AI Article Synopsis
- The liquid phase plasma (LPP) method effectively decomposes dimethyl phthalate (DMP) using a TiO photocatalyst and hydrogen peroxide, achieving a decomposition rate of 63% under optimal plasma conditions after 180 minutes.
- The optimal combination of TiO and hydrogen peroxide enhances the reaction rate, but too much of either can hinder the process due to reduced conductivity and other interferences.
- When using LPP alongside these additives, the DMP decomposition rate can improve by about 2.8 times, ultimately breaking down into simpler compounds like CO and HO through various intermediate stages driven by hydroxyl radicals.
Article Abstract
The liquid phase plasma (LPP) method with a TiO photocatalyst and hydrogen peroxide was used to decompose dimethyl phthalate (DMP). As the applied voltage, pulse width, and frequency were increased, the rate of decomposition was increased and the decomposition rate was 63% for 180 min under plasma optimum conditions. The addition of TiO photocatalyst and hydrogen peroxide increased the DMP decomposition reaction rate, but an excess cause a decrease in decomposition rate due to a decrease in conductivity, blocking of ultraviolet light, and scavenger effect. When the TiO photocatalyst and hydrogen peroxide were used together, the decomposition reaction rate of DMP was greatly improved by using LPP single process alone. Also, when all the processes were used at the same time, the decomposition reaction rate was improved to about 2.8 times. DMP undergoes bond cleavage and ultimately decomposes into CO and HO via dimethyl 4-hydroxyphthalate and methyl salicylates due to hydroxyl radicals and various active species generated by the LPP reaction.
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| http://dx.doi.org/10.1016/j.envres.2018.11.025 | DOI Listing |
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