Effect of Particle Size and Sintering Temperature on the Formation of Mullite from Kyanite and Aluminum Mixtures

The eﬀect of particle size and sintering temperature of the mixtures of kyanite and metallic aluminum related to the thermal transformation of kyanite into primary mullite and free silica was studied. In addition, the reaction between α -Al 2 O 3 (in situ produced by aluminum oxidation) and the silica was obtained in cristobalite structure from kyanite to obtain secondary mullite. The kyanite powders were milled by 0.5, 3, 6, and 12 hours and then were mixed with aluminum powder, which were previously milled by 3 hours. After that, the powders were characterized by X-ray diﬀraction technique (XRD), scanning electronic microscopy (SEM), diﬀerential thermal analysis (DTA), and thermogravimetric analysis (TGA), and the particle size was determined in a centrifugal analyzer particle size Shimadzu model SA-CP4. The mixed powders were pressed uniaxially into cylindrical samples (compacts), and then sintering was conducted at 1100, 1200, 1300, 1400, 1500, and 1600 ° C; these samples were characterized by XRD, SEM, and thermodilatometry analysis (TD); density and open porosity measurements were performed by the Archimedes method. The samples were thermally etched to observe the microstructure, which consisted of mullite equiaxial grains contained in a glassy phase. It was observed that the nonmilled kyanite mineral becomes into mullite plus silica at temperatures between 1400 and 1500 ° C. When the particle size was reduced at sizes less than 1 µ m, the transformation temperature was low until 200 ° C; the X-ray patterns of the sintered samples at 1400 ° C, ground for 6 hours, showed mullite peaks with small reﬂections of cristobalite and α -Al 2 O 3 , and these samples exhibited high density and low open porosity.


Introduction
Mullite (3Al 2 O 3 ·2SiO 2 ) is the only stable silicoaluminate in the binary system of SiO 2 -Al 2 O 3 at atmospheric pressure [1,2] and is a very important refractory material with high melting temperature, high hot strength, excellent thermal shock resistant, and high creep resistance; it is volume stable at very high temperatures, it has a low coefficient of thermal expansion, and it has excellent electrical insulation properties [3,4]. It has outstanding hot load-bearing properties, and it is resistant to many corrosive environments. Mullite is very low in magnetic iron, which is beneficial in many applications [5]. e finely dispersed, amorphous silica is very reactive and combines easily with sources of alumina to form mullite that is beneficial. Mullite rarely occurs as a mineral in nature. In fact, the word mullite is derived from the Isle of Mull off the west coast of Scotland, where the only naturally occurring deposits of mullite have ever been found [6][7][8]. Kyanite is an anhydrous aluminosilicate, with crystalline structure triclinic, it belongs to the Al 2 O 3 -SiO 2 system, and its chemical formula is Al 2 O 3 ·SiO 2 ; its decomposing at high temperatures produces mullite (3Al 2 O 3 ·2SiO 2 ) and free silica (SiO 2 ). e mullitization process accompanies 16-18 vol % expansion, making it be widely used as expanding agent in the refractory field [9]. Decomposition occurs according to the following reaction: 3 Al 2 O 3 · SiO 2 ⟶ Δ 3Al 2 O 3 · 2SiO 2 + SiO 2 kyanite primary mullite + cristobalite Sainz et al. [10] showed that the formation of mullite from kyanite is carried out by means of thermal transformation; the kyanite decomposes into mullite plus silica due to the induced heat. During the decomposition, they found different stages of transformation and formation of a liquid. e first stage was at 1320°C, which corresponds to the beginning of the transformation of the kyanite; the second stage was located between 1320 and 1420°C, associating with the progress of the reaction allowing a complete transformation to 1420°C. Raghdi et al. [11] synthesized mullitezirconia composites prepared from halloysite reaction with boehmite and zirconia. ey reported the phase transformations that ended at 1550°C with the formation of monolithic mullite in halloysite-boehmite mixture and mullite-zirconia composites in halloysite-boehmite-zirconia mixture. Goski