Poly(melamine-formaldehyde-silica) Composite Hydrogel for Methylene Blue Removal

aUniversidade Federal do Piauí, Programa de Pós-Graduação em Ciência e Engenharia dos Materiais, Campus Ministro Petrônio Portella, CEP 64049-550, Teresina, PI, Brasil bInstituto Federal do Piauí, Campus Parnaíba, Avenida Monsenhor Antônio Sampaio, s/n. Bairro Dirceu Arcoverde, CEP 64211-145, Parnaíba, PI, Brasil cUniversidade Federal do Piauí, Departamento de Química, Campus Ministro Petrônio Portella, CEP 64049-550, Teresina, PI, Brasil dUniversidade Federal do Piauí, Departamento de Física, Campus Ministro Petrônio Portella, CEP 64049-550, Teresina, PI, Brasil


Introduction
Hydrogels are composed of three-dimensional (3-D) insoluble polymer materials containing hydrophilic groups (modified or synthetic), capable of absorbing and retaining a considerable amount of water due to their morphological expansion [1][2][3] . The increasing hydrogels synthesis methods aim to supply the demand for biocompatible materials and adequate for use in different applications such as pollutant removal, development of medicines, cosmetics, hygiene, and agricultural products 2,3 . Hydrogels are demanded because they present unique properties that account for biodegradability, biocompatibility, low-cost, facile synthesis, renewability, and excellent hydrophilicity [4][5][6][7] .
The use of polymers in the synthesis of hydrogels aims to increase hydrophilic capacity 4 . Poly(N-isopropyl acrylamide) 8 , poly(ethylene glycol) 9 , poly(vinyl alcohol) 10 , poly(cellulose/chitosan) 11 , and polyurethane 12 are examples of polymers extensively used in hydrogel fabrication. These polymers have in common hydroxyl and nitrogen groups capable of establishing hydrogen or van der Waals bonds through their structures, enabling them to absorb significant amounts of water 4 .
Poly-melamine-formaldehyde (PMF) polymer exhibits advantages that allow its use in hydrogels synthesis because of its large amounts of nitrogen, high resistance to chemical attack, and low-cost of production 13 . Besides, PMF offers a comprehensive 3-D structure that can be easily broken down; it can be applied in liquid filtration, sound, thermal and electrical insulation, development of components for construction industries, packages, high-quality laminated surfaces, fire retardant, heavy metal removal, dyes adsorption, etc [14][15][16][17] . The methylol monomers exhibit attractive properties like low molar weight and up to 9 different possibilities of intermolecular interactions comprising 6 hydroxyl groups and 3 nitrogen atoms 18 . The numerous possible points of interaction make PMF suitable for hydrogel fabrication 13 .

Sodium silicate purification
Unpurified sodium silicate solution (also containing 22.66 wt.% of water, 9.2 wt.% of sodium hydroxide, and 0.8 wt.% of iron) was purchased in a local city market in Teresina-PI, Brazil. We purified the sodium silicate material before using it in later stages. The previous purification procedure is recommended for impurity removal, such as iron ions. We used hydrochloric acid to solubilize iron precipitates forming their ions. The silica purification process consisted of using 200 g (120 mL) of the commercial sodium silicate solution diluted to 1 L of deionized water at 25 °C. Then, 28 mL of concentrated hydrochloric acid (Vetec 32%) was added dropwise while the solution was being stirred.
The purified sodium silicate solution was stoked for posterior use in the hydrogel formation to form Si-NPs.

Melamine-formaldehyde polymer synthesis
We have conducted the synthesis of PMF according to the work of Merline et al. 55 . The reaction between melamine and formaldehyde took place at a molar ratio of 1:3, and the polymerization mechanism of melamine-formaldehyde resin is known from the literature 55 . The initial procedure consisted of the dissolution of 1.5 g of melamine (SigmaAldrich 99%) in 25 mL of deionized water (18.2 MΩ.cm) in an open system. The solution was stirred and heated at 70 °C, followed by the addition of 3 mL of formaldehyde (Merk 38%), and kept under agitation to complete the PMF formation. The shift of white color to a translucid solution indicated that the reaction had happened. Later, we maintained the system with the exact condition of stirring and heating, and 30 mL of glycerin (Vetec 99.5%) was added and stirred for another 10 min. The glycerin consists of a source of hydroxyl groups to the system, which is susceptible to make hydrogen bonds allowing the formation of a structure capable of absorbing large amounts of water. Therefore, the final solution consists of the mixture of the PMF and glycerin used in the hydrogel synthesis.

