like, indicating the initial stage of formation of NiO nanoparticles. These results show that the onset of crystallization and growth of NiO particles takes place at 693 K. Regardless of the heating rates, it is evident from the inset of Fig. 2(a) that the intensity of the reflections of NiO increases with increasing temperature, which is attributed to the gradual increase in the number and size of particles, and particularly the improvement of crystallinity of the nanoparticles. These results show also that there is not dependence on heating rates in the particle growth. Fig. 3 shows clearly that no difference is observed for the samples treated with heating rates of 5 and 10 K min⁻¹. Moreover, it was found that the systems show two stages in the particle growth (before and after 673 K). The first stage can be attributed mainly to the nucleation process up to 673 K, indicating that the particles are amorphous. After this temperature, particle growth is fast, which is attributed to crystallization of the particles (grain growth). Differences in the two sets of samples were not detected, probably due to the acquisition time of the XRD pattern, which is relatively high compared with the growth rate of the particles.

Figure 2 X-ray diffraction patterns collected using the conventional detector, obtained at heating rates of (a) 5 K min−1 and (b) 10 K min−1.

Figure 3 Calculated particle size as a function of temperature obtained using the conventional detector.

To confirm our assumptions and determine the best conditions for nucleation and growth of the particles, we used an imaging-plate detection system. In this experiment it is possible to identify differences in the growth of the particles as a function of heating rate as compared to the results obtained by a conventional detection mode. Fig. 4 shows the XRD patterns of the reflections {002} and {111} of NiO as a function of the temperature and heating rate. One can conclude that this set of results yields a better way to observe the growth of particles by means of peak profiles. We note a clear increase in the intensity from 698 K and 728 K for the samples treated at 5 K min⁻¹ and 10 K min⁻¹, respectively. This result indicates the beginning of crystallization and growth according to the results obtained by the conventional system. However, it is worth noticing that the initial stage of crystallization and the differences between heating rates can be better observed using the imaging plates (see Figs. 3 and 5). It has been shown previously (Meneses et al., 2007a) through XAS experiment that this may be related to the nucleation time. Furthermore, we have observed that increasing heating rates decrease the growth rate of the particles. On the other hand, there is a compromise between the heating rates and the degree of disorder of the samples: the lower the heating rates the greater the degree of disorder (Meneses et al., 2007c). A higher degree of disorder can lead to stacking faults or dislocations of the planar lattice, increasing the effect of strain.

Figure 4 X-ray diffraction patterns collected using the imaging-plate detector, obtained at heating rates of (a) 5 K min−1 and (b) 10 K min−1.

Figure 5 Calculated particle size as a function of temperature obtained using the imaging-plate detector for crystallographic plane families {111} and {002}.

By using equation (1), as described by Danzig et al. (1995),

where D is the mean particle size estimated by Scherrer's equation, t is the time, T is the temperature and D₀ is the diffusion coefficient, the mean diffusion coefficients of reflections {111} and {002} for all XRD experiments were determined from measurement as a function of time at 593 K for 60 min. This temperature was fixed for all systems because the diffusion coefficient increases with temperature (Danzig et al., 1995). It was chosen as it determines the first stage of crystallization of the particles. This coefficient is an important parameter for controlling the particles' growth. The increase of this coefficient can lead to the system having a larger particles sizes distribution. We do not observe differences in the diffusion coefficient with the use of a conventional detection system (see Table 1). Moreover, the experimental data obtained from use of the imaging-plate detector show a decrease in dispersion coefficient with increasing heating rate. These results indicate that the heating rate influences the particle size. However, we are only able to detect this using the very sensitive imaging-plate technique.

4. Conclusion

To summarize, we have studied the growth and formation of NiO nanoparticles through in situ XRPD studies using two detection systems and an amorphous precursor made of salt and an organic agent. The results demonstrate the potential of time-resolved in situ XRPD using an imaging-plate detector to study the kinetics of formation and controlled growth of nanoparticles. The results also show that the heating rate used in the synthesis process is an important feature for controlling particle size. It was found that low heating rates accelerate growth of the particles.