Two mineral powders: Natural diatomite and alumina (Al2O3) were selected for the elaboration of our ceramic membrane supports. Alumina Al2O3 was obtained from Sigma–Aldrich; diatomite originates from the Sig region (Algeria). Alumina is intended to improve the mechanical properties of the diatomite-based membrane supports. It is also used to increase the average pore size of samples. The organic additive, Methylcellulose, is used as a binder in order to improve the rheological properties of the paste; thus, it facilitates the forming of supports.

Specimens were prepared in steps. The first step is to prepare the paste by mixing diatomite as major raw material and different amounts of alumina powders. Five different compositions were prepared by changing the relative amount of alumina (from 0 to 20wt%) as ratios of: 100:0, 95:5, 90:10 and 80:20 (by weight). These are named: 0A, 5A, 10A and 20A, respectively. The starting materials were initially mixed with 4wt.% methyl-cellulose as a binder. With the progressive addition of water, the powder mixture was aged to obtain a plastic paste with high homogeneity and to allow forming. Water was added to the mixtures between 35% and 40wt.% to obtain a plastic paste that has high homogeneity and moisture content. The second step is the synthesis of membrane supports using the extrusion method (Fig. 1a). The paste was molded into two forms, tubular and flat rectangular. The flat rectangular samples have been used for mechanical tests (three-point bending test). To obtain homogeneity and quality drying, we cut the tubular supports to the desired lengths at the end of the extruder nozzle and placed them on aluminum rollers rotating evenly so that the tubes do not deform. The tubular supports have 6mm inner and 10mm outer diameters, while the length is selected according to our needs. After drying at room temperature, the supports (Fig. 1b, c) were sintered at temperatures ranging from 1100 to 1250°C for 1h. First, 2°C/min heating rate is applied in the range 30–250°C; then, the heating rate is increased to 5°C/min from 250°C to target.

Fig. 1.

(a) A photograph of a mechanical extruder. (b, c) A photograph of prepared tubular and flat rectangular supports, respectively.

(0.14MB).

Several techniques were used to investigate the proprieties of ceramic supports. The structural proprieties of the raw and supports materials were determined by X-ray diffraction (XRD) using an ULTIMA IV Rugaku, CuKα (λ=1.54093Å). The flexural strength of sintered supports has been measured by mechanical experiments consisting of a three-point standard test (five test specimens were used). The morphology and surface quality of supports were examined with scanning electron microscopy (SEM). The pore characteristics: total porosity ratio, APS or diameter, and pore size distribution (PSD) has been determined by mercury intrusion porosimetry technique (Micromeritics, Model Autopore 9220) for specimens sintered at different temperatures. Chemical analysis of raw materials was carried out by means of a Spectro iQ II X-Lab apparatus. Differential scanning calorimetry (DSC) and thermogravimetric analysis (TGA) were performed using an SDT Q600 TA Instruments from 30 to 1250°C at a heating rate of 10°C/min. The Fourier Transform Infrared (FT-IR) spectra are recorded in the wavenumber range between 400 and 4000cm−1 at room temperature.

The chemical composition of the starting powders is given in Table 1 as weight percentages of oxides. It can be said that the diatomite powder is essentially composed of large amounts of silica (SiO2) and CaO, whereas Al2O3, MgO, and Fe2O3 can be considered as impurities. The quantitative analysis of added alumina (Al2O3) shows that the purity of this raw material is about 99%. It also contains 0.24wt% MgO, 0.22wt% P2O5, and 0.11wt% Na2O as impurities. XRD patterns of the raw diatomite, calcined diatomite, and alumina powder are given in Fig. 2. The main phases forming the raw diatomite are found to be amorphous SiO2, quartz form of SiO2, calcite (CaCO3), and ankerite (Ca(Mg,Fe)(CO3)2) (dolomite forms) (Fig. 2a) [28–30]. Fig. 2b shows that upon calcination at 800°C for 1h, an increase in the intensity of the quartz peak, the disappearance of the CaCO3 and ankerite phases, and the appearance of wollastonite CaSiO3 phase can be observed. The XRD spectrum of alumina powder involving only Al2O3 peaks is shown in Fig. 2c. This spectrum also shows that the alumina powder is well-crystallized.

Fig. 2.

XRD spectra of (a) raw diatomite. (b) Calcined diatomite at 800°C for 1h. (c) Alumina powder.

(0.14MB).

Fig. 3 and Table 2 illustrate the FTIR spectroscopy of the starting raw and calcined diatomite. The spectrum confirms the presence of CO32− deformation bands at 1431, 876, and at 727cm−1 from calcite and ankerite in diatomite. The signals related to silica are found at 798cm−1and 1068cm−1. A large band centered on 3389cm−1, and the peak at 1637cm−1 are attributed to the stretching and bending vibrations of OH bond of the adsorption water; they disappear after calcination. This result indicates the hydrophilic character of raw diatomite. We can also see that the vibration CO32− bands, initially present on the raw diatomite spectrum, disappear in the case of treated diatomite. This finding is in good agreement with the XRD results.

