Photovoltaic Cells and Systems: SQU Journal for Science, 18 (2013) 25-32 © 2013 Sultan Qaboos University 25 Synthesis of Doped and non-Doped Nano MgO Ceramic Membranes Shiraz Labib Nuclear Chemistry Department, Hot Laboratories Center, Atomic Energy Authority, Cairo, Egypt, Email: dr_sh_labib@yahoo.com. ABSTRACT: Doped and non-doped MgO coated thin films on alumina substrates were prepared using a chelating sol-gel method under controlled conditions to prepare nanomaterials with unprecedented properties. The effect of doping of ZnO on thermal, surface and structural properties was investigated using DTA-TG, BET and XRD respectively. Also microstructural studies and coating thickness measurements of MgO thin film were conducted using SEM. An increase in the thermal stability of MgO with increasing ZnO doping percent was observed. The increase of ZnO doping percent showed a marked decrease in the average particle size of MgO powder as a result of the replacement of some Mg 2+ by Zn 2+ which has similar ionic radius as Mg 2+ . This decrease in particle size of MgO was also related to the decrease of the degree of MgO crystalinity. The increase of ZnO doping also showed a marked decrease in coating thickness values of the prepared membranes. This decrease was related to the mechanism of ZnO doping into a MgO crystal lattice. Keywords: MgO; MgO-ZnO; polymeric sol-gel; doping mechanism; nano properties; thin films. تحضير أغشية سيراميكية مطعمة وغير مطعمة من نانو أكسيد الماغنيسيوم شيراز لبيب الخارصيٌن كطبايار رقٌايط مطي بأكسٌدكسٌد الماغنٌسٌوم المطعم أكسٌد الماغنٌسٌوم و أفى هذا البحث تم تحضٌركل من :ملخص ظروف تحضٌر محكميط و ذليل لتحضيٌر ميواد نانومترٌيط عند sol-gelكسٌد األلومنٌوم باستخدام طرٌاط أعلى دعامار مصنعط من الخصياص و السيطحٌط و ذار مواصفار غٌر مسبوقط. تم عمل دراسط تأثٌر التطعٌم بأكسٌد الخارصٌن عليى المواصيفار الحرارٌيط حٌود و حط السطوحقٌاس مسا و الوزنًو التفاضلً يالتحلٌل الحرار ألكسٌد الماغنٌسٌوم و ذلل بدراسط الظاهريالبللورٌط و الشكل لٌط تطعٌم أكسٌد الماغنٌسيٌوم بأكسيٌد آ. تم استنتاج ع قط بٌن لألغشٌط المحضر اإللكترونًوسكوب الماسح راألشعط السٌنٌط و المٌك الثبيار الحيرارأل ألكسيٌد الماغنٌسيٌوم المطعيم ماارنيط فيًالخارصٌن و النتاصج المختلفيط للاٌاسيار المعنٌيط. هيذا و قيد ليوحظ تحسيٌن لألغشيٌط المحضير بزٌياد نسيبط التطعيٌم. يجسٌمار و السيلول البلليورالحجم فًلوحظ وجود ناصان و قد ألكسٌد الغٌر المطعم. با ن العنصيرٌن لمميا قيٌم أالخارصٌن خاصيط و بأٌونارٌونار الماغنٌسٌوم أبعض بإح لحجم الجسٌمار له ع قط فًوهذا الناصان تقليل سمك الطبقاث المحضرة لألغشيت بزيادة نسبت التطعيم. ٌضا السبب وراء أبا كما ٌوضح تارٌ األٌونًمماثلط لنصف الاطر ، الماغنيسيم المطعم ، مواد نانومتريت ، طبقاث رقيقت. Sol-gel: اكسيذ الماغنيسيم ، اكسيذ الخارصين ، طبقاث مفتاح الكلمات 1. Introduction gO is a highly ionic crystalline solid, which crystallizes into a cubic rock salt structure. It is characterized by a large band gap (7.8 eV), high thermal conductivity and stability (Raj et al., 2007). It has extensive applications in the area of toxic waste remediation, refractory, paint and superconductor products. It also shows excellent adsorption properties in enhanced surface areas and intrinsically higher surface reactivity (Niu et al., 2006). Due to its superior electronic properties, it can be used as a substrate for high temperature superconductor film deposition. It has a wide application in microwave devices (Raj et al., 2007). MgO thin films are of scientific and technological importance due to their applications in optical and electronic devices, in catalytic reactions, as protective coatings on metals and in gas sensors (Raj et al., 2007). Therefore, MgO is considered an important applied and economical material. Nano MgO ceramic membranes are prepared