Hydrogel synthesis
The silicate in acid medium forms hydrogels with Si-NPs and, depending on the proportion between siloxane (Si-O-Si) and silane (Si-OH) groups, and it can have more or less hydrophilic character 56,57 . The PMF provides the composite sustainment because it is a fibrous structure, one of the most important findings in this work. 280 mL of the previously prepared sodium silicate solution (274 g/L) was added in a beaker with 670 mL of deionized water, as described in section 2.1. The diluted sodium silicate solution was heated to 70 °C and kept under stirring. Then, we added the previously prepared PMF-glycerin solution, as described in the previous section. After adding the PMF-glycerin solution, the mixture was stirred for 5 min, followed by the dropwise addition of 10 mL of concentrated acetic acid (Vetec 99.5%) to allow the formation of Si-NPs in the hydrogel. After the addition of acetic acid, we found the hydrogel pH = 7.5. Figure 1a represents the stages of formation of the PMF-glycerin resin, while Figure 1b shows the formation of the PMF-Si composite. The original hydration of the PMF-Si composite was 93%, determined after the preparation procedure.

Material characterizations
The synthesized hydrogel PMF-Si was submitted contact per time 48 h with sulfuric acid (4.5 mol/L), nitric acid (4 mol/L), phosphoric acid (4 mol/L), methyl alcohol, ethyl alcohol, acetylene, and benzene solutions at 25 °C. However, the viscosity, the white color, solubility in water, the ability to not ignite, and the low water loss rate remained stable. We performed the physicochemical characterizations of the obtained materials by using several techniques: X-ray diffraction (XRD), Fourier transform infrared (FTIR), scanning electron microscopy (SEM), transmission electron microscopy (TEM), atomic force microscopy (AFM), thermogravimetric analysis (TGA); and humidity rate determination. We took the XRD measurements in a Bruker D8 Discover diffractometer and used a tube with a copper anode coupled to a Johansson monochromator for Kα 1 operating at 40 kV and 40 mA in the 2θ interval ranging from 5º to 80º for carrying out the analysis. The FTIR analyses of the materials were performed in KBr (3 wt% of the sample contents) in the region from 4000 cm -1 to 400 cm -1 , with 16 scans and 4 cm -1 resolution, using a PerkinElmer equipment, model FTIR Spectrum 100. After the sample was fixed on a brass sample holder and covered with a thin gold film, we obtained SEM images to make the material's surface conductive. The images were acquired with a JEOL microscopy, model JSM-IT300, in high vacuum with the secondary electrons detector and electron acceleration voltage ranging from 5 to 15 kV. We carried out TEM analyzes in JEOL equipment, model JEM-2100, with a voltage of 200 kV. We dispersed the samples in hexane for 15 min and then subjected them to a low-frequency ultrasound bath. An aliquot of the obtained dispersion was dripped onto the copper grid covered with carbon and dried. We obtained AFM images with NTMDT AFM equipment in intermittent contact mode. Three different areas of the samples were analyzed. We performed TGA analysis using thermogravimetric equipment from TA Instruments, model SDT Q600 V20.9 Build 20, using an inert Argon atmosphere, with a 100 mL/min flow rate, a heating ratio of 10 °C/min, and temperature ranging from 10 to 1000 °C. The hydrogel's maximum hydration capacity and its rehydration performance were studied using a thermobalance Bel iThermo instrument, model 163L, with a fixed temperature at 65 °C and room temperature at 24 °C, respectively.

Dehydration and rehydration of PMF-Si hydrogel
The tests of hydrogel dehydration and rehydration were determined using a digital thermobalance. The dehydration tests were carried out with the sample heating at 65 ºC for 5 h. The initial hydrogel weight (water + PMF-Si composite) used to calculate the dehydration percentage was ~10 g in all tests. We performed the rehydration experiments from samples dehydrated from 10 g of hydrogel to lose 70, 75, 80, 85, and 90% in mass at 65 °C. After reaching these mass-loss percentages, we hydrated the samples with the same mass of water lost. The system was then heated to remove the excess of water up to see just the hydrogel phase. We used the final mass of the heated system to calculate the percentage of rehydration. All experiments were performed in triplicate.