Fig. 3.

FTIR spectrum of diatomite. (a) Before and (b) after calcination at 800°C for 1h.

(0.15MB).

The particle size distribution for the raw material was measured by the Horiba laser scattering particle size distribution analyzer LA 960 (Fig. 4). This figure shows that almost 50% of the particles have a diameter below 20μm. The average particle size for alumina and crushed diatomite is about 9μm and 20μm, respectively. Scanning Electron Microscopy (SEM) images of the powders are shown in Fig. 5. The raw diatomite powder consists of particles of various forms such as discs, pinnate and tubular shapes (Fig. 5a). In addition, diatomite has a porous microstructure, and some large particles are an agglomeration of smaller particles. Fig. 5b shows that the alumina particles have irregular shapes and variable sizes; plate-like particles are also present.

Fig. 4.

Particle size distribution for diatomite and alumina powders.

(0.15MB).

Fig. 5.

SEM micrograph of powders; (a) diatomite, (b) alumina.

(0.13MB).

Differential scanning calorimetry (DSC) and thermogravimetric analysis (TGA) were used to determine the structural evolution of the raw diatomite powder (Fig. 6). These two analyses were performed under air in the range of 30–1250°C. Fig. 6 shows the results for raw diatomite; three endothermic peaks show up on the DSC curve. The thermogravimetric curve indicates that the first and second endothermic processes are accompanied by a decrease in the mass of the sample. The first peak at about 83°C, associated with a weight loss of about 4.4%, can be explained by the release of surface adsorbed water. The second endothermic peak at about 668°C can be associated with a weight loss of around 12% that could be attributed to the decarbonation of calcite from (CaCO3) to CaO (breakdown of carbonates accompanied by CO2 release). The endothermic reaction, at around 1096°C, could be caused by the transformation of the quartz to cristobalite [31].

Fig. 6.

DSC and TGA curves for diatomite powder.

(0.11MB).

Phases identification is of great importance to understand our prepared prototype and determine the application. The presence of certain phases may limit their use to the filtration of solutions. We have used XRD to investigate the influence of alumina additives on formed phases. Fig. 7 shows the XRD pattern of the samples sintered at 1200°C for 1h. The principal observed phases are cristobalite (tetragonal SiO2), quartz (hexagonal SiO2), alumina Al2O3, wollastonite (CaSiO3), and anorthite (CaAl2Si2O8). The cristobalite phase should be ascribed to the transformation of the amorphous silica phase (SiO2·nH2O) into cristobalite, as well as part of quartz [31]. In all studied samples, the amorphous silica phase (SiO2·nH2O) transformed into cristobalite rather than other silica phases during calcination, primarily because the amorphous phase was the aggregation of cristobalite microcrystalline. Quartz in raw diatomite is inclined to turn into cristobalite upon calcination rather than tridymite because of the presence of the crystal nuclei of cristobalite produced from the phase transfer of micro-amorphous silica to cristobalite; it is thought that this process lowers the activation energy [31]. For the specimens containing 20wt.% of alumina, the latter reacts with CaO and SiO2 to produce an anorthite phase (CaO·Al2O3·2SiO2); the wollastonite phase also disappears at this percentage, and anorthite becomes more crystallized. By contrast, when supports are prepared only from diatomite, the main phases observed are wollastonite, quartz, and cristobalite.

Fig. 7.

XRD spectra of support samples sintered at 1200°C for 1h.

(0.26MB).

For the fabrication of high-quality membrane supports, the important properties to be optimized are porosity, APS, pore size distribution, mechanical properties, chemical stability, and concentration of surface and volume defects. The open cell porosity and the APS for supports sintered at 1200°C for 1h, as a function of wt.% of added alumina, are illustrated in Fig. 8. The findings suggest that the average values of our quantities vary significantly and depend on the wt.% of the alumina additive. The APS gradient presents a trend dissimilar to that of the open porosity (Fig. 8a). It is clear that the alumina additive decreases the open porosity while it increases the APS. SEM micrographs confirm this result presented in Fig. 10. For example, the support (0wt.% Alumina) has an APS around 3.3μm and an open porosity ratio of 56%. In contrast, the support (diatomite +20wt.% Alumina) has an APS around 20.7μm and an open porosity ratio of 39.5%. We have to bear in mind that these supports have been sintered in the same conditions (1200°C for 1h). The low open porosity for samples 10A and 20A sintered at 1200°C can be explained by the liquid phase formation following the reaction between wollastonite–silica– and anorthite. In general, the melted phase of the mixture plays a major role; it makes the material bulk denser. Alumina and impurities like CaO, MgO, K2O, and Na2O (Table 1) facilitate the formation of low-temperature eutectics in diatomite. Hence, we have the formation of a melt phase in silica-rich grains resulting in enlarged pores [32,33]. Fig. 8b illustrates the pore size distribution curves for supports containing 0, 5, 10, and 20wt.% of alumina additives sintered at 1200°C. This figure shows that for specimens prepared from diatomite alone, most of the pores have a diameter that ranges from 1.4μm to 6μm. whereas, for samples with alumina addition, most pores diameter ranges from 1.4 to 45μm. This means that the APS is larger for supports prepared with alumina addition. The pore size distribution, the APS, and open porosity percentage curves for specimens containing 10wt.% of alumina as a function of sintering temperature (1150–1250°C) are shown in Fig. 9. This composition was chosen because it has the best characteristics in terms of the APS, the open porosity, and the flexural mechanical strength. It can be seen that APS increases with temperature, while we see the opposite for open porosity. When the sintering temperature increased from 1150 to 1250°C, the APS moves from 2.5 to 40.4μm while the open porosity decrease from 52.8 to 26.3%. Therefore, the ideal temperature for sintering is 1200°C. The results above prove that the APS and the porosity can be controlled by choosing the appropriate percentage of alumina added. Structural characteristics of the final membrane supports, prepared from diatomite and alumina, are summarized in Table 3.

