Results and discussion The composit

Results and discussion
The composite materials characterized in this study were those prepared at a temperature of 500 °C, which were denoted as AC85 and AC50, with percentages of 85 % and 50 % of clay, respectively. The choice of these composites for the characterization studies was due the lower activate temperature used during preparation and the best efficiency on adsorption of methylene blue dye. Composite samples and their precursor´s materials (Argel100 and Charcoal100) were characterized by X-ray diffraction (Figure 1). It can be observed that the materials have a peak at approximately 2θ = 7.0o, indicating that they are layered material of the montmorillonite clay type. After activated of the materials at 500 °C, a change in the diffraction peaks was observed for the composites AC85 e AC50 in relation to the clay Argel100, for low angles. This displacement suggests an increase in the interlamellar (d001) spacing due to the process of intercalation of the charcoal between the layers of clay. It was observed that the d001 for A100 as . Ǻ peak ; hile for the oposites the spaig as . Ǻ for AC85 ad . Ǻ for AC50.14 Therefore, this interlamellar spacing is more pronounced for the composites when compared with the Argel clay. It was also noted that Argel100 possessed a 2θ peak at approximately 14.58 Ǻ, hih as ot preset for the oposites, suggesting the presence of charcoal in the composites.15-16 Studies performed by Rodrigues et al. (2004) with organoclay nanocomposites/rubber presented an increase in basal clay mineral distances showing interleaving of quaternary ammonium cations. This is in agreement with the observations verified for composites studied in this work, with incorporation of charcoal in clay structure.16-17 Thermogravimetric analysis (TG/DTG) was used to evaluate the thermal properties of the materials. Figure 2c and 2d exhibits curves responding to loss of mass for the AC85 and AC50 composites, respectively. It can be observed that the DTG curve obtained for the AC85 composite (Figure 2c) shows four events with a total loss of mass of approximately 15.4 % of the initial mass. The first mass loss equal to 5.4 % (between 40 and 200 °C) is attributed to the evaporation of 1.14 hydration or weak-bonded water molecules, for the AC85 composite) and 2.7 molecules of weak-bonded water for the composite AC50. This probably occurs due to the presence of montmorillonite that exhibits the first region of loss of mass between 40 and 200 °C, corresponding to water elimination. The event can be attributed to the volatilization of weak-bonded water, present on the surface of the agglomerates and between the aggregates. The second mass loss occurs between 200 and 550 °C and is related to the volatilization of solvation water (interlamellar), which is more strongly bonded. The third mass loss, between 500 and 700 °C, is related to the loss of structural hydroxyls, and it can be noted that events above 750 °C are present in all composites, showing a decomposition of the oxides present in the sample. Figure 2a and 2b shows the mass loss events for the precursors Charcoal100 and Argel100.1