by a sol-gel process that offers enhanced homogeneity and better control for the size, the shape and the degree of agglomeration of the resulting nanocrystals, as well as simple compositional control and low processing temperature (Maensiri et al., 2007; Iyer et al., 2009; Desai et al., 2007; Caruntu, 2006; Cernea, 2005; M SHIRAZ LABIB 62 Willard et al., 2004). A better control of precursor reactivity may be achieved through the addition of chelating agents such as ß-diketones, carboxylic acids or other complex ligands (Cernea, 2005; Sanchez et al., 1988). This paper deals with the preparation of doped and non-doped nano MgO membranes using a polymeric sol-gel method that offers the possibility of controlling the synthesis of thin film hierarchical internal structure (Crisan et al. 2000). Doping MgO with ZnO is studied in order to create doped nanocrystals and nanostructures with unprecedented properties (Yang et al., 2010). The effect of ZnO doping on thermal, surface and structural properties is studied. Also microstructural studies and coating thickness measurements of MgO thin film are conducted. The relationship between the mechanism of ZnO doping into a MgO crystal lattice and the properties studied is discussed. 2. Experimental 2.1 Substrate preparation Disk alumina substrates of thickness (0.1cm), diameter (10 cm), pore size distr ibution (0.1 µm), and porosity (18.42 Vol. %) (Labib, 2006) were used for doped and non-doped MgO coating thin films. These substrates were synthesized by a polymeric sol-gel process using aluminium tri-second butylate (99.9 % Merck, Germany), distilled water, isopropyl alcohol (99.8 % Scharlau, Spain) and glacial acetic acid (98 % Merck, Germany). The precursors used were of A.R. grade. Glacial acetic acid (2 mol), as a chelating agent, was added to the alcoholic solution of aluminium tri-second butylate having the molar ratio (isopropyl alcohol/aluminium tri-second butylate: 5:1 respectively). This solution was stirred for ten minutes, then it was exposed to a controlled rate of hydrolysis with a diluted solution of isopropyl alcohol having the molar ratio (isopropyl alcohol/distilled H2O: 5:0.5 respectively). The prepared polymeric sol was stirred for ten minutes and then aged at room temperature for 48 h. The aged polymeric sol was dried at 120 o C for 1h, calcined at 500 o C for 1h, ground for 15 min, pressed uniaxially at 12 k.N using (poly vinyl alcohol) as a binder and then sintered at 1100 o C for 1h (Labib, 2006). 2.2 Membrane preparation Doped and non-doped MgO ceramic membranes were initially prepared using magnesium nitrate hexahydrate [99% Winlab, England], zinc nitrate hexahydrate [99% Merck, Germany], isopropyl alcohol [99.8% Scharlau, Spain], acetylacetone [≥ 99% Merck, Germany] and distilled water. All the reagents used were of A.R. grade. The composition of the prepared samples is shown in Table 1. Table 1. Composition of the prepared samples. Sample MgO % ZnO % M100 100 00 M99 99 01 M95 95 05 M90 90 10 Polymeric magnesium oxide sol was prepared by drop-wise addition of an alcoholic mixture of isopropyl alcohol (5.0 mol) and distilled water (1.0 mol) to the stirred alcoholic solution of magnesium nitrate hexahydrate and acetyl acetone having the molar ratio (isopropyl alcohol /magnesium nitrate /acetyl acetone: 10:0.8:1.6 respectively). The different doped MgO-ZnO sols were prepared by adding 1, 5 and 10% of zinc nitrate hexahydrate to each of the alcoholic solutions of 99, 95 and 90% of magnesium nitrate hexahydrate, followed by adding acetyl acetone. The mixed polymeric sols were prepared by drop-wise hydrolysis with the alcoholic mixture of isopropyl