MB removal
We evaluated the adsorption of MB (Vetec) on PMF-Si composite by batches containing 1 g of hydrogel (72 mg of dry PMF-Si) in contact with 10 mL (10-1500 mg/L) of MB solution under stirring at 4000 rpm, for 10 min, at 25 °C 58-60 . We performed contact time, pH variation, and hydrogel reuse tests at the MB concentration of 50 mg/L. The concentration MB was determined from the absorbance values at 664 nm, using a Genesys UV-Vis spectrophotometer model 10S. We analyzed the solutions at different exposure times ranging from 5 to 120 min to elucidate MB's kinetic adsorption response on the hydrogel. The data was used to perform the adsorption isotherm where it was determined the adsorption capacity, q e (mg/g), indicating the amount of adsorbed MB dye per amount of dry adsorbent using Equation 3: where V is the solution volume (L), o C is the initial MB concentration (mg/L), e C is the equilibrium concentration (mg/L) of MB, and m the adsorbent mass (g).
The potential of zero charge (PZC) of the composite PMF-Si was determined using the HORIBA SZ-100 equipment. Seven suspensions (1% w/v) were produced in 0.01 mol/L KCl solution, varying the pH from 1-7. We used HCl and NaOH solutions to control the average pH. The suspensions were stirred for 12 h, maintained for another 12 h at 25 °C, and then PZC measurements were made with the supernatant. We evaluated the hydrogel's adsorption capacity for MB removal by varying the pH between 1 and 12. The tests were performed with 1 g of the hydrogel hydrated, 10 mL of MB at a concentration of 50 mg/L, and a temperature of 25 °C. All experiences were done in triplicate.

Evaluation of hydrogel reuse
We performed the hydrogel reuse tests on MB dye adsorption using 1 g of hydrogel and 10 mL of 50 mg/L MB solution at 25 °C temperature. The dye's desorption was done by adding 7 mL of 1 mol/L HCl solution, and the contact time was 20 min. After treatment with an acid solution, we performed 4 washing cycles with 12 mL of deionized water. Centrifugation of the solution at 4000 rpm for 10 min was used to remove the acid and water. The MB concentration was determined from absorbance values at 664 nm using a Genesys UV-Vis model 10S spectrophotometer. Figure 2 shows the FTIR spectra for melamine, PMF, and PMF-Si materials. The infrared spectrum of melamine is presented in Figure 2a, and the founded bands are similar to the one found by Ali et al. 61 . Bands at 3470 cm -1 and 3419 cm -1 are attributed to the asymmetric stretching of the NH 2 group, and two large bands at 3333 cm -1 and 3132 cm -1 are attributed to the symmetric elongation and vibrational bending of primary amine 16,55 . The bands at 1655, 1555, 1469, and 1439 cm -1 belong to the stretching of C=N bonds present in the ring of 1,3,5triazine of melamine 61,62 . The band at 814 cm -1 is assigned to the vibrational bending of the ring in 1,3,5-triazine of melamine 55,63 . The band located at 1198 cm -1 is ascribed to the C-N bond stretching at primary amine 62 . PMF, Figure 2b, showed that the primary amine present in melamine has disappeared. The formation of broadband at 3336 cm -1 is attributed to hydroxyl groups' stretching vibration and demonstrates that melamine and formaldehyde are reticulated in the PMF resin 16 . The band around 2956 cm -1 is assigned to the stretch of primary carbon bonds, which is absent in neat melamine and occurs in PMF due to the reaction between melamine and formaldehyde 64 . We observed the methylene stretches (CH 2 ) at 1489 cm -165 . The band located at 1155 cm -1 is ascribed to the lengthening of CO bonds 65 and the band at 1061 cm -1 is attributed to an effect of the lengthening vibration of ether groups 55 . Bands localized at 1565, 1489, and 810 cm -1 are attributed to the melamine rings' vibration 24 . The band at 1330 cm -1 derives from the symmetrical stretch deformation of CN bonds 66 . Figure 2c shows the spectrum of the PMF-Si composite. The intense and wideband at 3340 cm -1 is due to the stretch vibration of OH of silanol groups in the PMF-Si composite structure, and possibly also due to the presence of residual water, being a consequence of its high hydrophilic character 67 .

