The TFT-LCD waste glass and SB waste were provided by the Central Taiwan Resource Recycling Plant and Solar Energy Technology Company, respectively. These wastes were dried, ground and sieved to achieve a particle size≤74μm. As shown in Table 1, its chemical composition was measured and analyzed by X-ray fluorescence (XRF) spectroscopy. The main components of the TFT-LCD waste glass were SiO2, Al2O3 and CaO, which accounted for 69.70%, 15.30% and 8.45%, respectively, and the SiO2/Al2O3 ratio was approximately 4.5. The main components of the SB waste were SiO2 and Al2O3, which accounted for 70.10% and 13.90%, respectively. The SiO2/Al2O3 ratio was calculated to be approximately 5.0. Among them, TFT-LCD waste glass mainly came from material cut from glass substrates, and SiO2 and Al2O3 were the main composition of the glass network structure, thereby providing an abundance of SiO2 and Al2O3.

TFT-LCD waste glass and SB waste were mixed together, and silicate and aluminosilicate were extracted through an alkali fusion temperature of 450°C with the addition of a 1.5 proportion of NaOH (mixed powder:NaOH=1:1.5). The powder was mixed with distilled water (liquid/solid ratio, L/S=5, 10, 20) at different ratios to dissolve the aqueous solution containing SiO2 and Al2O3 and then filtered to obtain sodium aluminosilicate solutions with SiO2/Al2O3 molar ratios of 26, 41.8 and 56.3.

Al-MHCM was synthesized by using the hydrothermal method. First, the required amount of CTAB was dissolved in 30mL of deionized water and ammonia to form a template solution. Sodium aluminosilicate solutions with the different SiO2/Al2O3 molar ratios stated above were slowly added to the CTAB template solution while stirring. Sulfuric acid (1M) was used to adjust the pH of the dispersion, and then the dispersion was stirred continuously for 2h. The mixed solution was then transferred to a stainless steel autoclave (200mL) lined with Teflon. The mixed solution was heated at different hydrothermal temperatures (90, 105, 120°C) for 48h. Next, the obtained product was washed with distilled water, filtered, and then dried in an oven at 105°C overnight. Finally, the obtained product was calcined up to 550°C at a heating rate of 5°C/min in air to burn off the surfactant from the matrix. The obtained mesoporous material was called Al-MHCM.

The used TFT-LCD waste glass and SB waste were analyzed by an XRF fluorescence analyzer (RIX 2000) to obtain the chemical element composition of the raw materials. The pore structure of Al-MHCM was determined by X-ray powder diffraction (D8A XRD) to identify the crystalline phases in the material. Diffraction data were collected between 2θ=1–8° using the Ni-filtered CuKα radiation (λ=0.1542nm). Scanning electron microscopy (SEM; American FEI company (Nova Nanosem 230) was used to characterize the surface morphology and structural changes of the sample. High-resolution solid state 27Al MAS NMR spectra was recorded on a Bruker AVANCE III 400MHz NMR spectrometer at 104.26MHz, with a pulse width of 1.00μs, a pulse delay of 1s, a spinning rate of 15kHz and 1000 scans. Specific surface area, pore volume, and average pore size of materials were determined at 77K on a nitrogen adsorption–desorption apparatus (TriStar 3000) and calculated by the Brunaer–Emmett–Teller (BET) method. Samples were degassed at 250°C for 2h before performing the adsorption-desorption experiment. Pore-size distributions were created using the adsorption branch of the isotherm via the Barrett–Joyner–Halenda (BJH) model.

The moisture adsorption/desorption test was performed in accordance with the method for measuring the equilibrium moisture content in Japanese Industrial Standards JIS A 1475. First, the test body was dried in an oven at 105°C for 24h, and its constant weight was recorded. Next, the sample was placed in a constant temperature and humidity controller, and the relative humidity was changed to 10, 33, 55, 75, 85, and 95% at a fixed temperature of 23°C. The constant weight of adsorption (from low to high) and desorption (from high to low) of the sample was recorded at this relative humidity. Finally, the moisture adsorption per unit area of mesoporous Al-MHCM was obtained at different times. The standard of the Japanese Industrial Regulations (JIS A 1470) humidity control building materials regulations was verified, and the standard value, based on the average equilibrium moisture content (>5kg/m3), was evaluated.