alcohol and distilled water. The different prepared polymeric sols were stirred vigorously for 20 min. The dip coat process was performed at room temperature by immersing alumina substrates into the different polymeric sols for 2 h (Peters et al., 2005), (immersion and withdrawal rate: 0.5 mm 1 s  ). After dip coating, the different ceramic membranes were left overnight to be dried at room temperature. The different prepared membranes and the unsupported membranes were dried at 200 o C for 1h with a heating rate of 3 o C 1 min  . The process of dipping, withdrawing and drying was repeated 6 times to obtain suitable coating thicknesses (Sekulic et al., 2006) and then the membranes were sintered at 400 and 600 o C for 6 h with a heating rate of 3 o C 1 min  . 2.3 Membrane characterization The thermal degradation behaviors of the unsupported membranes were studied using differential thermal analysis (DTA) and thermogravimetric (TG) analysis (Shimadzu 60, Japan). DTA/TG studies were performed by heating the sample from room temperature to 400 o C in an air atmosphere with a heating rate of 3 o C 1 min .  Specific surface area measurements were taken, applying the Brunauer-Emmet-Teller (BET) method, using (Nova 3200 Series, SYNTHESIS OF DOPED AND NON-DOPED NANO MgO CERAMIC MEMBRANES 62 USA). Prior to the analysis, the different samples were evacuated at 300 o C for 2h. Particle size values of the unsupported membranes were calculated from: dBET = 6/SSABET.ρsample (1) where, ρsample is the density of the samples used (Mikhail and Robens, 1975), ρsample was calculated from the density of MgO (ρMgO ) = 3.58 x 10 3 kg/m 3 and the density of ZnO (ρZnO) = 5.61 x 10 3 kg/m 3 taking into consideration the appropriate amount of both components (Samerjai et al., 2009). The crystal structures of the different unsupported membranes were identified using X-ray diffraction (XRD) (Philips X’pert multi-purpose diffractometer, USA). A copper-tube X-ray tube operating at 40 kV and 30 mA was used, and the wavelength Kα1 used was 1.54056 A 0 . The scan was performed over the range 2 (40-70). The identification of the crystalline phases present was done using the JCPDS database cards. The microstructures and coating thicknesses of the prepared membranes were studied using a scanning electron microscopy (SEM) (JEOL JSM-5600, Japan). Prior to SEM analysis, the samples were sputtered with a thin layer of gold using JEOL Fine Coat (JFC-1500 Ion Sputtering Device, Japan). 3. Results and discussion 3.1 Unsupported membranes 3.1.1 Differential thermal analysis-thermogravimetric analysis (DTA-TG) Thermal properties of the unsupported membranes were investigated using DTA/TG analysis and the corresponding curves are shown in Figure 1. Owing to the low heating rate used (3 o C 1 min  ), the samples were heated only to 400 o C. TG curve for the sample M100 shows two weight losses at T< 300 oC. The gradual mass loss below 300 o C could be assigned to the evaporation and the elimination of the bonded water, residual organic solvents as well as to the burning of nitrate groups from the metal nitrate precursor. This result was correlated to the two endothermic peaks of the DTA curve at T<100 oC (Li et al., 2008; Anas et al., 2010). The third distinct weight loss ~37.83% at 100- 400 o C was due to the crystallization of Mg(OH)2 to cubic MgO as indicated from the weight loss value (37.83%). Figure 1. DTA-TG analysis for (a) M100 and (b) M90 membranes in air with a heating rate of 3 o C/min. The theoretical weight loss for Mg(OH)2 transformation to MgO is (30.8%) (Niu et al., 2006). The exothermic peaks at 400 o C in the DTA curve demonstrated the