Partition study of textile dye Remazol Yellow Gold RNL in aqueous two-phase systems

•Sustainable methods for the removal of Remazol Yellow Gold RNL are in demand.•Partition studies in aqueous two-phase systems were carried out.•Biphasic systems employing salts with polymers or ionic liquids were evaluated.•The optimized system gave satisfactory dye partition coefficients (KYR).•Rem...

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Bibliographic Details
Published in:Fluid phase equilibria 2015-04, Vol.391, p.1-8
Main Authors: de Alvarenga, Juliana Maria, Fideles, Renata Aparecida, da Silva, Maira Vieira, Murari, Gabriella Frade, Taylor, Jason Guy, de Lemos, Leandro Rodrigues, Dias Rodrigues, Guilherme, Mageste, Aparecida Barbosa
Format: Article
Language:English
Subjects:
Aqueous two-phase systems
Dyes
Effluents
Gold
Green chemistry
Ionic liquids
Partition
Partitioning
Partitions
Polyethylene glycol
Remazol Yellow Gold RNL
Textiles
Wastewater treatment
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Summary:•Sustainable methods for the removal of Remazol Yellow Gold RNL are in demand.•Partition studies in aqueous two-phase systems were carried out.•Biphasic systems employing salts with polymers or ionic liquids were evaluated.•The optimized system gave satisfactory dye partition coefficients (KYR).•Removal of Remazol Yellow Gold RNL from real wastewater was achieved. The removal of organic dye pollutants from wastewater produced by the textile industry is a complex problem that presents potential health risks to the general public. Remazol Yellow Gold RNL (YR) dye is readily used to dye cellulose base materials and the methods developed for its removal from aqueous systems are either inefficient or too expensive to be adopted by smaller textile manufactures. Our approach is based on aqueous two-phase system (ATPS) using salts and either polymers or ionic liquids to extract Remazol Yellow Gold RNL from wastewater. Parameters such as the nature of the electrolyte, molecular mass of polymer and tie line length (TLL) on the dye partition coefficient (KYR) were all evaluated. A phase diagram for the polyethylene glycol (PEG 4000gmol−1) and magnesiumsulfate system at 298.15K was obtained and used to study the partitioning of YR. The KYR values demonstrate the potential of both systems for the removal of dyes from industrial effluents. The partition mechanism was discussed based on the Haynes model and using the of Gibbs standard energy change (ΔtrG°). The driving force (enthalpy and/or entropy) that governs the partitioning of the dye depends on the nature of the ATPS. The optimized conditions that gave the best system was successfully applied to the removal of YR from wastewater obtained from a local textile manufacturer. The high KYR values in the presence of the effluent demonstrate the potential and robustness of the ATPS for the treatment of effluents from textile industries.
ISSN:0378-3812
1879-0224
DOI:10.1016/j.fluid.2015.01.022