Effects of Milling pH and Hydrothermal Treatment on Formation of Nanostructured Boehmite Binder for Alumina Extrusion

The in situ formation of nanostructured aluminum hydroxides on the surface of alumina particles, which can work as inorganic binder, was reported in this paper.The effect of the suspension pH duringmilling of alumina powder and subsequent hydrothermal treatment for the hydroxide formation and microstructure was depicted. Under acidic pH condition, the formation of hydroxides was not observed. When the pH of suspension changed from acidic to basic during milling, bayerite [Al(OH) 3 ] nanoparticles were formed, but only a fraction of this hydroxide was converted to boehmite (AlOOH) during subsequent hydrothermal treatment. The aluminum hydroxide and oxyhydroxide formed in this condition improved the smoothness of extruded rods and the strength of presintered segments. For the powder milled under basic pH condition, the mechanochemically formed bayerite was completely converted into boehmite nanoparticles during the hydrothermal treatment. The presence of boehmite nanoparticles contributed to improving plasticity during extrusion, which allowed the reduction of organic binder and increased the strength of presintered alumina rods.


Introduction
Nowadays, the development of green manufacturing processes with reduced environmental impacts, rational consumption of energy, minimum waste of material, and low emission of pollutants is a critical concern.Among the several actions that may contribute to achieving the abovementioned goals, the use of low-toxicity materials and recycling plays a major role [1].With regard to ceramic processing, environmental impacts may be reduced in many ways, such as the development of rapid sintering processes, new additives to decrease the temperature of powder synthesis, replacement of toxic organic solvents used in forming methods (such as tape casting and powder injection molding) by aqueous systems, development of manufacturing routes with fewer steps, and elimination or reduction of organic binders (e.g., PVA, PEG, PMMA, and PVB) [2][3][4].
Organic (polymeric) binders have been used to provide adequate rheological behavior to the ceramic powders during the forming step and mechanical strength to the formed green bodies.The amounts of these additives can reach 10 vol% or more, depending on the forming method and binding system employed [4].Organic binders are transient processing additives that decompose during the firing step, generating potentially harmful hydrocarbon gases (e.g., C 3 H 5 , C 4 H 5 O, and C 5 H 8 O 2 ) and CO 2 which, once released to the atmosphere, contribute to the greenhouse effect [5].Such environmental impact can be reduced by replacing the organics by inorganic binders, such as boehmite (aluminum oxyhydroxide, -AlOOH), which generates only water as gaseous byproduct [6,7].The addition of boehmite nanoparticles to ceramic powders can produce pastes with adequate extrusion behaviors (plasticity and liquid retention capacity) resulting in formed bodies with characteristics (green density and strength) similar to those obtained for pastes containing plastic clays [7,8].Boehmite has also been used as a processing additive in other forming methods, such as sol-gel, cold isostatic pressing, and slurry compaction [9][10][11].
The mechanical activation route, also known as mechanochemical synthesis, has received significant attention in recent years to prepare nanoparticles, modify the structure of the particle surface, and synthesize inorganic and organic compounds at room temperature [12][13][14][15][16].It is usually performed in ball mills, where the compressive and shearing forces exerted by the balls impacts during milling or grinding induce a variety of reactions in the material, such as the formation of crystal defects (e.g., Schottky and Frenkel defects in oxides), amorphization, and phase transformations [12,17].Mechanochemical synthesis has been used to obtain complex oxides, metastable phases, nanoparticles with core-shell configurations, and nanometric crystallites formed on the surface of the milled particles (nanocrystalline coatings), which are difficult to synthesize by conventional methods [14][15][16][17].Depending on the materials chemistry, desired microstructure, milling environment, and other processing parameters, different mechanisms might play a role in mechanical activation and these are not yet fully elucidated because direct monitoring of the transformations during milling is difficult.Particularly, there is little information published on the role of water in the mechanochemical treatments (wet ball milling) [12,13].