occurrence of the reaction (Li et al., 2008). On the other hand, the TG curve for M90 shows four distinct weight loss regions at temperatures (20-400 o C): two weight losses ~ 13.8 and SHIRAZ LABIB 62 20.4% from 20 to 250 o C corresponding to the combined evaporation of bonded water, residual organic solvents and the nitrate groups from both magnesium nitrate and zinc nitrate. This explained the increase in weight loss percent with respect to the pure material. The two weight losses ~ 16.5 and 8.7% at 250-400 o C correspond to the transformation to MgO and ZnO respectively taking in mind the stoichiometric ratio of the metal precursor used. An important feature which was observed was the shift of weight loss to higher temperature with respect to the case of pure material. This result indicated the role of dopant (ZnO) in increasing the thermal stability of the MgO phase (Han et al., 2007). Also, the presence of two weight losses at 250-400 o C confirmed the presence of two phases: cubic MgO and hexagonal ZnO wurtzite structures. 3.1.2 Specific surface area measurements (SSA) Table 2 shows the specific surface area values of the unsupported membranes thermally treated at 600 o C for 6h. A marked increase in specific surface area values was observed with increasing ZnO doping percent. This increase was accompanied by a decrease in particle size as shown in Table 2. The decrease in particle size means a decrease in the crystalline behavior of the cubic MgO by incorporating ZnO. This result was explained as follows: since the ionic radius of Zn 2+ (0.083) nm is similar to that of Mg 2+ (0.078) nm, the position of Mg 2+ can be occupied by Zn 2+ (Huang et al., 2008; Saraiva et al., 2010). MgO structure is similar to the well-known NaCl structure. The O 2- anions are in a cubic closest packing and the Mg 2+ cations fill all the octahedral sites (Saraiva et al., 2010). The increase in doping percent of ZnO indicated that the octahedral positions occupied by Mg 2+ ions were replaced by Zn 2+ ions and when the doping percent reached 50% the structure became unstable and a disappearance of MgO structure was observed (Saraiva et al., 2010). In general, the MgO structure was determined under thermodynamic conditions, the increase of doping percent can decrease the mobility of adatoms (ZnO atoms) within the structure. So, the structure became kinetically not thermodynamically determined (Saraiva et al., 2010). This result was confirmed by the increase in the MgO peak broadness given in XRD results. Table 2. Specific surface area and particle size values of the unsupported membranes thermally treated at 600 o C for 6h. Sample Specific Surface Area (SSA) (m 2 /g) Particle Size dBET (nm) M100 M99 M95 M90 26.56 74.37 106.70 121.54 63.0 22.4 15.0 13.0 3.1.3 X-Ray diffraction analysis (XRD) Figure 2 shows the XRD patterns of doped and non-doped MgO powder thermally treated at 600 o C for 6 h. The characteristic peak of pure MgO (200) was presented at 2 ~ 43 degrees as indicated from (JCPDS-card N0 45-0946). The development of ZnO peak (103) at 2 ~ 62 degree (JCPDS-card N0 36-1451) was observed with increasing ZnO doping percent. A marked increase in the peak broadness of MgO, as marked by the arrow, was observed which confirms the decrease in the particle size and the crystallinity of MgO with adding ZnO, as given previously. Two important features were observed: i- The increase of MgO peak broadness and its shift to a higher angle with increasing ZnO doping percent. This shift was due to the variation of the lattice parameters confirming that ZnO was alloyed with MgO forming a Mg(Zn)O solid solution. This trend was known as