and Caley [12] investigated the reaction sintering of kyanite and alumina to form mullite composites, and the resulting 78%-22% mullite material formed a finegrained structure (1 μm) with 14% decrease in shrinkage and 11% reduction in linear expansion coefficient. Chargui et al. [13] prepared mullite from natural kaolin and aluminum slag; they studied the structural transformations of kaolinaluminum slag mixtures during heating. e amount of formed mullite increases with the firing temperature; at 1500°C, the mullitization of the mixture is almost complete. e morphology of the formed mullite is bimodal (primary and secondary phases). e primary mullite, formed from processing of kaolin by the gradual collapse of metakaolin from 990°C, has a shape of elongated crystals. On the other hand, the secondary mullite formed by solution-precipitation from the glass phase in the presence of alumina particles has a shape of acicular grains. Guo and Li [14] fabricated mullite ceramics with different crystal shapes of mullite by in situ reaction with middle-grade kyanite as raw material, Al(OH) 3 , c-Al 2 O 3 , ρ-Al 2 O 3 , and α-Al 2 O 3 as alumina sources. Results showed that mullite in the sample with Al(OH) 3 mainly showed acicular morphology, with a successive slowdown in reactivities of Al(OH) 3 , c-Al 2 O 3 , ρ-Al 2 O 3 , and α-Al 2 O 3 , the amount and aspect ratio of mullite were reduced, and its growth mechanism gradually transforms into two-dimensional nucleation. Acicular mullite not only reinforced samples but also made effective pore sizes smaller, which allowed the sample with Al(OH) 3 to present low bulk density, high apparent porosity and linear changes, small average pore size, and good mechanical strength. Sánchez-Soto et al. [15] utilized kaolin waste, sericite clay containing kaolinite, and industrial kaolin with addition of alumina in a wet medium to synthesize mullite (72 wt% Al 2 O 3 and 28 wt% SiO 2 ). ey found by sintering at 1500-1600°C for, at least, 30 min, and the reaction sintering between α-alumina and silica originated from thermal decomposed kaolinite in the samples produced mullite. According to XRD results, it evidenced the disappearance of residual crystalline phases, mainly quartz and cristobalite, with relicts of α-alumina in a single case. e thermal phase evolution was affected by the presence of impurities in the mixtures. ese impurities produce, in fact, the formation of a glassy phase or partial vitrification in some areas as deduced by SEM-EDS, giving rise to a better sintering which allow the sample to reach a 74% of total densification. A variety of preparation methods are used to synthetize mullite from various materials, such as alumina-silica minerals, hydroxides, sols, silicon alkoxide, and aluminum alkoxide [16,17]. In the present work, the reaction sintering of kyanite + aluminum mixtures has been used in the synthesis of the mullite samples studied. e processing route employed can be explained according to the following reactions [9]: Reaction sintering is an adaptation of the reaction bonding aluminum oxide developed by Claussen et al. [18] who found that the reaction bonded is an oxidation-based process, which begins with a compact of aluminum and alumina. During heating in air, the Al particles are oxidized in the solid state having a volume expansion ≈28%, which can compensate for the shrinkage by sintering. e oxidation of the aluminum particles represents the key to this new technology for obtaining Al 2 O 3 -based composites. e characteristics of these composites are as follows: low sintering shrinkage and high resistance. e low shrinkage results from a partial compensation for sintering shrinkage by an expansion associated with oxidation.
e high resistance is due to the fine grain size (<1 μm) which develops during the reaction bonding process. Reaction sintering has been shown to favour the absence of sintering aids which can 2 Advances in Materials Science and Engineering allow for improved strength and final density at lower firing temperatures. e principle advantage of reaction sintering is foreseen as the in situ development of multiphase composites with a fine, uniform microstructure achieved using economical reactants [19,20].