Milling alumina powders in aqueous media is a possible route to modify the surface of alumina particles by the in situ formation of aluminum trihydroxides surface layers (bayerite [-Al(OH) 3 ] and gibbsite [-Al(OH) 3 ], depending on the pH of suspension) [18,19].The aluminum hydroxides formed by mechanochemical modification of the surface of alumina particles can be converted to boehmite by a hydrothermal treatment, resulting in pastes with adequate plasticity for extrusion tests and extruded segments with high strength, allowing the reduction of organic binder content [20].In this work, the effect of pH on the formation of aluminum hydroxides on the surface of alumina particles during wet milling is investigated.Also, the efficiency of these hydroxides as inorganic binders for extrusion is evaluated.

Experimental
The starting powder used in the experiments was an unground low-soda calcined alumina (CL 2500, Almatis), indicated by the manufacturer for electronic components such as substrates.
Ceramic suspensions were prepared adding 100 g of deionized water to 100 g of alumina powder (20.1 vol% of solids).Each suspension was ball milled at 90 rpm during 10 h using an alumina jar.As grinding media, 2.6 kg of yttriastabilized tetragonal zirconia polycrystal (Y-TZP) balls of three diameters was used, in the following mass ratio: 24% of  5 mm; 49% of  15 mm; and 27% of  25 mm.
The pH of the suspensions before milling was measured with a pH-meter (B374, Micronal) and was 9.2.The first milling was conducted without any pH control and, after milling, the pH had increased to 10.3.This condition was named basic pH milling.The second milling was performed after the addition of 1.70 mL of HCl solution (50 wt%) to the suspension, without any additional control of pH, with initial value of 4.1.After this milling, the pH value increased to 8.4 and this condition was named acidic-basic milling.The third milling was identical to the second milling except for three stops to add HCl to maintain the pH low.A total of 5.0 mL of HCl solution was added so that the final pH of this suspension was 4.2.This condition was named acidic pH milling.
The milled powders were dried in air at 100 ∘ C.Then, 60 g of each powder was mixed with 30 g of distilled and deionized water in a porcelain crucible.Afterwards, the mixtures were hydrothermally treated at 150 ∘ C and 3 atm for 3 h using an autoclave (Fabbe Primar).
The starting powder, milled powders, and hydrothermally treated powders were analyzed using the following techniques: (i) Chemical analysis by X-ray fluorescence spectrometry (XRF 1800, Shimadzu).(ii) X-ray diffraction, XRD (X'Pert Pro, PANalytical); the measurements were performed using CuK radiation with counting time of 10 s at scanning step of 0.02 ∘ .(iii) Fourier transform infrared (FTIR) spectroscopy (Nicolet Magna 550, Thermo Fisher Scientific) in transmission mode with 49 scans/min and step of 2 cm −1 ; for this analysis, 0.002 g of powder was hand mixed with 0.2 g of KBr powder using an agate mortar and then pressed with 98 kN load to form a disc with 13 mm in diameter.(iv) Particle size analysis using a laser diffraction granulometer (LS 100Q, Coulter Beckman) with particles dispersed in water; before analysis, the suspensions were deagglomerated with an ultrasonic probe of 100 W. (v) Specific surface area analysis by BET (Brunauer-Emmett-Teller) method; the nitrogen gas sorption isotherms were measured using a surface area analyzer (Gemini VII 2390, Micromeritics); the powders were degassed under vacuum at 200 ∘ C for 24 h before the testing.(vi) Scanning electron microscopy, SEM (JSM T330-A, Jeol), transmission electron microscopy, TEM, and scanning transmission electron microscopy (STEM) using a field emission gun (FEG) microscope (Tecnai G 2 F20, FEI) operating at 200 kV.(vii) Differential scanning calorimetry and thermogravimetry, DSC/TGA, using a simultaneous thermal analyzer, STA (SETSYS Evolution, Setaram), with a heating rate of 5 ∘ C/min and synthetic air as atmosphere.
The performance of generated aluminum hydroxides as inorganic binder for alumina was evaluated by means of an extrusion test.Some pastes were prepared by adding carboxymethyl cellulose, CMC (Lamcol MMS, Lamberti), to the treated powders as supplementary binder.For each powder, pastes with 0, 1.0, 1.5, and 2.0 wt% of CMC were prepared.First, 10 g of milled and hydrothermally treated powders was hand mixed with a solution of CMC (10 wt%) in distilled water.The total water content was set at 18 wt% of the mass of alumina powder for all pastes (a preliminary study indicated that this content was adequate to prepare pastes with consistency close to that of the ball clay).The homogenized pastes were allowed to age for 48 h in a closed plastic bag.Afterwards, the plasticity of prepared pastes was evaluated using a stainless-steel pin-barrel extrusion device, with barrel and die diameters of 16 and 3 mm, respectively (reduction in area of 96%) [21].Force was applied to the piston at a crosshead speed of 5 mm/min in a universal testing machine (3336, Instron).
