Response surface methodology adhering central composite design for the optimization of Zn (II) adsorption using rice husk nanoadsorbent

[Display omitted] •Potential synthesis of novel nanocellulose from agricultural waste of paddy crop and evaluation of nanoadsorbent of rice husk for Zn (II) removal.•Designing and Modelling of Zn (II) adsorption onto rice husk.•Successful optimization of process parameters and interactive effects be...

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Bibliographic Details
Published in:Chemical physics letters 2022-08, Vol.801, p.139684, Article 139684
Main Authors: Kaur, Mandeep, Kumari, Santosh, Sharma, Praveen
Format: Article
Language:English
Subjects:
Adsorption
Central composite design
Nanoadsorbent
Response surface methodology
Zn (II)
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Summary:[Display omitted] •Potential synthesis of novel nanocellulose from agricultural waste of paddy crop and evaluation of nanoadsorbent of rice husk for Zn (II) removal.•Designing and Modelling of Zn (II) adsorption onto rice husk.•Successful optimization of process parameters and interactive effects between the influencing variables in RSM unified CCD.•Comprehensive investigation of isotherm models with system obeying Langmuir model indicating monolayer adsorption of Zn (II).•The Pseudo-second order kinetic model suggests a rate limiting step involving chemical reaction. Present study highlights the effectuality of rice husk nanoadsorbent RHN for the removal of Zn (II) from aqueous solution. A peculiar statistical technique central composite design of response surface methodology by using Design-Expert® software version 11 was executed to investigate Zn (II) removal by varying three adsorption parameters such as pH, dose and metal ion concentration. Quadratic model equation and analysis of variance were outlined in the study. Zn (II) removal was found to be 80% at optimum conditions pH 6, dose 0.8 g/L and metal ion concentration 15 mg/L and desirability was near 0.9. To comprehend the nature of adsorption process, linear forms of isotherms were gratified. Langmuir isotherm model was found to be compatible with adsorption data indicating monolayer adsorption on homogeneous active sites of nanoadsorbent with 0.9978 R2. Pseudo-second order kinetic model fitted well to the adsorption data with R2 0.992. Spontaneous and endothermic nature of the process was depicted by thermodynamic study. Adsorption mechanism is reasonably explained by hydrolysis, precipitation, electrostatic interactions and HASB inreaction. The regeneration of RHN was analysed upto three successive cycles.
ISSN:0009-2614
1873-4448
DOI:10.1016/j.cplett.2022.139684