Materials and Methods
For this work, the starting materials were kyanite ore (Al 2 O 3 ·SiO 2 ) from the Kyanite Mining Corporation located in Dillwyn, Virginia, USA, with an average particle size of 35 mesh (417 µm), and aluminum powder, Alcoa Atomized Aluminum Powder, 20 µm. e phase identification was performed by X-ray diffractometry (XRD, Model Equinox 2000, Inel, Artenay, France) with Cu Kα1 (1.5406Å) radiation, operating at 30 mA and 20 kV. e morphology and microstructure were observed in a scanning electron microscopy (SEM, Model 6300, JEOL, Tokyo, Japan) with an accelerating voltage of 15 kV. e particle size was determined in a centrifugal analyzer particle size Shimadzu model SA-CP4; the specific surface area was performed by the nitrogen adsorption method (BET). e milling of the kyanite and metallic aluminum was carried out separately in a vertical mill attritor Szegvari (Union Process, USA), with a cylindrical stainless steel container capacity of 3.785 L in air, the grinding media were steels balls of 5 mm diameter, and milling time was 0.5, 3, 6, and 12 hours at 400 rpm. e aluminum was milled for 3 hours in wet with 100 ml of isopropanol as a control agent; then, kyanite ground at different times was mixed for 0.5 h, in order to homogenize the mixture. For the preparation of mixtures of aluminum kyanite, 15.73% Al and 84.27% kyanite were weighed to form a mullite 3 : 2 (3Al 2 O 3 ·2SiO 2 ) according to equation (2). e powder mixture was die-pressed uniaxially in a hydraulic press Stroud Daniels at 180 MPa into disks of 10 mm × 6 mm, and it was fired in a muffle furnace ermolyne brand, model 46200, with 8 heating elements of SuperKanthal 33 in air at a heating rate of 1°C/min up to 950°C, followed by 10°C/min heating to different temperatures (1100, 1200, 1300, 1400, 1500, and 1600°C). e thermal decomposition, weight, and dimensional changes were studied by TG/DTA (Setaram Model Setsys Evolution, Caluire, France) under an air atmosphere at a constant heating rate of 10°C/min. Bulk density of fired samples was determined by measuring of its mass and volume (the Archimedes method using distilled water), and porosity values were calculated from its bulk density and the theoretical density of mullite, using the following equation [21]: where ρ b (g/cm 3 ) is the bulk density of a sample and ρ t (3.16 g/cm 3 ) is the theoretical density of mullite. e chemical composition of raw materials was determined by atomic absorption spectroscopy (AAS, Model 2380, Perkin Elmer, Waltham, Massachusetts). For practical purposes, the letter K is used to identify the unmixed kyanite and KA for the kyanite-aluminum mixtures followed by the milling time. Figure 1 shows the diffractogram of the original kyanite, which is dominated by a very large peak at 26.6°2 theta, the (200) planes, while the relative intensities of the remaining reflections are smaller as reported in the JCPDS card no. 11-0046. In addition, small reflections of quartz and muscovite were identified. e chemical composition of raw materials is shown in Table 1, mullite (3 : 2) has a theoretical Al 2 O 3 /SiO 2 ratio of 2.54, this value is below for all mixtures, and this difference is possibly due to aluminum losses during grinding. Due to the wear of the grinding media (steel ball), there was contamination of Fe 2 O 3 (until 4.8% weight for KA12) in the kyanitealuminum powders, so the mixtures were leached with a concentrated solution of hot HCl. As we can see, this method was effective and reduced the amount of Fe 2 O 3 to values of 0.185 for the same sample. Figure 2 shows the micrographs of raw materials; the morphology and the size of the precursor powders were determined by scanning electron microscopy, the kyanite powders 2(a) are prismatic, elongated, tabular crystals with a size up to 400 μm long, and the aluminum powders have a cylindrical shape with a size ≈ 20 μm. e micrographs of mixed powders of kyanite-aluminum are observed in Figure 3; the unmilled mixture 3(a) is formed by elongated crystals of kyanite of approximately 300 μm in length covered by aluminum particles; after 0.5 h of grinding 3(b), the original morphology of the kyanite is no longer visible, and the particles showed average sizes of 6 μm. e powders milled for 3 h 3(c) consisted of elongated particles of up to 3 μm and others of smaller size, and the powders obtained during the grinding of 6 h 3(d) showed particles smaller than 1 μm and agglomerates of finer particles. Finally, in the mixture of powders milled for 12 h 3(e), quasispherical particles with sizes smaller than 1 μm were observed; it should be noted that aluminum was observed as irregular shaped particles with average sizes of 3 to 1 μm, and this morphology is due to the ductile nature of aluminum as it tends to be rolled at the time of grinding. e particle size distribution of the milled kyanite at different times is observed in Figure 4; the powders of the K0.5 sample exhibited a bimodal size distribution, with 60% of the particles in an interval of coarse size of 4 to 40 μm, and 40% of the particles in a fine range of 0.3 to 1.5 μm. e samples K3, K6, and K12 were obtained with average sizes (d 50 ) of 0.52, 0.38, and 0.16 μm, respectively. e specific surface area of the kyanite and the mixtures of kyanite-aluminum are observed in Table 2. For kyanite-aluminum mixtures, it can be noted that the increase in grinding time generated an increase in the specific surface area from 8.4 m 2 ·g −1 at 0.5 h of milling time to 42.36 m 2 ·g −1 at 12 h of milling.