Fourier transform infrared spectroscopy
Furthermore, the composite has free and encapsulated silanol groups due to the incorporation of Si-NPs into the PMF, Figure 1b. The band at 2943 cm -1 is assigned to the symmetrical stretch of the CH bond 16,64 . The band at 1565 cm -1 founded in the PMF is attributed to the vibration of melamine rings, and its displacement to 1571 cm -1 in the PMF-Si spectrum reveals an interaction between silanol groups, from silica, and rings of melamine structure 24 . The band at 1050 cm -1 results from the C-O stretch of glycol, demonstrating OH groups' presence stemming from glycerin 68 . The band at 924 cm -1 corresponds to the asymmetric stretching of Si-OH groups. The bands at 1111 and 786 cm -1 indicate symmetrical extension, while the band at 471 cm -1 indicates asymmetrical stretching of Si-O-Si and O-Si-O groups, respectively. Those groups are present in silica belonging to the PMF-Si composite. Those groups account for hydrophilic property, which contributes to water retention by the hydrogel, demonstrating the successful formation of the PMF-Si composite 69-72 . Figure 3 shows diffractograms acquired for melamine, SiO 2 , PMF, and PMF-Si composite in the 2θ interval ranging from 6 to 80º. Melamine displayed a well-defined crystalline profile with peaks between 15º and 45º. The founded peaks at 17.4, 20.6, 25.3, 30.6, 31.6, 33.6, 34.8, and 44.9° follow the literature, corresponding to the melamine crystallographic profile 73 . In opposition, PMF displayed an amorphous structure, indicating no crystalline contribution from melamine in the polymer structure. PMF showed a typical prominent peak located at 13.1º and 27.4º, indicating that melamine reacted with formaldehyde to form methylol monomers and, consequently, the growth of the PMF structure happened 16 .

XRD of melamine, SiO 2 , PMF, and PMF-Si composite
The purified silica material exhibited a typical amorphous structure with a distinguished peak centered at 22.6º 74,75 . PMF-Si composite also exhibited an amorphous profile and did not show the central peak at 27.4º, as it happened with PMF. Then, the PMF-Si composite structure is dependent on the amorphous silica addition. PMF-Si composite showed two new peaks centered at 9.3º and 22.2º because of interactions between PMF and Si-NPs. The peak centered at 9.3° must be attributed to the displacement of the peak assigned to the PMF centered at 13.1°. We believe that the same situation may have occurred with the peak centered at 22.2° attributed to the PMF-Si composite, contributing from peaks related to silica and PMF, located at 22.6° and 27.4°, respectively. Note that a significant change in the PMF morphology occurs when Si-NPs are embedded in its structure. This change is responsible for increasing the water absorption capacity in the PMF-Si composite.