The extruded segments (3.1 mm in diameter and ∼20 mm in length) were presintered in an electric furnace (model 1612, Jung) at 1100 ∘ C for 1 h, after a debinding step at 500 ∘ C for 1 h, with heating and cooling rates of 5 and 10 ∘ C/min, respectively.The surface of the extruded sample was evaluated using an optical stereo microscope (SZ61, Olympus), and the strength of the segments was determined using a four-point fully articulated flexure device (with outer and inner spans of 12 and 6 mm, resp.) in the universal testing machine, at a crosshead speed of 0.5 mm/min.

Starting and Milled
Powders.Chemical analysis by XRF spectroscopy showed that the starting alumina powder (CL 2500, Almatis) had a purity of 99.7% Al 2 O 3 and impurities of 0.07% Na 2 O, 0.07% CaO, 0.05% TiO 2 , 0.04% Fe 2 O 3 , 0.04% MgO, and 0.03% P 2 O 5 (in wt%).XRD and FTIR spectroscopy showed that -Al 2 O 3 was the only detected phase.The powder consisted of strong agglomerates with hundreds of micrometers in size and primary particles of few micrometers, connected by strong sintering bonds forming necking between particles, typical of unground calcined powders (Figure 1(a)).
After ball milling, the hard agglomerates were crushed and resulted in discrete faceted particles, typical of ground ceramic powders, in the range of submicrometric to micrometric sizes.No significant differences were observed between the powders milled under different pH conditions (acidic, acidic-basic, and basic medium) when analyzed by SEM (Figures 1(b)-1(d)).However, XRD analysis and FTIR spectroscopy revealed that the powder milled under acidic (pH 4.0-4.2) condition had only -Al 2 O 3 phase (ICSD 85137), as the starting powder, while the powders milled under acidic-basic (pH 4.1-8.4)and basic (pH 9.2-10.3)conditions presented small fractions of bayerite [-Al(OH) 3 , ICSD 38108], in addition to -alumina (Figure 2(a)).The presence of this aluminum trihydroxide was confirmed by FTIR spectroscopy (Figure 2(b)).The absorption bands at 3370, 3425, 3470, 3547, 3620, and 3654 cm −1 were assigned as vibration frequencies of the OH stretching modes of -Al(OH) 3 and are in accordance with reported FTIR spectrum data for bayerite [22][23][24][25].
Similar mechanochemical transformation of alumina particles during milling has been reported.For an -Al 2 O 3 powder ground in water at pH 8 using a high-energy stirred media mill, the amount of transformed aluminum trihydroxides increased with the milling time; after short milling (2 h) only bayerite (4.6%) was formed, but for longer milling times, gibbsite was also observed (after 8 h, 9.5% bayerite and 5% gibbsite) [19].Besides pH of suspension and milling time, the type of mill also affects the hydration of alumina.It has been shown that wet milling of an -Al 2 O 3 powder in a ball mill and a planetary ball mill resulted in formation of bayerite and gibbsite, while no transformation occurred when a jetmill was used.The relative amounts of formed trihydroxides varied with the milling type: ball milling (24 h) resulted in more gibbsite, and planetary ball milling (5 h) resulted in the formation of more bayerite [18].These reports indicate the complexity of mechanochemical transformation of alumina during milling, which depends on the pH of suspension, milling time, type of mill, and other milling conditions (water content, slurry-to-ball ratio, ball size, etc.).
