Barium Titanate is one of the most important ferroelectric materials which have many applications [1]. It belongs to a peroviskite structure as a ceramic so it needs to prepare BaTiO₃ ultrafine powder in order to reduce the calcination temperature, porosity, sintering temperature and sintering time [1]. All above parameters will lead to reduce the cost through reducing the energy and increase efficiency. The wide range of applications of BaTiO₃ includes preparing multi-layer ceramic capacitors (MLCCs), electro optical device, PTC and NTC resistors, piezoelectric actuators, transducers and chemical gas sensors. So that ultrafine powder is very necessary for these applications especially in (MLCCs) [1-7]. In this study, we try to discuss three chemical methods were used to prepare BaTiO₃ fine powder to conclude the best one according to the resultant phases, crystallite size, cost effective and time management.

In general, the three chemical techniques have been done depends on the roots those were used represented by, Titanium tetrachloride (TiCl₄) was used as a titanium source, Barium chloride (BaCl₂∙2H₂O) as a barium source and Sodium hydroxide (NaOH) and Oxalic acid (COOH)₂∙2H₂O were used as catalysts.

The First method (Sodium hydroxide-ethanol method): (10 ml) of TiCl₄ was added to (20 ml) of Absolute Ethanol to get yellow gummy solution. There is (10 ml) of distilled water was added gradually until got transparent solution. The resultant transparent solution was mixed with (70 ml) of (0.385 M) of BaCl₂, (220 ml) of (12 M) NaOH was added to the mixture. The reaction was carried out in water bath at (80˚C) for (5 hr). Then the resultant precipitate was subjected for washing and filtering (5 times), dried at (90˚C) for (12 hr). Calcination process was carried out at (850˚C) for (5 hr) to get BaTiO₃ ultrafine powder. The schematic diagram of the first method is shown in Figure 1.

The Second method (Oxalate method); this method was carried out by mixing (50 ml) of (1 M) of TiCl₄ (aqueous solution) with (50 ml) of (1.05 M) of Barium chloride (aqueous solution). The mixture was then added gradually to (50 ml) of (2.2 M) of Oxalic acid [8]. The reaction was carried out in water bath at (80˚C) for (15 min) the resultant powder was BariumTetanyl oxalate tetrahydrate [BaTiO(C₂O₄)∙4H₂O]. It was separated by filtration; washed and dried at (90˚C) for (12 hr). Calcination process was performed on two different parts, the first one was subjected to (600˚C) for (5 hr), the second part subjected to (850˚C) for (5 hr) to get BaTiO₃ ultrafine powder. The schematic diagram for the second method is shown in Figure 2.

The Third method (Sodium hydroxide method), the preparation was done by mixing (50 ml) of (1 M) TiCl₄ (aqueous solution) with (50 ml) of (1.05) M Barium chloride (aqueous solution). The mixture was added to (50 ml) of (7 M) of NaOH gradually. The reaction was carried out in water bath at (80˚C) for (5 hr) the resultant precipitate was then washed five times and dried at (90˚C)

for (12 hr). Precipitate calcination was done at (850˚C) for (5 hr) to get the fine powder. The schematic diagram for the third method is shown in Figure 3.

As well known, there are many techniques used to conclude the homogeneous powder represented by XRD, SEM and TEM. In our research it is concentrated on XRD to obtain the better method in preparation for simple reason represented by the availability of this apparatus in Iraq. Our study is concentrated on the searching of better method in preparation during different parameter as mentioned before, so, just only XRD technique is suitable to give us indication about which method is favor to produce BaTiO₃ fine powder through the investigation of crystal phase. We used for this purpose, X-ray diffractometer with CuKα₁ (λ = 1.5406 Ǻ) with voltage of (40 kV) and current of (10 mA). It was used to investigate the structure of BaTiO₃ powders at room temperature. The analysis was performed using XPowder software (http://www.xpowder.com) for calculations of lattice parameters and crystallite size. The second one is FullProfSuit software for Drawing XRD patterns and space group determination (http://www.ccp14.ac.uk). In addition to that there is XRD Database (PDF2# 05-626 for BaTiO₃) from International Center for Diffraction Data (ICDD) used to complete the specification of the powder produced.