Microscopy analysis
We performed a microscopy examination to acquire SEM, TEM, and AFM images to get an insight into the morphological structure of the synthesized materials. Figure 4 exhibits SEM images of neat melamine, silica, PMF, and  dry PMF-Si composite. Figure 4a shows the melamine morphology consisting of white-color crystalline agglomerates in solid-state at 25 ºC 63,76 . Figure 4b shows the purified silica precipitates presenting a cauliflower-like morphological appearance, representing an amorphous material, and agrees with the XRD spectrum shown in Figure 3. The amorphous silica profile was also verified in other studies 76,77 . Figure 4c shows the PMF morphology with a sponge-like porous structure. This arrangement is like the PMF images obtained by Schwarz and Weber 28 . In opposition, Figure 4d demonstrates that the dry PMF-Si composite presents a distinct structure compared to its precursors and resembling dehydrated human skin.
We obtained TEM images for silica and dry PMF-Si composite, Figure 5. Figure 5a shows the silica microparticles with a diameter of about ~0.45 µm. The silica microparticles are interconnected and forming an elongated agglomerate due to its high active surface and elevated density of silanol groups, which is typical of amorphous silica material in agreement with the results already examined 27 . Figure 5b displays the Si-NPs homogeneously distributed within the PMF matrix. The presence of no agglomerated and welldistributed Si-NPs within the PMF-Si composite contributes to achieving better stability and water absorption capability by the hydrogel. From Figure 5b, we determined the Si-NPs diameter using the software ImageJ. These Si-NPs exhibited an average diameter between 10 to 15 nm, as shown in Figure 6. The used precursor concentration of the Si-NPs avoided particle agglomeration, being a positive result for the PMF-Si composite 28 .
Figures 5c and d display the PMF-Si composite morphology. In the lower-left part of Figure 5c, fibers are spaced in the dry composite where large amounts of water can be confined by hydration. In the central region of the same image, fibers are close to each other, featuring an area where a large amount of water was removed from the composite. Figure 5d shows another region in which the PMF-Si composite has a circular geometry, and the fibrous structure is spread out in a 3D network that resembles a sponge structure. In the hydrogel dehydrating process, the PMF-Si composite shows a dense aspect of fibers. Cross-link bonds also characterize PMF. When re-hydrated, the polymer chains pull away, serving as structural support to achieve maximum water absorption. The supplied TEM images demonstrated that the PMF-Si composite consists of fibers and Si-NPs responsible for improved water absorption capacity.
We obtained AFM images of the PMF to better observe the polymer fibers' morphological aspect, Figure 7. We prepared PMF film by adding 5 mL of the PMF solution on a Petri dish to obtain the images. The sample was heated at 60 ºC in an oven for 24 h to form the polymer film. Then, the film was removed from the plate, cut, and submitted to AFM analysis. The images were acquired in different areas of the film. In these images, we can see the disposal of the fibers in vertical disposal. The fibers are spread all over the film and present an average diameter between 1 and 0.5 μm. Figure 7a shows dendrimers' formation in the fibers' terminal positions, which suggest possible separation and forming of new thinner fibers after water absorption forming the hydrogel. The polymer film also shows the fibers juxtaposed, different from what happens when the fibers are inside the hydrogel. In the hydrogel, the polymer fibers are separated to maximize water absorption. The AFM images confirm that the PMF constitutes fibers that promote structural reinforcement to the hydrogel, allowing its stability. Liao et al. 10 also observed the fibrous structure of PMF. Figure 7c is an interfacial approximation between PMF fibers and reveals a phase's presence, apparently, distant from the fibers, occurring at their edges. We believe that is because the fibers become thicker, characterized as a PMF residue that could make the fiber thicker if the polymerization process were continued. It was not possible to perform the AFM images of the PMF-Si composite. The operational impediment is due to the high hydrophilic nature that does not allow the composite fixation for analysis.  Table 1 summarizes the main events from the thermogravimetric results for the materials mentioned above. Figure 8a shows the melamine thermogravimetric profile with a unique event situated between 220 to 356 ºC, without any residue remaining, consistent with the literature 78 , which corresponds to the melamine decomposition. TG and DTG curves of PMF, Figure 8b, exhibited three events related to its thermal properties. The first event occurred between 29 and 325 °C associated with polymer dehydration and decomposition of small precursor molecules of PMF synthesis.

Thermogravimetric analysis
The second event occurred between 362 and 416 °C, demonstrating that the PMF suffered decomposition of less-dense morphological structures such as the residue of    PMF embedded on the surface of the fibers and major of the fibers that presented small diameter, which was previously discussed in Figure 7c. The third event occurred between 420 and 935 °C, attributed to the decomposition of the most compacted PMF structure and thicker fibers. The 10% of residual mass from the PMF decomposition is composed of carbon ashes 64 . The TG and DTG curves of silica, Figure 8c, revealed two relevant events, partly superimposed. The first event located between 48 and 115 ºC is attributed to the silica dehydration, followed by a second event related to the thermal decomposition of residual organic compounds, e.g., acetic acid, used in the silica synthesis, which extends to ~660 °C. It is possible to verify a high residual content (~87%) characterizing silica content free of water and organic matter. Figure 8d presents the TG and DTG curves of the dry hydrogel containing PMF-Si composite. The curve reveals the occurrence of four relevant events associated with composite dehydration and its thermal decomposition. The first one is attributed to the dehydration process located between 43 to 126 ºC with a mass-loss percentile of ~10%. Although the hydrogel was previously dehydrated at 60 °C for 24 h, its highly hygroscopic nature allowed water absorption, even using a dehumidified storage protocol. The second event between 126 and 282 °C had a mass-loss percentile of ~20% and corresponds to the organic compounds from silica synthesis. The third event occurred between 282 and 418 °C, attributed to the glycerin evaporation, which has a boiling point of 290 °C and presented a mass-loss percentile of about ~17%. The fourth and last event occurred between 418 and 525 °C, attributed to the PMF fibers' thermal decomposition, which presented a mass-loss percentile of ~11%. The residue from the PMF-Si composite decomposition is due to the Si-NPs and the carbonized organic matter corresponding to ~42%. From the results revealed here, it is possible to conclude that the PMF-Si composite presents a compatible thermal behavior with its composition, showing a series of thermal events associated with the dehydrated hydrogel's content. TG and DTG analyzes indicate that the PMF-Si composite is less stable than the PMF. That is because the fibers in the PMF-Si composite allowed a better material dispersion and, possibly, due to the segregation of thick fibers into thinner fibers while the composite is hydrated. Besides, the presence of Si-NPs favored the dispersion of the PMF fibers benefiting hydrogel stability.