-Alumina is not the stable phase in contact with water, and the aluminum trihydroxides, Al(OH) 3 , can be formed by a hydration reaction as follows: The Al  [27,28].It was reported that ageing a -Al 2 O 3 powder (with specific surface area, SSA, of 140 m 2 /g) in water with 0.1 M NaCl for more than one month at 25 ∘ C resulted in the formation of bayerite [29].Another study [25] showed that in a -Al 2 O 3 powder (SSA of 189 m 2 /g), suspended in distilled water during a week under continuous stirring at room temperature, different hydroxides were formed depending on the solution pH (adjusted by addition of HNO 3 or NH 3 ): at pH 4, no significant change was observed in the -Al 2 O 3 powder; but at higher pH different aluminum trihydroxides were formed.
In the acidic condition, at pH 5, gibbsite was formed with a small amount of bayerite, and in neutral and basic pH conditions the predominant phase formed was bayerite (with a small amount of gibbsite at pH 7 and 9 and only bayerite at pH 11).It was also observed that bayerite started to form only after 24 h in contact with water at pH 10 [28].Our results are in good agreement with these reports, since the powder milled under acidic (pH 4.0-4.2) condition did not form hydroxides, while the powders milled under acidic-basic (pH 4.1-8.4)and basic (pH 9.2-10.3)conditions formed bayerite.Moreover, considering the above-mentioned reports, ball milling accelerated the formation of bayerite, since this hydroxide started to form in contact with water in less than 10 h, using an -Al 2 O 3 powder, which is more stable than -Al 2 O 3 , and had a lower surface area (SSA < 10 m 2 /g).A comparison between the FTIR spectra of the investigated samples revealed that the powder milled under acidicbasic condition had sharper bayerite bands than those of the powder milled under basic pH condition (Figure 2(b)), suggesting the presence of well crystalized bayerite phase in the first powder and a more distorted bayerite structure in the second one.In fact, it has been observed that the increase in milling time for a bayerite powder (using a planetary ball mill in dry condition) resulted in gradual merging of the several O-H stretching vibration bands, at around 3500 cm −1 , into a single broad band.This result indicates that crystalline bayerite had undergone a transformation to amorphous phase.The disorder in the structure was ascribed to the breaking of hydrogen bonds that link the layers of Al(OH) 6 octahedra in the bayerite crystal during grinding [30].The less disordered bayerite structure in the powder milled under acidic-basic condition can be related to the phase transformation during the milling.The studied alumina powder (CL2500) had a basic pH character, which increased the suspension pH during the milling, as new surfaces were exposed to the liquid due to the fracture of particles.Once during the milling in acidic-basic condition the pH increased from 4.1 to 8.4, probably at the initial stage, in acidic pH; gibbsite or an amorphous hydroxide was formed and gradually transformed to bayerite as the pH increased.This behavior has been reported in experimental observations of the effects of pH on the hydration of alumina and -alumina and precipitation studies [28,31,32].This phase transformation favors the appearance of a recrystallized structure, which eliminates defects previously introduced in the precursor phase (gibbsite); therefore, less defective bayerite crystals were formed.In the basic (pH 9.2-10.3)condition, it seems that bayerite was formed primarily and subjected to the grinding effect over time, resulting in a disordered structure and broadening of the FTIR spectrum bands.
Figure 3 shows TEM and STEM images of the powders milled under different pH conditions.The surface of alumina particles milled under acidic pH condition (Figures 3(a) and 3(b)) had continuous and sharp features, indicating relatively extensive crystalline regions.Small crystallites on the surface of large alumina grains, which might be expected from the hydroxide transformation, were not detected.The observed microstructural features indicated that the mechanochemical transformation did not take place during milling in acidic pH.However, for the powders milled under acidic-basic (Figures 3(c) and 3(d)) and basic (Figure 3(e)) pH conditions, an irregular layer covering the surface of alumina particles was observed.This layer was more electron-transmissive than the original primary particles, which is related to the formation of a coating with lower density than the particles.This coating consisted of nanocrystallites less than 10 nm, some of them equiaxial, while others are of columnar shape, grown from the surface of primary particles.These microstructural features indicate the formation of aluminum trihydroxides, according to the results of XRD and FTIR spectroscopy.Some isolated polycrystalline nanometric agglomerates were also observed in these powders (Figure 3(f)) but were absent in the powder milled under acidic pH condition.Similar coatings of low density aluminum trihydroxides were also observed in ball milled -alumina powders in other studies [33][34][35].These results confirm that hydration occurs on the surface of alumina particles, in a process that is intensified under milling.It has also been proposed that the formation of aluminum trihydroxides can result from the dissolution of alumina and precipitation from a supersaturated solution, leading to the formation of hydroxide crystals away from the alumina surface [28].In fact, the solubility of alumina and aluminum trihydroxides in water is low in the pH range from 5 to 8 but increases sharply beyond this range [19,27,36], which makes this mechanism feasible.