Vergard's law which states that the lattice parameters depend on the composition (Saraiva et al. 2010). From this behavior, it was concluded that Mg(M)O systems can be treated as solid solutions (Saraiva et al., 2010). This means that the replacement of Mg by a cation with smaller radius was accompanied by a decrease in the lattice parameter and the opposite was noticed with a replacement by a larger cation (Saraiva et al., 2010). ii- The development and the intensity increase of ZnO peak (103) with increasing the doping percent indicated the presence of ZnO as a secondary phase. This result was also confirmed from TG results. So, not all ZnO was alloyed with MgO. SYNTHESIS OF DOPED AND NON-DOPED NANO MgO CERAMIC MEMBRANES 62 Figure 2. XRD patterns of doped and non-doped MgO membranes thermally treated at 600 o C for 6h. (a) M100, (b) M99, (c) M95 and (d) M90. 3.2 Supported membranes 3.2.1 Scanning electron microscopy (SEM) Figures 3 (a-d) show the SEM, at a magnification power of 8000 x, of doped and non-doped MgO thermally treated at 600 o C for 6h. A dense film of nanoparticles (200 nm) was shown in M100. The aggregated nanoparticles were in fact formed from tiny nanocrystallites within the size range of a few nm. The increase in the doping percent of MgO film with ZnO shows the development of a porous structure with slight variation in the average particle size. This decrease in structure density with increasing the doping percent can be attributed to the low mobility of the adatoms on the surface of the MgO films (Park et al., 2005). The decrease in adatom mobility on the MgO surface leads to the decrease in MgO (200) orientation, i.e. the decrease of the degree of crystallinity (Park et al., 2005). This result confirmed the result obtained in the SSA and XRD results. The adatoms acted as a grain growth inhibitor and influenced the grain growth kinetics either by pinning grain boundary or by changing the thermodynamic factors such as surface and grain boundary energies respectively (Suzuki et al., 2002). The energy necessary for the movement of MgO grain boundary increased and the driving force for the grain boundary migration decreased (He et al., 2002) leading to an inhibition of the grain growth. Similar behavior was reported in MgO-doped Al2O3 (Suzuki et al., 2002). The reduction in the spread of dihedral angles leading to a homogeneous microstructure was observed because of the presence of dopants (Suzuki et al., 2002). 3.2.2 Coating thickness Coating thickness measurements were done to give a detailed explanation of the kinetic role of ZnO incorporation into the MgO system, the mechanism of the film formation and the limit mobility of ZnO into MgO crystal lattice. Coating thickness measurements were calculated for the prepared membranes thermally treated at 200, 400 and 600 o C using cross SEM investigations. Figure 4 shows the plot of coating thickness values for the different prepared membranes versus thermal temperatures. The decrease of coating thickness layer with increasing temperature was due to the release of organic by-products and the crystalline formation of the final product, leading to a uniform coated film over the substrate. SHIRAZ LABIB 03 Figure 3. SEM of doped and non-doped MgO membranes thermally treated at 600 o C for 6h. (a) M100, (b) M99, (c) M95 and (d) M90. The marked decrease of coating thickness values of the prepared thin films were observed with increasing ZnO doping percent. This behavior was interpreted as follows: The thickness per deposited layer was dependent on several parameters: the concentration of the precursors, the sol viscosity and the density of the deposited