Regarding to our expert in preparation of ceramic powder, it was clear that the chemical methods (sol-precipitation) were used to get homogeneous and ultrafine powder whereas the conventional one (solid state reaction) needs high temperature of approximately (1000˚C - 1400˚C) followed by grinding. The resultant microstructure has a large grain size and multiple phases (i.e., heterogeneous) and is inventably porous with high sintering temperature of about (1350˚C - 1450˚C). While the chemical method can produce ultrafine powder, homogeneous, high purity and low grain size and porosity which lead to reduce calcination temperature in the range (600˚C - 900˚C) in comparable with solid state reaction. Solid state reaction might be considered as indirect method while chemical methods (solution methods) are direct method because that the reaction was done in the solution directly between Ba⁺², Ti⁺⁴ and O^–2 directly to get BaTiO₃ precursor, that was clear by XRD as shown in Figure 4.

The results, for the first method, showed that the crystalline phase with tetragonal structure (a = b = 3.9841 Ǻ, c = 4.0162 Ǻ) with space group (P4 mm) was predominate. The crystallite size was calculated by using XPowder software according to Williamson Hall equation.

where B is full width at the half maximum (FWHM), d is the crystallite size, (ε) elastic strain and (θ) is the diffracted angle as shown in Figure 5. The results showed that the crystallite size is in the range (26 - 42 nm) and the non-uniform strain is about (0.18). While Guangneng [2], obtained cubic structure for BaTiO₃ before calcination.

The results of XRD for Oxalate method as shown in Figure 6, it was clear that before calcination we got amorphous phase for BaTiO(C₂O₄)∙4H₂O as a result of presence the carbon atoms and the water in the mixture. After calcinations, at (600˚C), the crystalline phase with cubic structure (a = 4.0073 Ǻ) was appeared with space group (Pm - 3 m). The calcination at (850˚C/5hr) tend to produce the crystalline phase with tetragonal phase (a = b = 3.999 Ǻ and c = 4.0053 Ǻ) with space group (P4mm). On the other hand, the crystallite size was in the range (21 - 25 nm) and the non-uniform strain is (0.246) for the sample calcined at (600˚C/5hr). Whereas the crystallite size was in the range (25 - 37 nm) and the non-uniform strain is (0.253) for the sample calcined at (850˚C/5hr). Hwu [1], obtained cubic structure BaTiO₃ for (600˚C/6hr) calcination and tetragonal BaTiO₃ for (800˚C/6hr) calcination, and the crystalline size were (32.41 nm) and (41.32 nm) for (600˚C) and (800˚C) calcination respectively, So Hwu’s results are similar to our obtainable result .

The results of XRD for the sample prepared by third chemical method as shown in Figure 9, it was clear that the prepared powder before calcination showed the crystalline phase with cubic lattice constant (a = 4.0247 Ǻ) with space group (Pm - 3 m), and after calcination at (850˚C) crystalline phase was still remains cubic lattice with lattice constant (a = 4.0025 Ǻ) and space group (Pm - 3 m) with slightly deviation in some of diffracted peaks as appeared in Figure 9. There are many unknown peaks as mentioned in (Figures 4, 9), return to the phase of TiO₂ that was present within the BiTiO₃ phase. In order to eliminate the unknown peaks in the 1^st and the 3^rd methods, it became necessary the increasing of NaOH molarity or increasing the reaction time and that demands more power in production tends to consider a high expensive methods.

The crystallite size was in the range (26 - 36 nm) and the non-uniform strain is (0.152) for the sample before

calcinations. The crystallite size was in the range (27 - 35 nm) and the non-uniform strain is (0.184) for the sample calcined at (850˚C).

Regarding to the obtainable results by three chemical methods used to prepare fine powder of BaTiO₃, we conclude that the best method for producing BaTiO₃ was the 2^nd method (Oxalate method) according to XRD. The XRD pattern for the 2^nd method shows all the peaks of BaTiO₃ and the crystallite size is in the range (21 - 25 nm) and (25 - 37 nm) for the sample calcined at (600˚C) and (850˚C) respectively. While the first and the third methods shows unknown peaks, which belong to TiO₂, in XRD pattern and have a larger crystallite sizes. The reason for selected the 2^nd method is the reaction time, which was (15 min) and it did not require washing and filtering. While the reaction time for the 1^st and 3^rd method was (5 hr) and it required washing and filtering for (5 times). The catalyst (Oxalic acid), the molarity was (2.2 M), while catalyst (NaOH), the molarity was (12 M) and (7 M) for the 1^st and 3^rd methods respectively. All these reasons, leads to conclude that the Oxalate method is the better one. For the third method the suggestion is to increase the NaOH molarity (i.e. NaOH: TiCl₄ = 8:1, 9:1,) to eliminate the unknown peak in XRD.