Spirulina Based Iron Oxide Nanoparticles for Adsorptive Removal of Crystal Violet Dye

In comparison to algal biomass, algae-based nanoparticle (green synthesis) not only aids in the removal of toxins from wastewater, but it is also an ecologically benign strategy with enhanced efficacy. In the present study, Spirulina is being utilised to make green iron oxide nanoparticles (S-IONPs)...

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Published in	Topics in catalysis Vol. 65; no. 19-20; pp. 1675 - 1685
Main Authors	Bhukal, Santosh, Sharma, Anuj, Rishi, Divya, Kumar, Sumit, Deepak, Bansal, Pal, Kaushik, Mona, Sharma
Format	Journal Article
Language	English
Published	New York Springer US 01.12.2022 Springer Nature B.V
Subjects	Adsorbents Adsorptivity Aqueous solutions Catalysis Characterization and Evaluation of Materials Chemistry Chemistry and Materials Science Crystals Decoloring Dyes Industrial Chemistry/Chemical Engineering Iron oxides Langmuir waves Nanoparticles Original Paper Pharmacy Physical Chemistry Toxins Wastewater Algal iron oxide NPs CV dye Nano-adsorbent Removal efficiency
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Abstract	In comparison to algal biomass, algae-based nanoparticle (green synthesis) not only aids in the removal of toxins from wastewater, but it is also an ecologically benign strategy with enhanced efficacy. In the present study, Spirulina is being utilised to make green iron oxide nanoparticles (S-IONPs), which further used to make an effective adsorbent for the removal of cationic crystal violet (CV) dye using ultra-sonic waves. The created nano-adsorbent was thoroughly investigated using a variety of characterisation techniques, including FT-IR, XRD, FE-SEM, and UV–VIS spectroscopy. Moreover, the S-IONPs adsorbent performed remarkably well in removing key chemicals from synthetic solutions, such as dyes. The pseudo-second order model was used to describe the kinetic profile, while the linearized Langmuir theory with r 2 of 0.96413 and q max of 55.62 mg/g was used to show the adsorption isotherm. Sequestration of the CV dye from aqueous solution using S-IONPs was carried out efficiently. The potential of S-IONPs for decolorization of crystal violet dye solution was also confirmed through various analytical techniques. Graphical Abstract Preparation of Spirulina based iron oxide nanoparticles for sequestration of Crystal Violet dye from aqueous solution
AbstractList	In comparison to algal biomass, algae-based nanoparticle (green synthesis) not only aids in the removal of toxins from wastewater, but it is also an ecologically benign strategy with enhanced efficacy. In the present study, Spirulina is being utilised to make green iron oxide nanoparticles (S-IONPs), which further used to make an effective adsorbent for the removal of cationic crystal violet (CV) dye using ultra-sonic waves. The created nano-adsorbent was thoroughly investigated using a variety of characterisation techniques, including FT-IR, XRD, FE-SEM, and UV–VIS spectroscopy. Moreover, the S-IONPs adsorbent performed remarkably well in removing key chemicals from synthetic solutions, such as dyes. The pseudo-second order model was used to describe the kinetic profile, while the linearized Langmuir theory with r2 of 0.96413 and qmax of 55.62 mg/g was used to show the adsorption isotherm. Sequestration of the CV dye from aqueous solution using S-IONPs was carried out efficiently. The potential of S-IONPs for decolorization of crystal violet dye solution was also confirmed through various analytical techniques.Preparation of Spirulina based iron oxide nanoparticles for sequestration of Crystal Violet dye from aqueous solution In comparison to algal biomass, algae-based nanoparticle (green synthesis) not only aids in the removal of toxins from wastewater, but it is also an ecologically benign strategy with enhanced efficacy. In the present study, Spirulina is being utilised to make green iron oxide nanoparticles (S-IONPs), which further used to make an effective adsorbent for the removal of cationic crystal violet (CV) dye using ultra-sonic waves. The created nano-adsorbent was thoroughly investigated using a variety of characterisation techniques, including FT-IR, XRD, FE-SEM, and UV–VIS spectroscopy. Moreover, the S-IONPs adsorbent performed remarkably well in removing key chemicals from synthetic solutions, such as dyes. The pseudo-second order model was used to describe the kinetic profile, while the linearized Langmuir theory with r 2 of 0.96413 and q max of 55.62 mg/g was used to show the adsorption isotherm. Sequestration of the CV dye from aqueous solution using S-IONPs was carried out efficiently. The potential of S-IONPs for decolorization of crystal violet dye solution was also confirmed through various analytical techniques. Graphical Abstract Preparation of Spirulina based iron oxide nanoparticles for sequestration of Crystal Violet dye from aqueous solution
Author	Sharma, Anuj Divya Pal, Kaushik Rishi Deepak, Bansal Mona, Sharma Bhukal, Santosh Kumar, Sumit
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Snippet	In comparison to algal biomass, algae-based nanoparticle (green synthesis) not only aids in the removal of toxins from wastewater, but it is also an...
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SubjectTerms	Adsorbents Adsorptivity Aqueous solutions Catalysis Characterization and Evaluation of Materials Chemistry Chemistry and Materials Science Crystals Decoloring Dyes Industrial Chemistry/Chemical Engineering Iron oxides Langmuir waves Nanoparticles Original Paper Pharmacy Physical Chemistry Toxins Wastewater
Title	Spirulina Based Iron Oxide Nanoparticles for Adsorptive Removal of Crystal Violet Dye
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