Liquid phase calorimetry and adsorption analyses of zeolite beta acidity
Literature Information
Julio Lemos de Macedo, Grace Ferreira Ghesti, José Alves Dias, Sílvia Cláudia Loureiro Dias
Zeolite beta acidity, activated at 550 °C, was characterized by calorimetric and adsorption studies of pyridine in cyclohexane (Cal–Ad). Two different acid sites were found: n1 = 0.1612 mmol g−1 with ΔH1 = −83.6 kJ mol−1; and n2 = 0.3820 mmol g−1 with ΔH2 = −62.8 kJ mol−1. Step calcinations followed by FTIR indicated n1 as Lewis sites and n2 as weak Brønsted sites. When activated at 450 °C, zeolite beta showed three different sites: n1 = 0.0467 mmol g−1 with ΔH1 = −227.3 kJ mol−1; n2 = 0.1163 mmol g−1 with ΔH2 = −93.3 kJ mol−1; and n3 = 0.3322 mmol g−1 with ΔH3 = −80.4 kJ mol−1. Sites n1 and n2 were assigned as Brønsted centers, while n3 as a combination of Brønsted and Lewis sites. These results suggest that the zeolite beta strongest Brønsted sites are converted to Lewis sites at 550 °C. These Lewis sites are not only related to extra-framework Al species, but also to aluminium atoms partially bonded to the zeolite framework, as evidenced by infrared bands at 3777 and 875 cm−1. FTIR and thermogravimetric analyses of gas phase adsorbed pyridine were also used to investigate the materials acidity and a good agreement was found with Cal–Ad data. The results showed that the Cal–Ad method offers a more detailed description of the zeolite surface acidity by providing thermodynamic parameters not easily obtained by other techniques. A linear relationship between enthalpy and entropy values for several zeolites (ZSM-5, TS-1, MOR, Y and BEA) is also reported.
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DOI: 10.1039/B001766N
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