Fig. 1 shows the XRD diffraction patterns of Al-MHCM synthesized at different temperatures and different Si/Al molar ratios. The XRD pattern of Al-MHCM shows that the main diffraction peaks are at 2.34 and 2.42° along with 3.90 and 4.50°, which correspond to the characteristic d(100), d(110) and d(200) peaks of MCM-41, respectively [32]. At lower Si/Al ratios, the main characteristic peaks are slightly shifted, which is mainly due to the 2θ angle shift caused by the high aluminum content in the source material; this result means that Al atom doping in the crystal lattice changes the crystallinity of the product and causes poor sorting. As the Al content increases, Al-MHCM exhibits a decrease in lattice parameters, which is related to the difference in the ionic radius of Al and Si ions [33]. Therefore, when the Si/Al molar ratio from 41.8 increase to 56.9 (temperature is 90°C), the intensity of the diffraction peak gradually decreases, indicating that the order of the structure decreases [34,35]. In addition, it can be found from the change in the hydrothermal temperature that when the temperature increased from 90 to 120°C, the main characteristic peak d(100) has relatively stable crystallinity. The characteristic peaks (d110 and d200) representing the hexagonal structure also have a tendency to gradually form as the hydrothermal temperature increased because when the hydrothermal temperature increased, the balance between the solid and liquid phases of the initial gel is destroyed; this imbalance accelerates the aggregation of silicate species on the micelle surfaces. Therefore, a high hydrothermal temperature is conducive to the formation of a well-ordered MCM-41 structure because the high temperature will accelerate the condensation rate of silicate on the silicon dioxide wall [36,37].

Fig. 1.

Crystal phase of synthesized Al-MHCM. (a) Si/Al=26; (b) Si/Al=41.8; (c) Si/Al=56.3.

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The 27Al NMR spectrum was used to track the change in the position of Al added to Al-MHCM. All the spectra of the current Al-MHCM material are dominated by the signal of the tetrahedral-coordinated aluminum (AlIV) species with 27Al=53ppm (Fig. 2), confirming that they were related to the Bronsted acid site. If the material can exist in the form of tetrahedrons, the number of Bronsted acid sites on the surface of Al-MHCM will increase, thus increasing the affinity and catalytic performance of the material and simultaneously strengthening the humidity-regulating performance [34]. The weak signal at 27Al=0ppm is due to the octahedral-coordinated aluminum (AlVI) species (Fig. 2(c)) [38], and the appearance of these extra-framework aluminum species indicated that partial dealumination has occurred, which was related to Lewis acid sites [39]. However, when the Si/Al molar ratio is lower (Fig. 2(a), (b)), more Al atoms (AlVI) are introduced into the silicon dioxide framework, thereby generating and enhancing the AlIV signal. It is well known that AlIV can enhance the acid strength of adjacent SiOH groups, thereby forming Brønsted acid sites (BAS) with high catalytic activity [40]. In addition, from the area content of the tetrahedral-coordinated aluminum (AlIV) species, it can be seen that when the hydrothermal temperature is low (90°C), the occupied area is between 38.50 and 52.02%, and when the hydrothermal temperature is increased to 105°C, the area occupied by AlIV species is between 52.67 and 59.61%. In addition, when the hydrothermal temperature is 120°C, the area occupied by species at 53ppm increased to 54.98–67.17%. These results show that as the absence of AlVI sites for the Si/Al=26 or 41.8 means simply that all Al is incorporated as AlIV. However, previous studies have shown that by decreasing the Si/Al ratio, the AlIV signal can be enhanced [41], this led to more Bronsted acid sites on the surface of Al-MHCM.

Fig. 2.

The 27Al NMR spectrum of the synthesized Al-MHCM. (a) Si/Al=26; (b) Si/Al=41.8; (c) Si/Al=56.3.

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The N2 adsorption–desorption phenomenon provides a technique for determining the surface area, pore volume and pore size distribution. The N2 isotherm adsorption–desorption curve is shown in Fig. 3. All the synthesized Al-MHCM junctions exhibit a type-IV nitrogen adsorption-desorption isotherm. According to the International Union of Pure and Applied Chemistry chemical nomenclature (IUPAC), this is a typical feature of homogeneous mesoporous materials [42], attributed to the retention of the ordered mesoporous structure [43]. The isotherm shows the following three stages: when the low relative pressure is 0.2–0.3, the monolayer adsorption of nitrogen on the mesoporous wall is observed; and when the relative pressure is 0.3–0.4, a sharp increase occurs under the same parameter conditions with different Si/Al ratios. This is characteristic of capillary condensation in mesopores, which shows a narrow hysteresis loop. Finally, when the relative pressure is 0.5–0.9, the synthesized Al-MHCM shows slightly tilted plateau, which is caused by multilayer adsorption on the outer surface of particles [44]. In addition, when the Si/Al ratio is 26, 41.8 and 56.3, the specific surface area ranges from 506–587, 733–795 and 781–1013m2/g, respectively. The adsorption–desorption characteristics for all samples are typical of mesoporous materials, indicating that mesoporous materials have better adsorption performance.

