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Conclusions 32 The results reported in the present research brought new knowledge in the field of gas- phase PCO. The low-molecular VOCs of environmental concern containing hetero-atoms in their molecules were studied in detail considering reaction products and pathways, and reaction kinetics and its dependence on the experimental parameters. PCO is a promising method for the elimination of different VOCs due to its advantageous activity under ambient conditions, although higher but still mild temperatures may also be applied. Gas-phase PCO studies resulted in improved understanding of the MTBE and TBA oxidation mechanism on TiO2 and platinised TiO2: PCO, TCO and oxidation products were determined; the L-H model parameters of the reaction kinetics were obtained; and the role of air humidity was clarified. The limits of ethanethiol concentration and the reaction conditions at which the performance of the reactor’s work was stable for indefinite time were established. Photocatalytic oxidation products for ethanethiol were identified. The kinetics of photocatalytic oxidation of ethanethiol was well described with the monomolecular L-H model, although it did not exhibit full conformity to all rules supporting the physical meaning of the reaction model. Methyl amine and DMA were easily oxidized photocatalytically on UV-irradiated TiO2. The volatile PCO products of MA and DMA were determined. The PCO reaction kinetics fitted the L-H description. The photocatalyst demonstrated stable activity at the temperature and concentration ranges tested in the experiments.
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Page 1 and 2: Anna Kachina GAS-PHASE PHOTOCATALYT
Page 3 and 4: ABSTRACT Anna Kachina Gas-phase pho
Page 5: ACKNOWLEDGEMENTS 5 The author grate
Page 9 and 10: LIST OF PUBLICATIONS 7 The present
Page 11 and 12: 1 INTRODUCTION 9 Substances emitted
Page 13 and 14: 11 oxidation (TCO) experiments were
Page 15 and 16: 1.2.3 Amino compounds 13 The chemic
Page 17 and 18: 15 The commercialization of TiO2-ba
Page 19 and 20: 17 polymer matrix (Brezová et al.,
Page 21 and 22: 19 ambient temperatures. However, s
Page 23 and 24: 2.3 Reaction kinetics 21 The L-H mo
Page 25 and 26: 3 RESULTS AND DISCUSSION 3.1 Experi
Page 27 and 28: 3.2 Catalyst life-time and reaction
Page 29 and 30: Table 3.2.1 Catalyst deactivation t
Page 31 and 32: 29 Table 3.3.1 Reaction rate consta
Page 33: 31 Table 3.4.1 Arrhenius equation p
Page 37 and 38: 35 Fernández, A., Lassaletta, G.,
Page 39 and 40: 37 Lee, S. H, Kang, M., Cho, S. M.,
Page 41 and 42: 39 Sabate, J., Anderson, M. A., Agu
Page 43: 41 APPENDICES

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