International Journal of
Water Resources and Environmental Engineering

  • Abbreviation: Int. J. Water Res. Environ. Eng.
  • Language: English
  • ISSN: 2141-6613
  • DOI: 10.5897/IJWREE
  • Start Year: 2009
  • Published Articles: 315

Full Length Research Paper

Raw, activated and modified biosorbents for the speciation of C. I. acid red 2 from aqueous solutions: An adsorption study

Richa Sharma1, Soami P. Satsangee1, Sudhir K. Verma1*  
Department of Chemistry, Faculty of Science, Dayalbagh Educational Institute, Agra, India.  
Email: [email protected]

  •  Received: 02 June 2020
  •  Accepted: 07 October 2020
  •  Published: 31 January 2021

References

Ahmad MA, Ahmad N, Bello SO (2015). Modified durian seed as adsorbent for the removal of methyl red dye from aqueous solutions. Applied Water Science 5:407-423.
Crossref

 

Alaguprathana M, Poonkothai M (2017). Decolourisation of the textile dye methyl red from aqueous solution using sugarcane bagasse pith. Asian Journal of Advances in Agricultural Research 3(3):1-9.
Crossref

 

Ardejani FD, Badii K, Limaee NY, Mahmoodi NM, Arami M, Shafaei SZ, Mirhabibi AR (2007). Numerical modeling and laboratory studies on the removal of direct red 23 and direct red 80 dyes from textile effluents using orange peel, a low cost adsorbent. Dyes and Pigment, 73(2):178-185.
Crossref

 

Azhar SS, Liew AG, Suhardy D, Hafiz KF, Hatim MDI (2005). Dye removal from aqueous solution by using adsorption on treated sugarcane bagasse. American Journal of Applied Sciences 2(9):1499-1503.
Crossref

 

Chung KT, Fulk GE, Andrews AW (1981). Mutagenicity testing of some commonly used dyes. Applied and Environmental Microbiology 42(4):641-648.
Crossref

 

Dadfarniaa S, Haji ShabaniAM, Moradi SE, Emami S (2015). Methyl red removal from water by iron based metal-organic frameworks loaded onto iron oxide nanoparticle adsorbent. Applied Surface Science 330:85-93.
Crossref

 

Dim PE (2013). Adsorption of methyl red and methyl orange using different tree bark powder. Academic Research International 4(1):330-338.

 

Food and Agricultural Organization (FAO) (1994). Production Year Book. (Food and Agricultural Organization of United Nations, Rome).

 

Garg VK, Amita M, Kumar R (2004). Basic dye (methylene blue) removal from simulated waste water by adsorption using Indian rose-wood saw dust: A timber industry waste. Dyes and Pigments, 63(3):243-250.
Crossref

 

Ghaedi M, Shokrollahi A, Tavallali H, Shojaiepoor F, Keshavarz B, Hossainian H, Soylak, M, Purkait MK (2011). Activated carbon and multiwalledcarbonnanotubes as efficient adsorbents for removal of arsenazo (III) and methyl red from waste water. Toxicological and Environmental Chemistry 93(3):438-449.
Crossref

 

Ghaedi M, Kokhdan SN (2012). Oxidized multiwalled carbon nanotubes for the removal of methyl red (MR): kinetics and equilibrium study. Desalination and Water Treatment 49(1-3):317-325.
Crossref

 

Hameed BH (2009). Spent tea leaves, a new nonconventional and low-cost adsorbent for removal of basic dye from aqueous solutions. Journal of Hazardous Materials 161(2-3):753-759;
Crossref

 

Hassan AA, Abdulhussein HA (2015). Methyl red dye removal from aqueous solution by adsorption on rice hulls. Journal of Babylon University/Engineering Sciences 23(3):627-637.

 

Hill G, Waage J, Phiri G (1997). The water hyacinth problems in Tropical African, Proceedings of the First Meeting of the International Water Hyacinth Consortium, World Bank, 18-19.

 

Ioannou Z, KarasavvidisCh, Dimirkou A, Antoniadis V (2012). Adsorption of methylene blue and methyl red dyes from aqueous solutions onto modified zeolites. Water Science and Technology 67(5):1129-1136.
Crossref

 

Inthorn D, Singhtho S, Thiravetyan P, Khan E (2004). Decolourisation of basic, direct and reactive dyes by pre-treated narrow-leaved cat tail (Typhaaugustifolia Linn). Bioresources Technology 94(3):299-306.
Crossref

 

Jadhav DN, Vanjara AK (2004).Removal of phenol from wastewater using sawdust, polymerized sawdust and sawdust carbon. Indian Journal of Chemical Technology 1:194-201.