Hydrothermally Treated Powders.
The powders milled under different conditions were hydrothermally treated and characterized by XRD and FTIR spectroscopy (Figure 4).As expected, the powder milled under acidic pH condition had no alteration during the hydrothermal treatment and the XRD pattern indicated only the presence of -Al 2 O 3 phase (Figure 4(a)).However, the powder milled under acidic-basic condition presented both bayerite [-Al(OH) 3 , ICSD 38108] and boehmite (-AlOOH, ICSD 93734) phases, whereas the powder milled under basic pH condition had only boehmite, in addition to the main -Al 2 O 3 phase, as shown in the XRD patterns and confirmed with the FTIR spectra (Figure 4(b)).
The absorption bands at 3090 and 3293 cm −1 were assigned as vibration frequencies of OH stretching modes (asymmetric and symmetric, resp.) of -AlOOH and are in accordance with the FTIR spectrum data reported for boehmite [37][38][39][40].These results showed that the aluminum trihydroxide formed during ball milling (bayerite) was partially or completely transformed to aluminum oxyhydroxide (boehmite) during the hydrothermal treatment.
Boehmite has been synthesized by hydrothermal treatment of either trihydroxides or solutions, but minimum conditions must be satisfied to achieve full conversion or precipitation.It was demonstrated that the transformation of bayerite to boehmite was incomplete (50% conversion) under static hydrothermal treatment (180 ∘ C, 1 MPa, 2 h), but it was enhanced under stirring, controlled atmosphere (H 2 ), and higher pressure (4 MPa) [41].For a solution of Al(NO 3 ) 3 ⋅9H 2 O and NaOH in alkaline medium (pH 11.6) using an autoclave at 160 ∘ C, it was observed that bayerite was formed in the early stages of precipitation and was later converted to boehmite by dissolution-reprecipitation mechanism; 100% boehmite was obtained after 5 h of hydrothermal treatment [42].Also using a solution of aluminum nitrate, with urea as neutralizing agent, under stirring of 300 rpm in a closed reactor (0.9 MPa), the minimum temperature required for precipitation of the crystalline boehmite was 160 ∘ C [43].
In this work, the hydrothermal treatment was conducted at 150 ∘ C and 0.3 MPa during 3 h, without agitation.This setting was not sufficient to achieve the full conversion of bayerite to boehmite for the powder milled under acidic-basic condition.However, under the same conditions, the bayerite present in the powder milled at basic pH was completely converted to boehmite.This result indicated that the bayerite formed when the pH is maintained in the basic range during the whole milling process can be more easily transformed to boehmite during autoclaving, which might be related to the more disordered structure of the bayerite formed in this case (broader FTIR absorption bands, Figure 2(b)).It is well known that phase transformations can be accelerated by the reduction of particle size and the presence of crystal defects, which can act as rapid diffusion paths and sites for heterogeneous nucleation [44,45].Thus, mechanochemically induced crystal defects seem to have favored the phase transformation of bayerite to boehmite during the hydrothermal treatment.Figure 5 shows TEM images of hydrothermally treated powders.The powder milled under acidic-basic condition presented a layer of hydroxide on the surface of micrometric alumina particles (Figure 5(a)) as well as some agglomerates of nanometric particles (Figure 5(b)).On the other hand, the powder milled under basic pH condition had a few nanoparticles covering the alumina particles, but most of them were detached from the surface (Figure 5(c)), forming agglomerates of very fine boehmite particles (Figure 5(d)), as identified by XRD and FTIR spectroscopy analyses (Figure 4).Agglomerates of boehmite nanoparticles with characteristics similar to those shown in Figure 5(c) were observed by TEM analysis, after hydrothermal treatment at 120 ∘ C of a solution of Al(NO 3 ) 3 ⋅9H 2 O and NaOH [42].This feature was taken as an indication that the conversion of bayerite into boehmite would be controlled by dissolution-reprecipitation mechanism, since the topotactic phase transformation is not likely to occur due to different structural forms,  and , of these compounds [42].Similarly, for the powder milled under acidic-basic condition, it seems that only a fraction of the massive layers of bayerite formed on the surface of alumina particles was converted into boehmite nanoparticles (Figure 5(b)), while the remaining fraction was kept untransformed (Figure 5(a)).