Fig. 3.

The N2 adsorption–desorption isotherm curves of the synthesized Al-MHCM. (a) Si/Al=26; (b) Si/Al=41.8; (c) Si/Al=56.3.

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Fig. 4 shows the total pore volume and pore diameter calculated by the N2 adsorption–desorption measurements and the BJH method and are listed in Table 2. The pore size distribution curves of all Al-MHCM shown in Fig. 4 are unimodal and belong to a narrow range of mesopores that are approximately 3–4nm, indicating the existence of mesopores in the particles. Thus, this result confirms the successful synthesis of a uniform mesoporous material, and is consistent with the BJH method for calculating the pore size (Table 2). In addition, Fig. 4(a) shows that when the Si/Al ratio is 26, the pore volume of the synthesized Al-MHCM is 0.4–0.5cm3/g. When the Si/Al ratio is increased to 56.3, the pore volume is increased to 0.9–1.4cm3/g. Based on the above knowledge, the increase in the Si/Al ratio and hydrothermal temperature can form an ordered mesoporous structure. The pore volume and specific surface area of the synthesized Al-MHCM increase accordingly, with the highest pore volume being 0.97cm3/g, and the highest specific surface area being 1013m2/g (Al-MHCMc3). The results of Sohrabnezhad and Mooshangaie show that adding metal (such as Ag/AgBr) to an MCM-41 material will increase the pore size and pore volume, which indicated that some of the metal was dispersed on the inner pore surfaces of the MCM-41 material [45]. The unit cell parameter “a0” can also be determined using the equation a0=(2*d(100)/√3) from the diffraction peak (1 0 0). Table 2 shows the computed d(100) and a0 values. Furthermore, Table 2 shows the surface area and pore volume of three samples. The maximum value of a0 is 4.69nm. The increase of a0 indicates that the pore wall of silica becomes thicker and more orderly with the increase of Si/Al molar ratio and hydrothermal temperature. Additionally, when the hydrothermal temperature is 120°C, the Si/Al molar ratio from 41.8 increase to 56.3, the a0 of Al-MHCMc3 from 4.69nm decreased to 4.45nm, this behavior might possibly be caused by a slight distortion of the mesoporous channels due to the partial polymerization over pore structures induced by superficial reaction. The thickness of the pore wall was calculated to be 0.72–1.51nm, indicating the high hydrothermal stability of the synthesized Al-MHCM.

Fig. 4.

The total pore volume and pore diameter calculated of the synthesized Al-MHCM. (a) Si/Al=26; (b) Si/Al=41.8; (c) Si/Al=56.

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In this study, the microstructure changes of Al-MHCM were observed through FE-SEM. The morphology of the Al-MHCM material at a 50,000× magnification is shown in Fig. 5. During the hydrothermal treatment under alkaline conditions (pH=10), silicate and aluminosilicate are extracted from the TFT-LCD waste glass and SB waste. Then, the extracted silicate and aluminosilicate are mixed with the CTAB surfactant to form a mesoporous silica material similar to MCM-41 [42]. In addition, it can be seen that even after the calcination process (550°C), the macrostructure of Al-MHCM remains intact, thus confirming the high thermal stability of Al-MHCM [46]. The morphology of Al-MHCM is clearly observed as round nanoparticles, and the appearance of the particles is mainly spherical. From the observations in Fig. 5(a)–(c), when the Si/Al ratio is 26 and the hydrothermal temperature is 90–120°C, the size distribution of Al-MHCM crystals is approximately 0.13–0.22μm. When the Si/Al ratio is increased to 41.8, the crystal size is approximately 0.11–0.40μm. At the highest Si/Al ratio (56.3), the Al-MHCM crystal size distribution is approximately 0.22–0.60μm. This phenomenon shows that the increase in hydrothermal temperature causes the crystal size to increase significantly. According to the study by Tian et al. [47] this increase in crystal size was mainly due to the increased synthesis temperature and rapid hydrolysis reaction that affected the uniformity of the generated particles [47]. In addition, Xie et al. [48] stated that the difference between products obtained by the same synthesis method was due to the formation of delayed structures due to changes in the reaction medium pH or the occurrence of uneven precipitation [48].

