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Peculiarites of Benzene Decomposition in Cavitation Fields

Zynovii Znak1 znak_zo [at] ukr.net
Yurii Sukhatskii11 sukhatsky [at] i.ua
Olha Zin1 zin.olha [at] gmail.com
Roman Mnykh1 mnyhr [at] ukr.net
Semen Khomiak2 semkhom [at] ukr.net
Anastasiia Hrabarovska1 1584466 [at] ukr.net
  1. Chemistry and Chemical Technology of Inorganic Substances Department, National University «Lviv Polytechnic», Ukraine, Lviv, S.Bandera Str., 12
  2. Department of Technology of Biologically Active Substances, Pharmacy and Biotechnology, National University «Lviv Polytechnic», Ukraine, Lviv, S. Bandera Str., 12
Abstract 

It is proposed to carry out treatment of wastewaters, containing of aromatic compounds, in particular benzene, in cavitation fields. The results of studies of the cavitational decomposition of benzene under isothermal conditions (at temperatures 303, 313 and 323 K) are presented. The extremal characterof the dependence of the degree of decomposition of benzene from temperature with a minimum of 313 K is established. An abnormal appearance of the dependence is explained by possibility of occurrence of secondary processes , namely the formation of gas bubbles of nanometer sizes (babstons) and their clusters, which have high mechanical resistance and diffusivityy, and also on the basis of the kinetic theory of Frenkel's fluid.Recommendations for the implementation of the benzene decomposition process in cavitation fields are formulated on the basis of the results of experimental studies.

Keywords 
cavitation fields
decomposition
benzene
ultrasonic magnetostrictive emitter
stationary treatment mode
References 

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