Dehydration and rehydration results
The dehydration tests showed substantial water loss in the first two hours of heating at 65 °C representing a decrease in water content of approximately 80%, as shown in Figure 9a. The hydrogel dehydration reached ~0.728 g after 4 h of heating and remained constant for an extra 1 h.
The rehydration performance seriously affects the hydrogel's properties, a critical issue in its practical applications 79 . From Figure 9b, the hydrogel achieves complete rehydration even after reaching 70% of dehydration. Hydrogel dehydration below 70% also showed complete rehydration. We found that weight loss of up to 70% characterizes the hydrogel's reversibility returning to its original water contents. When we increased the hydrogel dehydration to 90%, its rehydration capacity considerably decreases, such that when dehydrating the hydrogel by 90%, rehydration is about ~30%. The success in hydrogel rehydration (maximum dehydration is up to 70%) is due to its excellent hydrophilic properties. Rehydration is possible because the silanol groups (2 ≡ Si−OH → ≡ Si − O −Si ≡ + H 2 O) and hydroxyl groups (Figure 1) are present on the PMF-Si composite surface and between its mesopores structure (Figure 4c), allowing the hydrogel to recover most of the original volume of water through the return effect 80 . The practical consequence of the facile hydrogel rehydration is attributed to the stabler Si-NPs adsorbed on the PMF structure.

