US EPA

1947130 

Journal Article 

Interaction of benzene with hydroxyl groups in zeolites: An FTIR study of C6H6 and C6D6 adsorption on H-ZSM-5 and D-ZSM-5 

Chakarova, K; Hadjiivanov, K 

2011 

1 

Microporous and Mesoporous Materials
ISSN: 1387-1811 

143 

1 

180-188 

10.1016/j.micromeso.2011.02.025 

WOS:000291524700024 

Adsorption of benzene on H-ZSM-5 leads, at low coverages, mainly to formation of 1:1 adducts with the zeolite bridging hydroxyl groups (3612 cm(-1)). As a result, the O-H modes are shifted to two discrete bands with maxima at ca. 3350 and 3250 cm(-1). The appearance of two bands is attributed to Fermi resonance of the shifted O-H stretchings with the 3 delta(OH) modes. Small amounts of benzene molecules interacting simultaneously with two hydroxyls are also observed. At high benzene coverages ordered structures are formed. As a result, the shifted band appears at 3175 cm(-1), a value misleading to overestimated acidity. In addition, a part of benzene with time turns bonded to bridging OH groups via hydrogen atoms thus producing another shifted band at ca. 3500 cm(-1). Small amount of Al-OH species were also present (band at 3663 cm(-1)). It was concluded that the O-H stretchings of these groups were shifted by ca. 225 cm(-1) upon benzene adsorption. Silanol groups (3745-3700 cm(-1)) are heterogeneous and produce two shifted bands at 3625 and 3585 cm(-1).



Adsorption of C6D6 leads to similar results. The shifted O-H bands coincide in position with those produced by adsorption of C6H6. In this case, however, D-H exchange of the bridging OH groups easily occurs. The C6D6-induced shift of the O-D modes of the bridging deuteroxyls is lower than expected taking into account the H-D isotopic shift factor. In addition, the ratio between the intensities of the two bands and the split value also differ. These results confirm the occurrence of Fermi resonance. (C) 2011 Elsevier Inc. All rights reserved. 

Adsorption; Benzene; C6D6; H-ZSM-5; FTIR spectroscopy