en تخصصي Special مقاله اصیل Original Article <div style="text-align: justify;"><br> <span style="color:#000000;"><span style="font-family:Times New Roman;"><span class="fontstyle0">Background: </span><span class="fontstyle2">Formaldehyde (FA) is a carcinogen compound, which is soluble in water. FA can be removed from aqueous solution using advanced oxidation methods.</span><br> <span class="fontstyle0">Methods: </span><span class="fontstyle2">In this study, the oxidation of FA was studied under fluorescent and UV light. Hydrogen peroxide (H</span><span class="fontstyle2" style="font-size:5pt;">2</span><span class="fontstyle2">O</span><span class="fontstyle2" style="font-size:5pt;">2</span><span class="fontstyle2">) was used as an oxidant. The pH value and H</span><span class="fontstyle2" style="font-size:5pt;">2</span><span class="fontstyle2">O</span><span class="fontstyle2" style="font-size:5pt;">2 </span><span class="fontstyle2">amount of samples were optimized. The chemical oxygen demand (COD), FA concentration, and H</span><span class="fontstyle2" style="font-size:5pt;">2</span><span class="fontstyle2">O</span><span class="fontstyle2" style="font-size:5pt;">2 </span><span class="fontstyle2">consumption were followed.</span><br> <span class="fontstyle0">Results: </span><span class="fontstyle2">It was observed that the pH value of the sample was more significant under fluorescent light than UV light at oxidation of FA. The highest COD removal and H</span><span class="fontstyle2" style="font-size:5pt;">2</span><span class="fontstyle2">O</span><span class="fontstyle2" style="font-size:5pt;">2 </span><span class="fontstyle2">reduction were 18.57 and 30.90%, respectively, at pH 12.00, with a 1:1 ratio of FA:H</span><span class="fontstyle2" style="font-size:5pt;">2</span><span class="fontstyle2">O</span><span class="fontstyle2" style="font-size:5pt;">2 </span><span class="fontstyle2">under fluorescent light. 86.41% FA and 62.12%<br> COD removal were achieved at pH 7.00, with a 1:2 ratio of FA:H</span><span class="fontstyle2" style="font-size:5pt;">2</span><span class="fontstyle2">O</span><span class="fontstyle2" style="font-size:5pt;">2</span><span class="fontstyle2">, under UV light. It was observed that H</span><span class="fontstyle2" style="font-size:5pt;">2</span><span class="fontstyle2">O</span><span class="fontstyle2" style="font-size:5pt;">2 </span><span class="fontstyle2">was consumed at all pH values under UV light. On the other hand, under fluorescent light, the concentration of H</span><span class="fontstyle2" style="font-size:5pt;">2</span><span class="fontstyle2">O</span><span class="fontstyle2" style="font-size:5pt;">2 </span><span class="fontstyle2">decreased only at pH 12. In control samples containing only H</span><span class="fontstyle2" style="font-size:5pt;">2</span><span class="fontstyle2">O</span><span class="fontstyle2" style="font-size:5pt;">2</span><span class="fontstyle2">, the H</span><span class="fontstyle2" style="font-size:5pt;">2</span><span class="fontstyle2">O</span><span class="fontstyle2" style="font-size:5pt;">2</span><br> <span class="fontstyle2">reduction was 92.09% at pH 11.91, while it was 2-6% at other pH levels under fluorescent light. The H</span><span class="fontstyle2" style="font-size:5pt;">2</span><span class="fontstyle2">O</span><span class="fontstyle2" style="font-size:5pt;">2 </span><span class="fontstyle2">reduction changed between 33 and 44% at different pH values under UV light. The oxidation of FA was found to be suitable for the pseudo-first-order kinetic model and Langmuir isotherm model.</span><br> <span class="fontstyle0">Conclusion: </span><span class="fontstyle2">The most effective oxidation was obtained at the original pH value (7.00) and 1:2 ratio of FA:H</span><span class="fontstyle2" style="font-size:5pt;">2</span><span class="fontstyle2">O</span><span class="fontstyle2" style="font-size:5pt;">2 </span><span class="fontstyle2">under UV light.</span></span></span><br style=" font-style: normal; font-variant: normal; font-weight: normal; letter-spacing: normal; line-height: normal; orphans: 2; text-align: -webkit-auto; text-indent: 0px; text-transform: none; white-space: normal; widows: 2; word-spacing: 0px; -webkit-text-size-adjust: auto; -webkit-text-stroke-width: 0px; " > <span dir="LTR"></span></div> Water treatment, Formaldehyde, UV light, Hydrogen peroxide 267 276 http://ehemj.com/browse.php?a_code=A-10-1-224&slc_lang=en&sid=1 Fatma Deniz fatmadeniz@mersin.edu.tr 10031947532846009209 10031947532846009209 Yes Corresponding author: Department of Environmental Engineering, Mersin University, Mersin, Turkey Mehmet Ali Mazmancı mazmanci@mersin.edu.tr 10031947532846009210 10031947532846009210 No Department of Environmental Engineering, Mersin University, Mersin, Turkey