Table 1 shows the results of particle size distribution and specific surface area (SSA) of milled and hydrothermally treated powders.As noted before (Figure 1), a significant reduction in particle size occurred, since  50 changed from 90 m in the starting powder to around 1.65 m after ball milling, regardless of the pH of the suspension.The powder milled under basic pH condition had higher SSA (5.25 m 2 /g) than the powder milled under acidic-basic condition (4.14 m 2 /g), due to its higher content of boehmite nanoparticles after hydrothermal treatment.The powder milled under acidic pH condition presented the highest SSA (6.71 m 2 /g).Nonetheless, this value could not be correlated with the presence of nanoparticles, since no aluminum hydroxides were formed in this powder.Additionally, the particle size distribution was similar for all powders.
Figure 6 shows the results of thermal analyses of milled and hydrothermally treated powders.As expected, no significant thermal events were observed in the powder milled under acidic pH condition, since it contained only the stable -Al 2 O 3 phase.For the powder milled under acidic-basic condition, which had bayerite and boehmite, the weight loss gradually increased during the initial heating, achieving 0.14 wt% at 238 ∘ C, as a result of water desorption (TGA curve, Figure 6(b)).An abrupt weight loss of 0.20 wt% was observed between 238 and 265 ∘ C, corresponding to an endothermic peak in the DSC curve (Figure 6(a)) at 257 ∘ C, which was assigned to the decomposition of bayerite.The decomposition temperature of unground bayerite has been reported at around 300 ∘ C, but this temperature can be reduced to temperatures as low as ∼130 ∘ C after long milling  periods [30,41,51].Above 265 ∘ C, the weight decreased continuously, reaching a weight loss of 0.57 wt% at 445 ∘ C, when a new inflection was observed in the TGA curve.Such mass loss is related to a continuous dehydration of bayerite, as has been reported for the thermal decomposition of mechanically activated gibbsite and bayerite [51,52].
The decomposition reaction of bayerite can be described as [30] 2 Considering the predicted weight loss of 34.6 wt% for the water evaporation in (2), the weight loss of 0.43 wt% between 238 and 445 ∘ C corresponded to a bayerite content of 1.2 wt%.The weight loss rate increased again between 445 and 490 ∘ C in TGA curve (Figure 6(b)), although no significant variation in heat flux could be detected in this temperature range for the DSC curve of the powder milled under acidicbasic condition (Figure 6(a)).However, for the powder milled under basic pH condition, an endothermic peak at 473 ∘ C was observed, which was assigned to the decomposition of boehmite [41,46,53].Therefore, the weight loss of 0.07 wt% between 445 and 490 ∘ C in the powder milled under acidicbasic condition was assigned to the dehydration of boehmite, whe reaction is given by [30]   Considering the theoretical water loss in (3) (15.0 wt%), the estimated boehmite fraction was 0.5 wt% in the powder milled under acidic-basic condition.
For the powder milled under basic pH condition, which had only boehmite after the hydrothermal treatment, the mass decreased during the initial heating due to the water desorption, achieving 0.14 wt% of weight loss at 265 ∘ C (TGA curve, Figure 6(b)).Above this temperature, the weight loss rate gradually increased and almost ceased at 485 ∘ C (temperature at the end of endothermic peak of the boehmite decomposition, Figure 6(a)).Similar thermogravimetric curves for the decomposition of boehmite have been reported [41,46].In this temperature range (265 to 485 ∘ C), the weight loss was 0.48 wt%, which corresponded to a boehmite fraction of 3.2 wt%, according to (3).An exothermic peak was observed at 877 ∘ C in the DSC curve of the powder milled under basic pH condition, which can be related to the transformation of -Al 2 O 3 to -Al 2 O 3 [30].
