Decomposition of Azo Dye C.I. Direct Yellow 86 by the Fenton Process in the Presence of Nanoparticles of Iron Oxides

被引：0

作者：

Kos, Lech ^{[1
]}

Sojka-Ledakowicz, Jadwiga ^{[1
]}

Michalska, Karina ^{[1
]}

Perkowski, Jan

机构：

[1] Text Res Inst, PL-92103 Lodz, Poland

来源：

FIBRES & TEXTILES IN EASTERN EUROPE | 2014年 / 22卷 / 05期

关键词：

azo dye; Fenton reaction; nanoparticles; iron oxides; dye decomposition; HETEROGENEOUS FENTON; WASTE-WATER; DEGRADATION; ACID; MINERALIZATION; DECOLORIZATION; CATALYSTS;

D O I：

暂无

中图分类号：

TB3 [工程材料学]; TS1 [纺织工业、染整工业];

学科分类号：

0805 ; 080502 ; 0821 ;

摘要：

The aim of the study was to determine the efficiency of decomposition of azo dye C.I. Direct Yellow 86 by the Fenton method in the presence of nanoparticles of iron oxides and to compare it with the classical Fenton method. Water solutions of the dye were subjected to the classical purification method with the application of ferrous sulfate - and for comparison - to a process in which iron (II,III) oxide nanopowder was added to the ferrous sulfate. Analysis of the effect of the ferrous sulfate, iron (II,III) oxide nanopowder, hydrogen peroxide and the pH of the solution on the treatment efficiency showed that the process was optimised. The use of iron oxide nanopowder increased the efficiency of dye decomposition.

引用

页码：114 / 120

页数：7

共 19 条

[1] Decomposition of azo dye C.I. Direct Yellow 86 by the fenton process in the presence of nanoparticles of iron oxides
Rozklad barwnika azowego C.I. Direct Yellow 86 w procesie Fentona w obecności nanocząstek tlenków żelaza
1600, Sciendo (22):
[2] DECOMPOSITION OF AZO DYE DIRECT RED 23 IN THE FENTON PROCESS IN THE PRESENCE OF IRON OXIDE NANOPOWDER
Kos, L.
Sojka-Ledakowicz, J.
Zylla, R.
Michalska, K.
Perkowski, J.
PROCEEDINGS OF THE 13TH INTERNATIONAL CONFERENCE ON ENVIRONMENTAL SCIENCE AND TECHNOLOGY, 2013,
[3] Degradation of Azo Dye C.I. Reactive Blue 194 in Water by Sponge Iron in the Presence of Ultrasound
Liu, Yan
Wang, Xi-Kui
Chen, Bing
Wang, Chen
Shen, Ting-Ting
ENVIRONMENTAL ENGINEERING SCIENCE, 2014, 31 (10) : 541 - 547
[4] Photoelectrochemical oxidation of C.I. Direct Black 22 azo dye under elevated oxygen pressure
A. B. Isaev
Z. M. Aliev
N. A. Adamadzieva
Russian Journal of Applied Chemistry, 2012, 85 : 765 - 769
[5] Degradation mechanism of azo dye C.I. reactive red 2 by iron powder reduction and photooxidation in aqueous solutions
Wu, F
Deng, NS
Hua, HL
CHEMOSPHERE, 2000, 41 (08) : 1233 - 1238
[6] Optimization of C.I. Acid Red 14 azo dye removal by electrocoagulation batch process with response surface methodology
Aleboyeh, A.
Daneshvar, N.
Kasiri, M. B.
CHEMICAL ENGINEERING AND PROCESSING-PROCESS INTENSIFICATION, 2008, 47 (05) : 827 - 832
[7] Degradation of azo dye C.I. Acid Red 18 using an eco-friendly and continuous electrochemical process
Ali Reza Rahmani
Kazem Godini
Davood Nematollahi
Ghasem Azarian
Sima Maleki
Korean Journal of Chemical Engineering, 2016, 33 : 532 - 538
[8] Immobilization of TiO2 nanopowder on glass beads for the photocatalytic decolorization of an azo dye C.I. Direct Red 23
Daneshvar, N.
Salari, D.
Niaei, A.
Rasoulifard, M.H.
Khataee, A.R.
Journal of Environmental Science and Health - Part A Toxic/Hazardous Substances and Environmental Engineering, 2005, 40 (08): : 1605 - 1617
[9] Decomposition pathways and reaction intermediate formation of the purified, hydrolyzed azo reactive dye C.I. Reactive Red 120 during ozonation
Zhang, Feifang
Yediler, Ayfer
Liang, Xinmiao
CHEMOSPHERE, 2007, 67 (04) : 712 - 717
[10] Response surface optimization of electro-oxidation process for the treatment of C.I. Reactive Yellow 186 dye: reaction pathways
Rajkumar K.
Muthukumar M.
Applied Water Science, 2017, 7 (02) : 637 - 652

← 1 2 →