X-Ray Diffraction.
e X-ray diffraction patterns for the raw kyanite and kyanite-aluminum mixtures are shown in Advances in Materials Science and Engineering Figure 5; it can be observed that no reaction occurred during the milling 5(a) as peak patterns of milled samples are basically overlapping peaks in the XRD patterns of the unmilled samples.
Although peaks in the diffractograms of the samples milled 5(b) are smaller and wider because of the decrease in crystallite size and possible microstrain contained in the powder particles, in addition, aluminum peaks in 38.5°and   44.74°2 theta were observed [15]. e transformation of kyanite into mullite is closely related to the size of kyanite powders and sintering temperature [22]. Figure 6 shows the XRD patterns of the phase evolution of the mixture of kyanite and aluminum powders milled at different times and sintered in a range of 1100-1600°C. In Figure 6(a), we can see the samples unmilled (KA0 h) and sintered at 1100°C; in this sample, the major phase is kyanite (k) and α-Al 2 O 3 is obtained by the aluminum oxidation [23]. In the range of 1200-1500°C, it is observed that the reflection intensity of kyanite decreased, while the expelled silica (cristobalite-CR) and formed primary mullite were increased due to the sintering temperature. Finally, mullite without any traces of crystalline silica was formed after sintering at 1600°C. Cristobalite is a silica polymorph in ceramic materials, as it can crystallize in SiO 2 -rich systems during high-temperature processes.
e formation of cristobalite was increased at temperature ≥1200°C; at this temperature, the peak of 10 μm (a) 1 μm    the formation of kyanite (Al 2 SiO 5 ) at 1300°C, and the mechanical treatment enhances the formation and sintering of mullite. After 0.5 h of milling, Figure 6(b) shows the XRD patterns of the mixture sintering at various temperatures; at 1100-1200°C, the primary mullite phase started to form from the decomposition of kyanite. e majority phase is still kyanite with minor amounts of α-Al 2 O 3 . In the range of 1300-1400°C, the cristobalite phase started and the peaks of kyanite were not observed and noticeably increased the reflections of mullite. e behavior at 1500 and 1600°C is similar, so the mullitization reaction finished (from 1500°C) and could be observed only the characteristic peaks of mullite. Sule et al. [25] investigated the effect of temperature on mullite synthesis from attrition-milled pyrophyllite and α-alumina by spark plasma sintering at temperatures ranging from 1400°C to 1700°C, with this increase in sintering temperature, and the results showed a phase of mullite and a minority phase of alumina. ey also determined that the intensities of alumina peaks gradually decreased with increasing sintering temperature. Figure 6(c) shows the XDR spectra of the powders milled for 3 h; in the sample heated at 1000°C, it could be determined that the major phase was kyanite and minor ones were mullite and α-Al 2 O 3 . In the range of 1200-1300°C, the intensities of the kyanite reflections were decreased markedly and the mullite peaks increased. At 1400-1500°C, cristobalite started to derive from the decomposition of kyanite; at 1600°C, the mullitization reaction ends, and secondary mullite was formed through the interaction of α-Al 2 O 3 and SiO 2 (cristobalite). Figures 6(d) and 6(e) show the XRD patterns of the samples milled at 6 h and 12 h, respectively; the behavior is very similar, the decomposition started at 1200°C decreasing the kyanite peaks completely to temperature >1300°C, the cristobalite peak disappeared to 1600°C, and only the characteristic reflections of mullite were observed. e above behavior suggests that the reaction of decomposition accelerated with increasing temperature and decreasing particle size [24,26]. Similar conclusion was drawn by Khattab et al. [27], where XRD patterns showed that by increasing the sintering temperature up to 1350°C, the peak intensity of cristobalite and quartz has been decreased with remarkable increase in the peak intensity of mullite and cordierite. Such decrease in peak intensity of cristobalite and quartz may be attributed to their reaction with MgO and Al 2 O 3 forming cordierite and mullite. Figures 7(a) and 7(b), respectively; in Figure 7(a), the initial mass reduction of 2.9% observed was associated with the evaporation of organic species that were absorbed during milling. Aluminum oxidation occurs in two well-defined stages; the first stage was observed in the range of 380-658°C (the solid-state oxidation of aluminum powder) with a weight gain of 7.2%. Later, an increment was identified in a weight of 2.7% in the second stage (658-840°C) due to oxidation of aluminum in the liquid state. At 1420°C, the mullitization reaction was complete, this temperature agrees with the XRD results (Figure 