Fig. 5.

The SEM images of the synthesized Al-MHCM.

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Fig. 6 shows the equilibrium moisture content of Al-MHCM at different relative humidities (RH%). The solid line in Fig. 6 shows the process of water vapor adsorption, and the dotted line is the process of water vapor desorption. The results show that the equilibrium water contents of all samples increase with increasing RH%. However, there is a significant difference in the equilibrium moisture content in the material, especially when the RH% is high (RH%=75–95). Fig. 6 shows that when the Si/Al ratio is 26, the RH% of the synthesized Al-MHCM is 95%, the equilibrium moisture content is in the range of 65.20–76.60m3/m3 (Fig. 6(a)). When the Si/Al ratio is 41.8, the highest equilibrium moisture content is shown to be in the range of 81.34–91.45m3/m3 (Fig. 6(b)). In addition, when the Si/Al ratio is 56.3 and the RH% of the synthesized Al-MHCM is 95%, the equilibrium moisture content is 69.63–75.15m3/m3 (Fig. 6(c)). Rahim et al. [49] noted that the equilibrium moisture content of rape straw concrete and hemp concrete ranged from 17.8 to 9.8m3/m3 at a high RH%=95 [49]. Hu et al. [17] confirmed that more mesopores can make the material more conducive to capillary condensation and improve the moisture adsorption capacity, and the equilibrium moisture content of diatomite/ground calcium carbonate composite material was 11.7m3/m3 at RH%=98 [17]. The results confirm that the equilibrium moisture content of Al-MHCM is better than the rape straw concrete and hemp concrete (9.8–17.8m3/m3) [49], and that of a diatomite/ground calcium carbonate composite aterial (11.7m3/m3) [17]. These results show that the adsorption characteristics are closely related to the specific surface area and pore size. In the process of water vapor adsorption and desorption, the pore size of Al-MHCM is significantly related to capillary condensation [50]. According to the study of Xie et al. [48] when the effective pore size for capillary condensation was 2.93–9.09nm when temperature was 23°C and relative humidity was 33–75% [48]. This theory corresponds to the result that the pore diameters of all synthesized materials in this study were between 3 and 4nm. Therefore, the pore size distribution of the synthesized Al-MHCM was in the mesopore range, so that it can perform the most effective humidity control function. In addition, Jansen et al. [51] observed that water saturation increased with relative humidity in a relatively nonlinear manner. Furthermore, they found that the diffusion coefficient did not depend on the water concentration itself because there was no difference in the diffusion rate between adsorption and desorption [51]. It can be clearly observed that when the RH% gradually increased, the larger pores also can be filled up [48]. This result showed that the larger slopes and peaks in the isothermal equilibrium moisture content curve indicated higher moisture storage capacity, and the smallest hysteresis loop between the moisture adsorption and desorption curves indicated that the water desorption capacity was similar to the water adsorption process [52]. In addition, when the low hydrothermal synthesis temperature is 90°C, the equilibrium moisture content of Al-MHCM at RH%=95 is 73.19m3/m3, and when the hydrothermal temperature is increased to 120°C, the equilibrium moisture content increased significantly to 76.60m3/m3 (Fig. 6(a)). The adsorption-desorption curve shows a hysteresis loop. Since the inner wall of the pore is in a wet state after the loss of water during the dehumidification process, the contact angle of the water molecules on the inner wall of the pore is small, thereby delaying the desorption effect. In contrast, in the process of moisture adsorption, the inner wall of the dry pore has a better moisture adsorption effect with its large water contact angle. The above results show that the change in the Si/Al ratio exhibits no obvious difference in regard to the change in equilibrium moisture content, while an increase in the hydrothermal temperature can destroy the balance between the solid and liquid phases of the initial gel; thus, the concentration of silicate and aluminosilicate in the liquid phase results in the aggregation of silicate species on the microcell surface. Aggregation promotes the crystallization process and increased the pore structure and specific surface area of Al-MHCM. Therefore, the equilibrium moisture content gradually increased.

Fig. 6.

The 24-h equilibrium moisture content curve of the synthesized Al-MHCM. (a) Si/Al=26; (b) Si/Al=41.8; (c) Si/Al=56.3.

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