Potential of zero charge and methylene blue removal
The Potential of zero charge (PZC) of the composite occurred at pH = 1.22, as shown in Figure 10a. At MB solution and pH below the PZC, the composite surface is positively charged, and at pH higher than the PZC, the composite surface is negatively charged 81 . Therefore, there is a reduced MB adsorption capacity when the pH is lower than PZC, and this is due to the composite having a positive potential on its surface when the pH is lower than 1.22 (see Figure 10b). However, when the pH is higher than 1.22, the PMF-Si composite surface becomes negative and electrostatic attraction occurs easier with the cationic MB dye molecules. The adsorption by hydrogen interaction justifies that even at lower pH than PZC, the PMF-Si shows an adsorption process.
MB adsorption mechanism on Si-NPs is by electrostatic forces and hydrogen interactions on the silane groups 82,83 since MB is positively charged and has amine groups 81,84 . Figure 11 shows a scheme of how adsorption of MB on silane groups can occur. The model shows the interfacial interaction arising from the silanolate groups' interactions (Si-O-) derived from silicate, and silane groups, with MB dye because of hydrogen interactions.
The adsorption of methylene blue dye is affected by pH variation 85 . The MB in aqueous solutions is presented in the form of positively charged ions (cationic dye), and its adsorption degree is influenced by the surface charge of the adsorbent, which has its value modified according to the pH variation of the medium 86 . The pH can cause functional groups' desorption on the adsorbent's active sites and changes in the surface charge of the adsorbent 87 . The adsorption capacity of MB on PMF-Si increased at pH higher than 2, agreeing with PZC, Figure 10a, and reached stability in the pH range between 4-9. At a pH higher than 9, there is an increase in the adsorption capacity of MB 88 .
The calibration curve from the samples containing different MB dye concentrations in the hydrogel was acquired, Figure 12a. A linear correlation between the absorbance of the samples and the residual dye concentration in the hydrogel is represented by the equation y = 0.1844x + 0.0078, with an R 2 = 0.99946. The accurate adjustment allowed us to calculate the final MB dye concentration of a different solution using the equation mentioned above. Figure 12b shows the contact time between the MB dye and PMF-Si hydrogel and displays the associated dye removal percentage. The curve indicates the maximum MB dye removal percentage reached 96% with a short contact time of 5 min. Figure 12b also suggests a rapid interaction between the MB dye and the hydrogel. Although the percentage of dye removal continues to increase with the contact time, its increase is not significant, although it allows for additional removal with a contact time of 90 min. Therefore, we achieved a short adsorption time of the dye removal by PMF-Si, which is a relevant result. The high dye removal percentage with a short adsorption time makes MB dye removal by PMF-Si hydrogel a versatile method for practical applications.
Langmuir model was used to fit the absorption data analysis of MB dye in hydrogel samples. This model comprises a  defined number of active sites and the occurrence of monolayer adsorption on a homogeneous surface 89,90 . The isothermal curve showed in Figure 13 follows the Langmuir adsorption model. The curve's shape indicates no competition between the solvent and the adsorbate, which means the PMF-Si hydrogel is a potential adsorbent of MB dye.
We calculated the adsorption capacity using Equation 4: where q max represents the theoretical maximum adsorption capacity in mg/g, e C is the concentration at the equilibrium in mg/L, and is the Langmuir's constant in L/mg 91 . The adsorption curve (Figure 13) reveals that the hydrogel has a maximum MB dye adsorption capacity of around 140 mg/g and a Langmuir's constant of about 3.16 × 10 3 L/mg. The calculated MB dye adsorption capacity value is higher than the ones reported for other materials such as rice hulls (~40 mg/g) 92 , clay (~72 mg/g) 93 , waste activated carbon (~15 mg/g) 81 , MCM-41/chondroitin sulfate hybrid hydrogels (~123 mg/g) 94 , polyvinyl alcohol/acrylic acid/poly4styrene sulphonic acid hydrogel (~131 mg/g) 95 . The PMF-Si hydrogel synthesized by Schwarz and Weber used commercial Si-NPs and exhibited an MB dye adsorption capacity of ~812 mg/g 13 . In our study, Si-NPs were formed in the hydrogel synthesis process, while Schwarz and Weber used commercial Si-NPs. The hydroxylated surface of the PMF-Si composite provided by silanol groups accounted for the strong interaction between the hydrogel and MB dye molecules. Therefore, PMF-Si hydrogel for MB dye removal should be encouraged since it is an effective and inexpensive strategy. Figure 14 displays the adsorption capacity of the hydrogel after successive reuse cycles. The process of removing MB from the PMF-Si hydrogel's surface, in its reuse, occurs by adding 1 mol/L HCl solution, followed by washes with deionized water until pH = 6 is reached. The strategy of lowering the pH to remove MB from the composite surface is because, at pH values below the PZC, there is desorption of many dye molecules. The adsorption capacity of PMF-Si gradually decreased from 92% to 42% after 7 adsorption cycles. The washing process justifies the decrease in adsorption capacity with the HCl solution. The low pH promotes a reduction in the silica surface's negative charge density,   making the material less MB adsorbent 88 . Another factor to consider is the loss of Si-NPs during successive washing cycles. Therefore, the indication of PMF-Si hydrogel's use for MB removal is a viable alternative since the materials have a low-cost, and the synthesis is simplified.

Conclusions
We successfully synthesized PMF-Si composite to form a hydrogel with promising properties for several applications (dye adsorbent, agriculture, fire-retardant, etc.). Thermal analysis implied that the PMF-Si composite presents a stable structure with well-defined stages of decomposition. The Si-NPs were obtained from purified sodium silicate and exhibited similar properties to the commercial Si-NPs, making this study an alternative for preparing quality and low-cost Si-NPs for hydrogel fabrication. The synthesized PMF-Si composite displayed fibrous structure provided by PMF, responsible for the hydrogel structural support. The Si-NPs showed a diameter between 10 and 15 nm helped to improve the water absorption capacity. The intrinsic PMF-Si composite hydration reached a maximum of 93 wt% of water. Complete rehydration is only possible when the maximum mass loss of water reaches 70 wt%. The composite showed PZC at pH = 1.22, which means that its structure at pH higher than 1.22 is negatively charged, and electrostatic forces occur with the cationic MB dye molecules. The MB dye adsorption capacity, q max = 140 mg/g, was higher than other materials routinely used for MB dye removal, demonstrating that the PMF-Si hydrogel can be used to remove MB dye and possibly other dyes. Although the adsorption capacity of PMF-Si gradually decreased from 92% to 42% after 7 adsorption cycles, the composite is low-cost, which makes viable its use for MB adsorption proposal.

Acknowledgments
This study was financed in parts by the Coordenação de Aperfeiçoamento de Pessoal de Nível Superior -Brasil (CAPES) -Finance Code 001.