6(a)), and when above 1400°C, the presence of kyanite is no longer observed. e behavior of the KA12 sample (Figure 7(b)) was similar; firstly, initial weight loss of 7.5% was greater than the sample KA0 h, since when milled for 12 hours, it absorbed more amount of organic species, since isopropyl alcohol was used as a control agent. e oxidation of aluminum in the solid state (first stage) was observed in the range of 450-658°C, with a weight gain of 3.2%; finally, a rate of oxidation reaction is reduced from 658 until 850°C. e decomposition temperature of kyanite is reduced by approximately 100°C with respect to the unground sample, since in this case, this happened at approximately 1315°C. is decrease is due to presumably because the very fine particle sizes experience a change in the kinetics of the decomposition reactions. Attrition-milling also produces much more reactive rejected silica that readily combines with aluminum oxide obtained in situ from aluminum metal additions to produce a phase-pure mullite [24]. Figures 8(a) and 8(b), respectively. In Figure 8(a), it can be seen that in the range of 330-830°C, an expansion of approximately 2.3% corresponds to the oxidation of aluminum. A slight expansion can be noticed at 660°C due to the melting of the aluminum. e reaction of kyanite decomposition occurs between 1325 and 1460°C with an expansion of 8.9%, followed by 5.6% shrinkage caused by sintering the sample. Figure 8(b) shows the dilatometry curve of the mixture KA12 h; the curve shows in 370-840°C a slight expansion caused by the oxidation of the aluminum. e next observed change was a contraction (approximately 6%) starting at approximately 1030°C, which was followed by the kyanite transformation between 1265 and 1310°C, with a slight expansion of 0.5%. en, a strong sintering shrinkage of 15.5% begins, and this section of the curve shows a deflection around 1485°C, which could indicate that the sample entered the final stage of sintering.

ermodilatometry (TD). e dilatometric behavior curves of the samples KA0 h and KA12 h are presented in
In addition to this change, at 1410°C, the curve showed a change in slope that could be associated with the reaction between the silica released by kyanite and the alumina that was formed by the oxidation of aluminum, whose product would be secondary mullite. Decomposition is accompanied by a characteristic volume expansion which can be as large as 16-18%, since kyanite is denser than mullite, 3.5-3.7 g/cm 3 and 3.16 g/cm 3 , respectively. e attrition-milling accelerates the decomposition of kyanite, reduces the decomposition expansion, and increases the shrinkage [28].

Differential ermal Analysis (DTA).
e thermal inspection of mixtures by differential thermal analysis (DTA) was carried out in inert atmosphere in the range of room temperature to 1600°C at a heating rate of 1°C/min until 950°C, above 950°C, and the heating rate was increased to 10°C/min to avoid much further oxidation [29]. In accordance with Yu [30], the mullite formation reaction is generally exothermic when oxide powders serve as the reactants; agreed with this, several exothermic peaks could be observed (Figure 9(a)). Peak at 325°C was associated with the evaporation of organic species that were absorbed during milling, an exothermic peak was observed that has a maximum at 571°C corresponding to the oxidation of aluminum in solid state, and at 659°C, a small endothermic peak due to the fusion of aluminum was identified. In the range of 720-740°C, a fairly wide and low-intensity endothermic peak was observed, which corresponds to the oxidation of aluminum in liquid state. At 965°C, a disturbance of the curve caused by the change in heating rate from 1°C/min to 10°C/min is shown, so it is not a thermal event associated with changes in the sample. At 1286°C, an endothermic event started, which finished at 1460°C, and the above one coincides reasonably well with the starting and ending temperatures of the decomposition of kyanite, which was observed in the dilatometry curve (Figure 8(a)). At 1508°C, a small exothermic peak that could correspond to the reaction between α-Al 2 O 3 , which comes from the oxidation of aluminum, and the silica expelled by the decomposition of kyanite to form secondary mullite. In Figure 9(b) (sample KA12 h), basically the same endothermic peaks ≤965°C corresponding to sample KA0 h are shown. e main difference corresponds to the temperatures of initiation and termination of the decomposition of kyanite, and the transformation temperature of the secondary mullite and these thermal events correspond to the endothermic peaks located at 1215, 1330, and 1400°C, respectively. In   Figure 10(a), it is observed that at temperatures of 1100 and 1200°C, there is a very small variation, and these values decreased when reaching the temperature of 1300°C, due