IntroductionRecently, higher concer

Introduction
Recently, higher concerns have been raised about the control of pollutants like volatile organic compounds (VOCs) mainly due to the more strictly environmental regulations on several countries [1,2]. VOCs involve a wide range of different compounds, such as oxygenates (alcohols, aldehydes, ketonas), aromatic hydrocarbons and halogen hydrocarbons [3]. The catalytic oxidation is an effective technology for removal of VOCs, presenting several advantages over absorption or thermal incineration processes [4,5]. However, the catalytic destruction of VOCs exhibit specific problems characteristic of these processes, such as low concentrations of VOCs in the feed stream; complex composition of the mixture of VOCs in the feed and high space velocities [6]. Therefore, the development of catalysts for oxidation of a particular mixture of VOCs is an important task. Benzene is a VOC present in different industries, such as petrochemical (benzene alkylation to ethyl benzene; reaction of benzene and long chain olefins to produce linear alkyl benzene; toluene disproportionation to benzene and xylenes; naphtha aromatization to benzene); paint and coating industries and steel manufacture. In the literature, several catalysts have been used for the total oxidation of benzene [7–11]. Generally, noble metal supported catalysts are preferred for the combustion of VOCs due to their higher activity. Papaefthimiou et al. [7] studied the catalytic oxidation of benzene isolated or in the presence of ethyl acetate and butanol on different group VIII metals supported on alumina. Pt and Pd supported on alumina were the most active catalysts. Furthermore, in the presence of ethyl acetate or butanol, the total oxidation of benzene was achieved at higher temperatures than benzene alone. However, metal oxides can be more active than noble metal catalyst in function of the nature of the VOC [6]. The deep oxidation of benzene, ethylacetate and hexane was carried out on MnO2 and Pt/TiO2 catalysts. The removal of ethylacetate was easier on the metal oxide than the noble metal catalyst. On the other hand, benzene was oxidized at lower temperatures on Pt/TiO2 catalyst. Moreover, the metal oxide catalysts are more resistant to poisoning by compounds containing sulfur or chlorine [12]. This is an interesting feature for the treatment of streams from steel manufacturing processes, which contains aromatic compounds in the presence of sulfur