In summary, thermal analyses indicated the formation of 1.7 wt% of aluminum hydroxides (1.2% bayerite and 0.5% boehmite) in the powder milled under acidic-basic condition and 3.2 wt% of boehmite in the powder milled under basic pH condition, both after the hydrothermal treatment.These results are in good agreement with those found by transmission electron microscopy, which indicated the presence of more nanoparticles in the powder milled under basic pH.

Extrusion Behavior of Treated Powders.
The behavior during the extrusion of pastes prepared with milled and hydrothermally treated alumina powders varied significantly, depending on the milling pH, as shown in Figure 7. Pastes prepared only with water addition did not develop the plasticity required for extrusion.The force applied on the piston gradually increased as the piston moved, reaching 2.0 kN after the displacement of 10 mm.Above this point, the force increased rapidly, exceeding 50 kN at the end of the test (Figure 7(a)).The steady increase in force is associated with the occurrence of water exudation during extrusion, known as liquid phase migration [54][55][56][57][58].The water retention capacity is important to maintain the layer of lubricating liquid between the ceramic particles during the forming process.Thus, as the amount of water in the paste was reduced, the force required to push the extruded segment increased.In fact, water droplets were observed leaking from the junctions of extrusion device during the extrusion test, and an almost-dried powder compact remained in the barrel of extrusion device after the test.
The pastes prepared with the addition of 1.0 wt% of CMC also showed significant water migration for the powders milled under acidic and acidic-basic pH conditions, in accordance with the continuous increase of the extrusion force as a function of the piston displacement (Figure 7(b)).The plasticity of pastes prepared with these powders was improved by increasing the CMC content.After addition of 1.5 wt% CMC, the migration of water and the extrusion force were reduced, even though for either powder a steady state of constant force along the piston displacement was not reached (Figure 7(c)).At piston displacement of 10 mm, the extrusion force values were 0.9 and 0.6 kN for the powder milled under acidic pH condition with 1.0 and 1.5 wt% of CMC, respectively, while for the powder milled under acidicbasic condition the force values were higher (1.6 and 1.0 kN, resp.).On the other hand, the pastes prepared with the powder milled under basic pH condition and addition of 1.0 and 1.5 wt% of CMC presented a plateau of constant extrusion force of 0.1 kN during the tests (Figures 7(b) and 7(c)).These results showed that the boehmite nanoparticles imparted plasticity to the alumina powder, improving the water retention during the extrusion when low amounts of organic (CMC) binder were added.The beneficial effects of boehmite are related to the nanometric dimensions of particles and the shear capacity of its layered crystal structure, which is similar to plastic clays [59].
The addition of 2.0 wt% of CMC changed the extrusion behavior of all powders.The pastes prepared with the powders milled under acidic and acidic-basic pH conditions However, for the paste prepared with the powder milled under basic pH condition, the extrusion force increased and reached 0.9 kN at the piston displacement of 10 mm, revealing that an excessive addition of CMC binder in the presence of boehmite is deleterious to the extrusion behavior of the paste.It has been shown that the addition of ∼11 wt% of colloidal boehmite and 0.3 wt% of PVA to -Al 2 O 3 powders yields pastes with good plasticity, water retention, and the ability to flow under an applied constant force of ∼1 kN in extrusion tests [8].Another work demonstrated that the addition of organic binders (0.25 wt% of PVA, 3.0 wt% of either PEG or glycerin) to an alumina paste containing 15 wt% of boehmite helped to achieve a very low extrusion pressure, similar to that observed using a conventional binder system (HPMC polymer) [60].In the present work, the alumina powder milled under basic pH condition had only 3.2 wt% of boehmite nanoparticles, but such low amount of boehmite, associated with a small fraction of organic binder (1.0 wt% CMC), was sufficient to prepare a paste with adequate rheology and low extrusion pressure.These results showed that the boehmite nanoparticles generated in situ by mechanochemical and hydrothermal treatments are very effective as inorganic processing aid for extrusion of alumina powders.Moreover, this processing route can decrease by 50% the content of organic binder used in the forming processes, with a potential to reduce the environmental impact caused by its thermal decomposition.