to the expansion produced during the decomposition reaction of kyanite. From 1400°C, the increase in density is restarted for all samples except for the unground sample (KA0 h), which does not densify due to the particle size (400 μm) and the strong expansion (≈18%) due to decomposition of kyanite causing cracking [9]. Upon reaching 1500°C, the density continued to increase, and at 1600°C, the maximum density was reached for the sample ground for 12 h (KA12 h) of 3.04 Kg·m −3 , approximately 96.2% of the density theoretical of mullite (3.16 Kg·m −3 ). It has been shown that the decomposition of kyanite starts at surface sites. From this perspective, the decrease in particle size activates the thermal decomposition of the surface that already has an increase in surface area and the amount of microcracks. In this way, the concentration of nucleation sites increases where decomposition can start. Many of the main factors that have a marked influence on the sinterability of ceramic materials are related to the characteristics of the compacted powder: the heating conditions and the Al 2 O 3 /SiO 2 ratio of the precursor materials. e effect of the agglomeration of dust particles on the sintering of mullite has also been evaluated [4]. e density reached will depend on the size and packing of the agglomerates, and breaking them will produce additional surface areas and smaller particle sizes. e presence of higher contents of alumina and SiC with low melting silicate phases increase the bulk density and consequently decrease the apparent porosity of samples [31]. Regarding the results of open porosity ( Figure 10(b) Figure 11, and the sample prepared with the unmilled kyanite KA0 h (Figure 11(a)) showed a great cracking, which is attributed to the great expansion of the decomposition [9]. In Figures 11(b)-11(e), the microstructures for the samples KA0.5 h, KA3 h, KA6 h, and KA12 h, respectively, are shown. In these figures, elongated mullite grains were found, surrounded by a dark phase [32]. It is well known that mullite grains with these characteristics grow when they are immersed in a vitreous phase. In this microstructure, it is clearly observed that milling improves the reactivity of kyanite with alumina. During heating, aluminum oxidizes and deposits on the surface of the kyanite particles, and when this species decomposes, primary mullite is formed and silica precipitates, as shown by the XRD patterns of these samples; the silica is expelled to the surface and comes into contact with the alumina grains reacting to form secondary mullite. In the samples prepared in this work, there was an alumina deficiency (see Table 1), possibly because during the milling, an amount of aluminum was lost that was    adhered to the walls of the mill and to the grinding elements. Because of this, the samples had an excess of liquid phase in which the mullite grains grow, as observed in the microstructures; the liquid phase can also form from the eutectic reactions between alumina and silica by impurities existed in kyanite. In unmilled mixtures, this vitreous phase is not expelled to the surface of the transformed grains, but it is trapped inside it. As Awaad et al. [33] pointed out, mullite formation is independent on the Al 2 O 3 /SiO 2 ratio, but greatly dependent on the type and amount of glassy phase present. erefore, the mullitization reaction is slower and cannot be completed. As the particle size decreases, denser and finer microstructures are obtained, with less open porosity and more homogeneous which is promoted by grinding.

Conclusions
(i) e present study shows that mullite can be obtained by reaction sintering of kyanite and aluminum metal powders. (ii) e decomposition reaction temperatures for kyanite and aluminum powders mixtures were lower relative to unground kyanite. erefore, we have that the transformation and growth of mullite is faster, deducing that this process depends on the particle size and the specific surface area. (iii) e reduction of the particle size by grinding influences the thermal decomposition of the kyanite, the expansion due to this transformation, and the secondary mullite formation reaction and increases the shrinkage. (iv) Milling significantly increases the reactivity of the kyanite. e milled kyanite decomposes faster and at lower temperatures than coarse kyanite. (v) e reaction between the silica expelled from the kyanite and alumina that forms in situ starts at∼1400°C. is reaction occurs faster for mixtures that contain finer kyanite. (vi) A milling time of 6 h is appropriate for obtaining micron size grains of mullite.

Data Availability
e data used to support the findings of the study are available from the corresponding author upon request.

Conflicts of Interest
e authors declare that there are no conflicts of interest regarding the publication of this paper.