However, a fraction of the organic

However, a fraction of the organic Fulvestrant components could be retained by the alumina surface, as will be discussed below. The “plateau” observed above 550 °C in the TG curve indicated that a stable phase had been formed. The dehydroxylation of boehmite (AlOOH) to γ-Al2O3 is known to occur at temperatures higher than 300 °C, and is accompanied by a theoretical weight loss of 15%.

The observed weight loss at 300–600 °C (28.16%) for the as-synthesized sample was significantly higher than the theoretical value. This can be attributed to the weight loss by decomposition of the rosin-boehmite complex formed in the synthesis medium, in addition to the dehydroxylation of boehmite to γ-alumina. X-ray diffraction patterns corresponding to the as-synthesized sample and pure boehmite (JCPDS Card 21-1307) are presented in Fig. 5(A and B). The as-synthesized sample dried at 80 °C showed some broad and weak peaks in positions that confirm the presence of FK228 the boehmite phase, prior to the formation of the γ-phase. Typical TEM images of the products after calcination at 650 °C are shown in Fig. 6. As can be observed, the sample mainly contains elongated nanoparticles with sizes smaller than 10 nanometers. On the other hand, the presence of aggregates of nanoparticles forming voids spaces or pores in the material is observed. In general, when aluminum alkoxides are hydrolyzed with controlled amounts of water, two

reactions can occur [19], [20], [21] and [22]: Al(OR)3+3H2O→Al(OH)3+3ROHAl(OR)3+3H2O→Al(OH)3+3ROH Al(OR)3+2H2O→AlOOH+3ROHAl(OR)3+2H2O→AlOOH+3ROH As it can be observed, the amount of water added is critical, if three moles or more of water are added to one mole of aluminium isopropoxide, one mole of aluminium hydroxide is formed and three Erastin moles of isopropanol

are liberated. Under the present experimental conditions, in water excess, different interactions may exist. These could be generated between the aluminum hydroxide surface and the resin acid, as the following reaction proceeds: [Al(O)(OH)]n→HO2CR[Al(O)x(OH)y(O2CR)z]n The carboxylate ligand is covalently bound to the aluminum surface. The resulted material is known as carboxylate-alumoxane. The alumoxanes are chemically functionalized nanoparticles and may be selectively prepared with a particle size of 5–150 nm depending on the identity of the organic substituents and the processing conditions, this is removed only under extreme conditions [4], [5], [6] and [7]. In this way, three possible coordination modes of the carboxylate ligands and aluminum ions on the surface of boehmite may occur [4], among which the linkage to two Al atoms seems to be the most stable mode (Fig. 7). Thus, carboxylates get bonded to the surface of boehmite mostly via this mode. The reason for more stability of this mode of linkage is the formation of six-membered rings which are stabilized through resonance [4] and [23].

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