Fig. 8.

(a) Variation of average pore size and open porosity as a function of the alumina content for supports sintered at 1200°C. (b) Pore size distribution in supports sintered at 1200°C for 1h.

(0.17MB).

Fig. 9.

(a) Variation of average pore size and open porosity with sintering temperature for supports (10wt.%). (b) Pore size distribution for supports (10wt.%) sintered at different temperatures.

(0.16MB).

A typical description of the microstructure of samples 0A, 10A, and 20A sintered at 1200°C is shown in Fig. 10. This micrograph illustrates the type of pore size distribution within the matrix. Small voids are found in the microstructure of sample 0A. There are less open porosity and larger pore sizes in the microstructure of samples 10A and 20A; this is because the alumina addition helps to ease the grain growth, thus encouraging the coalescence of pores, which in turn leads to larger average pore size. In fact, the eutectic liquid phase between alumina and elements composing diatomite promotes grain growth and diffusion at around 1200°C and also causes the enlargement of pores.

Fig. 10.

SEM micrographs of membranes support sintered at 1200°C for 1h. (a) Surface (b) cross-section.

(0.64MB).

Fig. 11 presents the flexural strength of specimens sintered at 1200°C as a function of added alumina (wt.%). Two separate stages can be noticed. First, as alumina is added, the flexural strength increases suddenly, up to 28MPa for supports 10A, before it starts decreasing in the second stage when the content of alumina exceeds 10wt.%. The initial increase in strength may be closely related to the effect of sintering which causes grains to densify. Sintering is a controlling factor that can boost mechanical properties. However, when 20wt.% of alumina are added, the strength value decreased sharply down to 8MPa. Accordingly, it can be said that the flexural strength is controlled by the alumina content and sintering. Open porosity and pore size have been found to correlate with the strength of a material. As expected, samples with high open porosity (i.e. samples with 0 and 5wt. % of Al2O3) and large pore size (i.e. samples with 20wt. of Al2O3) have the lowest flexural strength.

Fig. 11.

Flexural strength as a function of the alumina content for membrane supports sintered at 1200°C for 1h.

(0.09MB).

Tangential filtration experiments were performed on prepared membrane supports, using a home-made pilot plant at room temperature. Fig. 12a shows water permeability through the support (10% sintered at 1200°C) measured as a function of time and applied pressure. A stable flux is obtained after 30min. Correspondingly, the flux increases with the applied pressure; this is because the pressure enhances the convective driving force in the membrane support [34,35]. Additionally, the effect of the applied pressure on water permeates flux has been taken into account. Fig. 12b shows the flux of distilled water through the supports 0, 5, 10, and 20A as a function of applied pressure. As can be seen in Fig. 12b, with an increasing applied pressure difference (from 0.4 to 1.2bar), the flux increases linearly for all samples; this indicates that the pressure difference is the only driving force for permeation. The average permeability values are 8, 10, 15, and 28m3h−1m−2bar−1 for supports 0A, 5A, 10A and 20A, respectively. This trend is due to the effect of larger pore size that causes the increases in water flux. Because of the lower average pore size (≈3μm), the flux of water permeability is found to be relatively low, as expected for support 0A. Another fact is that the water flux increases proportionally with the added alumina. The porosimetry characterization results indicate that the APS varies exponentially with the amount of alumina added. We must remember, also, that the most important factor affecting the flux and permeability is the pore size, as can be demonstrated by the Hagen–Poiseuille equation [36].

Fig. 12.

(a) Distilled water flux versus time, at different working pressures, for supports (10wt.%) sintered at 1200°C. (b) Water flux variation as a function of different applied pressures.

(0.15MB).