 

Jadhav SU, Kalme SD, Govindwar SP (2008). Biodegradation of methyl red by galactomycesgeotrichum MTCC 1360.International Biodeterioration and Biodegradation 62(2):135-142.
Crossref

 

Janos P, Buchtova H, Ryznarova M (2003). Sorption of dyes from aqueous solutions onto fly ash. Water Research 37(20):4938-4944.
Crossref

 

Jeremias SM, Nivan BC, Luis EA (2006). Kinetics and calorimetric study of adsorption of dyes on mesoporous activated carbon prepared from coconut coir dust. Journal of Colloid and Interface Science 298(2):515-522.
Crossref

 

Klockeman DM, Toledo R, Sims KA (1997). Isolation and characterization of defatted canola meal protein, Journal of Agricultural and Food Chemistry 45(10):3867-3870.
Crossref

 

Lorenc-Grabowska E, Gryglewicz G (2007). Adsorption characteristics of congo red on coal based mesoporous activated carbon. Dyes and Pigments 74(1):34-40.
Crossref

 

Ozacar M, Sengil IA (2004). Application of kinetics models to the sorption of disperse dyes onto alunite. Colloids and Surfaces A: Physicochemical and Engineering Aspects 242(1-3):105-108.
Crossref

 

Poinern GEJ, Senanayake G, Shah N, Thi-Le XN, Parkinson GM (2011). Adsorption of the aurocyanide, Au(CN)2- complex on granular activated carbons derived from macadamia nut shells-a preliminary study. Mineral Engineering 24(15):1694-1702.
Crossref

 

Prasetyko D, Ramli Z, Endud S, Hamdan H, Sulikowski B (2006). Conversion of rice husk ash to zeolite beta. Waste Management 26(10):1173-1179.
Crossref

 

Rosemal M, Haris HM, Sathasivam K (2010). Methyl red removal from water by iron based metal-organic frameworks loaded onto iron oxide nanoparticle adsorbent. Archives of Applied Science Research 2(5):209-216.

 

Saleh TA, Al-Absi AA (2017). Kinetics, isotherms and thermodynamic evaluation of amine functionalized magnetic carbon for methyl red removal from aqueous solutions. Journal of Molecular Liquids 248:577-585
Crossref

 

Sandeep KB (2010). Adsorption Characteristics of Congo Red dye onto PAC and GAC based on S/N ratio: A Taguchi Approach, National Institute of Technology, Rourkela, India.

 

Santhi T, Manonmani S, Smitha T (2010). Removal of methyl red from aqueous solution by activated carbon prepared from the Annonnasqumosa seed by adsorption. Chemical Engineering Research Bulletin 14(1):11-18.
Crossref

 

Saxena R, Sharma S (2016). Adsorption and kinetic studies on the removal of methyl red from aqueous solutions using low-cost adsorbent: guar gum powder. International Journal of Scientific and Engineering Research 7(3):675-683.

 

So K, Wong P, Chang K (1990). Decolorization and biodegradation of methyl red by acetobacterliquefaciens. Toxicity Assessment 5(3):221-235.
Crossref

 

Srivastava R, Rupainwar DC (2011). A comparative evaluation for adsorption of dye on neemtree bark powder and mango tree bark powder. Indian Journal of Chemical Technology 18:67-75.

 

Tanzim K, Abedin MZ (2015). A novel bioadsorbent for the removal of methyl red from aqueous solutions. IOSR Journal of Environmental Science, Toxicology and Food Technology 9(12):87-91.

 

Tarawou T, Michael Horsfall J, Vicente JL (2007). Adsorption of methyl red by water-hyacinth (Eichorniacrassipes) biomass. Chemistry and Biodiversity 4(9):2236-2245.
Crossref

 

Tsai WT, Chang YM, Lai CW, Lo CC (2005). Adsorption of basic dyes in aqueous solution by clay adsorbent from regenerated bleaching earth. Applied Clay Science 29(2):149-154.
Crossref

 

Umesh K, Kaur MP, Garg VK, Sud D (2008). Removal of Nickel (II) from aqueous solution by adsorption on agricultural waste biomass using response surface methodological approach. Bioresource Technology 99(5):1325-1331.
Crossref

 

Vijayaraghavan K, Won SW, Yun YS (2009). Treatment of complex Remazol dye effluent using sawdust-and coal-based activated carbons. Journal of Hazardous Materials 167(1-3):790-796.
Crossref

 

Vijaya PP, Sandhya S (2003). Decolorization and complete degradation of methyl red by a mixed culture. Environmentalist 23:145-149.
Crossref

 

Wong P, Yuen P (1998). Decolourization and biodegradation of N,N'-dimethyl-p-phenylenediamine by Klebsiellapneumoniae RS-13 and Acetobacterliquefaciens S-1. Journal of Applied Microbiology 85(1):79-87
Crossref

 

Yargic AS, Yarbay Sahin RZ, Ozay N, Onal E (2015). Assessment of toxic copper (II) biosorption from aqueous solution by chemically-treated tomato waste. Journal of Cleaner Production 88:152-159,
Crossref

 

Yet ZR, Rahim MZA (2014). Removal of methyl red from aqueous solution by adsorption on treated banana pseudostem fibers using response surface method (rsm). The Malaysian Journal of Analytical Sciences 18(3):592-603,

 

Yuzhu FT, Viraraghavan K (2002). Removal of congo red from an aqueous solution by fungus Aspergillusniger. Advances in Environmental Research 7(1):239-247.
Crossref

 

Zare K, Gupta VK, Moradi O, Makhlouf ASH, Sillanpa M, Sadegh BH, Ghoshekandi RS, Pal A, Wang ZJ, Tyagi I, Kazemi M (2015). A comparative study on the basis of adsorption capacity between CNTs and activated carbon as adsorbents for removal of noxious synthetic dyes: a review. Journal of Nanostructure in Chemistry 5:227-236.
Crossref

 

Zollinger H (1987). Colour Chemistry-Synthesis, Properties and application of organic dyes and pigments, New York: VCH Publishers, NII Article ID (NAID) 10011739210.