film (Liebrecht, 2006). In a (MgO-ZnO) system, the mobility of the adatoms is more dependent on the film thickness than the other parameters (Guillén and Herrero, 2010). A direct correlation coexists between the mobility increase and both the coating layer thickness and grain size increase (Guillén and Herrero, 2010). On the other hand, the decrease in mobility occurs as a result of the strong interfacial interaction between the deposited film and the substrate leading to the decrease in coating thickness value (Park et al., 2005). It is certain that the adatomic mobility was an important factor affecting the coating thickness as well as the microstructure of the deposited films. Figure 4. Coating thickness values for doped and non-doped MgO membranes at different thermal temperatures. 4. Conclusion Doped and undoped MgO membranes were prepared using a chelating sol-gel process. ZnO was chosen as a dopant to MgO in different proportions. The addition of ZnO to MgO increased the thermal stability of MgO, as SYNTHESIS OF DOPED AND NON-DOPED NANO MgO CERAMIC MEMBRANES 03 investigated from DTA-TG results. The marked increase in specific surface area and decrease in particle size values, with increasing doping percent, was due to the decrease of the adatom mobility within the structure when increasing the percent of Zn 2+ replacing Mg 2+ ions. The increase of MgO peak broadness with increasing doping percent confirms the BET results. The decrease of adatom mobility affected the microstructure of the obtained films by increasing the porous structure of the obtained films, as shown in SEM investigations, and decreasing the coating thickness values. This was attributed to the strong interfacial interaction created between the deposited film and the substrate as a result of the decrease in adatom mobility. Therefore, the mechanism of increasing the percent of Zn 2+ replacing Mg 2+ ions played an important role in obtaining nano-coated thin film membranes. The aim of this paper was to understand the true role of doping ZnO into MgO matrix because this system is very important and opens the key of knowing the link between the mechanism of doping and the resultant properties. As concluded, the above results are compatible together leading to an improvement in MgO thin film microstructure with increasing ZnO doping percent and the field allows for other systems that have similar trends to be studied and applied. 5. References ANAS, SH., MUKUNDAN, P., SANOJ, A.M., MANGALARAJA, V.R. and ANANTHAKUMAR, S. 2010. Synthesis of ZnO Based nanopowders via a Non-hydrolytic Sol-gel Technique and their Densification Behaviour and Varistor Properties. Process. and Appl. Ceram. 4: 7-14. CARUNTU, D. 2006. Nanocrystalline Transition metal Ferrites: Synthesis, Characterization and Functionalization. Ph.D. Thesis, University of New Orleans, Louisiana, USA. CERNEA, M. 2005. Sol-gel Synthesis and Characterization of BaTiO3 Powders. J. Optoelectronics and Advanced Materials 7: 3015-3022. CRISAN, M., JITIANU, A., CRISAN, D., BALASOIU, M., DRAGAN, N. and ZAHARESCU M. 2000. Sol-Gel Monocomponent Nano-sized Oxide Powders. J. Optoelectronics and Advanced Materials 2: 339-342. DESAI, R., MEHTA, R.V., UPADHYAY, R.V., GUPTA, A., PRANEET, A. and RAO, K.V. 2007. Bulk Magnetic Properties of Cadmium Ferrite in Nano Regim. Bull. Mat. Sci. 30: 197-203. GUILLÉN, C. and HERRERO, J. 2010. Optical, Electrical and Structural Characteristics of Al:ZnO Thin Films with Various Thicknesses Deposited by DC Sputtering at Room Temperature and Annealed in Air or Vacuum. Vacuum 84: 924-929. HAN, Z-D., DIAO, CH., DONG, L. and ZHANG, X. 2007. Thermal Stability and Combustion Behaviors of LLDP/silica Nanocomposites. 