The surface finish of extruded rods prepared with the treated powders was varied, as observed by optical microscopy (Figure 8).For the extrusion tests that showed a plateau of constant extrusion force with the piston displacement, the extruded rods had relatively smooth surfaces (e.g., Figure 8(c)), but when this regime was not reached, the rods had rough surfaces and edge tearing-periodic surface cracks were formed (e.g., Figure 8(a)) [55].This type of defect occurs because of the poor paste plasticity, the high extrusion force, and the liquid migration.Although the powder milled under acidic-basic condition did not present a reduction of the extrusion force at the level presented by the powder milled under basic pH condition, the extruded rods had smoother surfaces (Figure 8(h)) than the rods prepared with the powder milled under acidic pH condition (Figure 8(g)).This result indicated the beneficial effect of the presence of nanoparticles (1.2 wt% bayerite and 0.5 wt% boehmite) on decreasing the friction between the extruded alumina rod and the die surface.
The extruded rods had no shrinkage after presintering at 1100 ∘ C, which means that their strength resulted only from the neck formation between particles during the initial stage of sintering and from the surface quality of the extruded segments [61].Figure 9 shows the results of four-point bending strength of the presintered samples as a function of CMC content added for extrusion.For segments prepared with the powder milled under acidic pH condition, the strength increased with CMC content (1.5 to 5.4 MPa), because of the improvement of surface smoothness.A similar tendency was observed for the segments prepared with the powder milled under acidic-basic condition, but with higher values of strength (4.8 to 6.9 MPa).These results indicated that, besides the surface quality, the presence of aluminum hydroxide nanoparticles also contributed to increasing the strength, since they enhanced the neck formation between alumina particles during the presintering treatment.The segments with the highest strength (7.0 MPa) were those prepared with the powder milled under basic pH condition and 1.5% CMC, which were benefited by the two effects, associated with the presence of boehmite nanoparticles: the batch had good plasticity, resulting in smooth surface, and the neck formation between alumina particles was enhanced [20].
The results showed that boehmite nanoparticles formed by mechanical activation and subsequent hydrothermal treatment can improve the plastic behavior of alumina pastes during extrusion, reducing the content of organic binder and increasing the strength of formed and presintered bodies.

Conclusions
The pH of suspension during the ball milling of alumina powder affects the formation of aluminum hydroxides on the surface of particles.Under acidic pH (4.0-4.2), the formation of hydroxides was not observed.When the milling medium naturally changed from acidic (pH 4.1) to basic (pH 8.4) during milling, bayerite [Al(OH) 3 ] nanoparticles were formed, of which only a small fraction was converted to boehmite (AlOOH) during the hydrothermal treatment; thermal analyses indicated formation of 1.2 wt% of bayerite and 0.5 wt% of boehmite.The aluminum hydroxides formed in this condition improved the smoothness of the extruded rods and the strength of presintered segments; nonetheless, they were not able to prevent water migration during the extrusion process.For the powder milled under basic pH (9.2-10.3)condition, the mechanochemically formed bayerite was completely converted to boehmite nanoparticles during the hydrothermal treatment, resulting in 3.2 wt% of boehmite in the alumina powder.The boehmite nanoparticles contributed to the development of plasticity, which allowed the reduction of the organic binder.Additionally, the strength of the presintered segments was increased.

Figure 1 :
Figure 1: SEM images of starting alumina powder (a) and powders wet milled under acidic (b), acidic-basic (c), and basic (d) pH condition.

Figure 3 :Figure 4 :
Figure 3: STEM images of the alumina powder milled under acidic pH condition (a, b) and TEM images of powders milled under acidic-basic (c, d) and basic (e, f) pH conditions.

Figure 5 :
Figure 5: TEM images of hydrothermally treated powders after milling under acidic-basic (a, b) and basic (c, d) pH condition.

Figure 7 :
Figure 7: Results of extrusion tests (force as a function of distance traveled by the piston) of the pastes prepared with treated powders (milled under different pH conditions and hydrothermally treated) and different amounts of CMC content: (a) 0 wt%, (b) 1.0 wt%, (c) 1.5 wt%, and (d) 2.0 wt%.

Figure 9 :
Figure 9: Results of four-point flexural strength of the presintered segments extruded with treated powders as a function of added CMC content.