16 th International Conference on Composite Materials, 8-13 July 2007, Kyoto, Japan. HE, CH., YU, Y., HU, X. and LARBOT, A. 2002. Influence of Silver Doping on the Photocatalytic Activity of Titania Films. App. Surface Sci. 200: 239-247. HUANG, CH-L., HOU, J. L., PAN, CH-L., HUANG, CH-Y., PENG, CH-W., WEI, CH-H. and HUANG, Y-H. 2008. Effect of ZnO Additive on Sintering Behavior and Microwave Dielectric Properties of 0.95MgTiO3-0.05CaTiO3 Ceramics. J. Alloys and Compounds 450: 359-363. IYER, R., DESAI, R. and UPADHYAY, R.V. 2009. Low Temperature Synthesis of Nanosized Mn1-xCdxFe2O4. Indian J. Pure and Applied Physics 47: 180-185. LABIB, SH. 2006. Preparation, Characterization and Formulation of Nano-ceramic Materials to be used for the Separation of some Heavy Metals. Ph.D. Thesis, Ain Shams Uni., Egypt. LI, M., XU, M., LIANG, H., LI, X. and XU, T. 2008. Preparation and Dielectric Properties of Mn-doped Ba0.6Sr0.4TiO3-MgTiO3 Composite Ceramics. Acta Physico-Chimica Sinica 24: 1405-1410. LIEBRECHT, L.J.H. 2006. Sol-Gel Derived Barium Titanate thin Films. M.Sc. Thesis, Uni. of Twente, The Netherlands. MAENSIRI, S., MASINGBOON, CH., BOONCHOM, B. and SERAPHIN, S. 2007. A Simple Route to Synthesize Nickel Ferrite (NiFe2O4) Nanoparticles using egg white. Scripta Materialia 56: 797-800. MIKHAIL, R.SH., ROBENS, E. 1975. Microstructure and Thermal Analysis of Solid Surfaces. John Wiley & Sons. Chichester, New York, Brisbane, Toronto, Singapore. NIU, H-X., YANG, Q., YU, F., TANG, K-B. and ZHOU, W. 2006. Simple Synthesis of Single-Crystalline Nanoplates of Magnesium Oxide. Chin. J. Chem. Phys. 19: 438-442. PARK, S.Y., LEE, M.J., KIM, H.J., MOON, S.H., KIM, S.G. and KIM, J.K. 2005. Relationship between the Microstructure and the Discharge Characteristics of MgO Protecting Layer in Alternating Current Plasma Display Panels. J. Vac. Sci. Technol. A. 23: 1162-1166. PETERS, T.A., FONTALVO, J., VORSTMAN, M.A.G., BENES, N.E., VAN DAM, R.A., VROON, Z.A.E.P., VAN SOEST-VERCAMMEN, E.L.J. and KEURENTJES, J.T.F. 2005. Hollow Fibre Microporous Silica Membranes for Gas Separation and Pervaporation. Synthesis, Performance and Stability. J. Memb. Sci. 248: 73-80. RAJ, A.M.E., NEHRU, L.C., JAYACHANDRAN, M. and SANJEEVIRAJA, C. 2007. Spray Pyrolysis Deposition and Characterization of Highly (100) Oriented Magnesium Oxide thin Films. Cryst. Res. Technol. 42: 867-875. SAMERJAI, TH., LIEWHIRAN, CH. and PHANICHPHANT, S. 2009. Characterization of ZnO/MgO Nanocomposites Synthesized by Flame Spray Pyrolysis. J. Microscopy Soc. Thailand 23: 87-90. SHIRAZ LABIB 06 SANCHEZ, C., LIVAGE, J., HENRY, M. and BABONNEAU, F. 1988. Chemical Modification of Alkoxide Precursors. J. Non-Crystalline Solids 100: 65-76. SARAIVA, M., GEORGIEVA, V., MAHIEU, S., AEKEN, K.V., BOGAERTS, A. and DEPLA, D. 2010. Compositional Effects on the Growth of Mg(M)O films. J. Appl. Phys. 107: 1-10 SEKULIC, J., LUITEN, M.W.J., ELSHOF, J.E.T., BENES, N.E. and KEIZER, K. 2006. Microporous silica and Doped Silica Membrane for Alcohol Dehydration by Pervaporation. Desalination 148: 19-23. SUZUKI, T., KOSACKI, I. and ANDERSON, H.U. 2002. Microstructure-electrical conductivity relationships in Nanocrystalline Ceria thin Films. Solid State Ionics 151: 111-121. WILLARD, M.A., KURIHARA, L.K., CARPENTER, E.E., CALVIN, S. and HARRIS, V.G. 2004. Chemically Prepared Magnetic Nanoparticles. Int. Mat. Rev. 49: 125-170. YANG, Y., JIN, Y., HE, H., WANG, Q., TU, Y., LU, H. and YE, Z. 2010. Dopant-induced Shape Evolution of Colloidal Nanocrystals: the Case of Zinc Oxide. J. Am. Chem. Soc. 132: 13381-13394. Received 7 August 2012 Accepted 3 September 2012