Elimination of malachite green from aqueous and saline water by laterite-derived Na-polyferrosialate and polyferrophosphosialate geopolymers: A comparative study

Publikation: Beitrag in FachzeitschriftArtikelForschungPeer-Review

Autoren

  • Tome Sylvain
  • Hermann Dzoujo Tamaguelon
  • Victor Shikuku
  • Achile Nana
  • Marie Annie Etoh
  • Claus Rüscher
  • Jacques Etame

Organisationseinheiten

Externe Organisationen

  • University of Douala
  • Kaimosi Friends University College
  • University of Dschang
Forschungs-netzwerk anzeigen

Details

OriginalspracheEnglisch
Seiten (von - bis)5982-5991
Seitenumfang10
FachzeitschriftCeramics international
Jahrgang50
Ausgabenummer4
Frühes Online-Datum3 Dez. 2023
PublikationsstatusVeröffentlicht - 15 Feb. 2024

Abstract

In this study, two laterites (LA)-based geopolymers were synthesized using alkalination (GPAL) and phosphoric acid-activation (GPAC) approaches and applied to scavenge malachite green (MG) dye from aqueous (non-saline) and saline water. The precursor (LA) and geopolymers were characterized by XRF, XRD, TG/DTA SEM, and FTIR techniques. Alkalination and acid-activation resulted in morphologically distinguishable geopolymers with different porosity structures. The dissolution of mineral phases and chemical composition was dependent on the activation medium, resulting in Na-polyferrosialate and polyferrophosphosialate geopolymers for GPAL and GPAC, respectively. The adsorption kinetics data were best described by the pseudo-first-order (PFO) model wherein the adsorption rate, denoted by rate constant (k1), increased with an increase in ionic strength (salinity). The equilibrium data were best modelled by the Sips isotherm. GPAL had a higher maximum adsorption capacity (Qms) than GPAC in both aqueous (non-saline) and saline water. The adsorption capacities were increased in saline solution relative to aqueous solutions without NaCl, from 12.4 to 54.1 mg/g and from 57.1 to 92.0 mg/g for GPAC and GPAL, respectively. The adsorption mechanism entailed electrostatic interactions, hydrogen bonding and hydrophobic interactions. Salinity decreased the solubility of MG and increased the hydrophobic interactions and affinity of MG, implied by apparent equilibrium constant (Ka), resulting in increased adsorption density (Qms). These results indicate that alkaline-based geopolymers are better candidates for scavenging MG dye from water, especially in saline environments.

ASJC Scopus Sachgebiete

Zitieren

Elimination of malachite green from aqueous and saline water by laterite-derived Na-polyferrosialate and polyferrophosphosialate geopolymers: A comparative study. / Sylvain, Tome; Tamaguelon, Hermann Dzoujo; Shikuku, Victor et al.
in: Ceramics international, Jahrgang 50, Nr. 4, 15.02.2024, S. 5982-5991.

Publikation: Beitrag in FachzeitschriftArtikelForschungPeer-Review

Sylvain T, Tamaguelon HD, Shikuku V, Nana A, Etoh MA, Rüscher C et al. Elimination of malachite green from aqueous and saline water by laterite-derived Na-polyferrosialate and polyferrophosphosialate geopolymers: A comparative study. Ceramics international. 2024 Feb 15;50(4):5982-5991. Epub 2023 Dez 3. doi: 10.1016/j.ceramint.2023.11.252
Download
@article{c899b1c0355e42049a6afa8ee95d3a9e,
title = "Elimination of malachite green from aqueous and saline water by laterite-derived Na-polyferrosialate and polyferrophosphosialate geopolymers: A comparative study",
abstract = "In this study, two laterites (LA)-based geopolymers were synthesized using alkalination (GPAL) and phosphoric acid-activation (GPAC) approaches and applied to scavenge malachite green (MG) dye from aqueous (non-saline) and saline water. The precursor (LA) and geopolymers were characterized by XRF, XRD, TG/DTA SEM, and FTIR techniques. Alkalination and acid-activation resulted in morphologically distinguishable geopolymers with different porosity structures. The dissolution of mineral phases and chemical composition was dependent on the activation medium, resulting in Na-polyferrosialate and polyferrophosphosialate geopolymers for GPAL and GPAC, respectively. The adsorption kinetics data were best described by the pseudo-first-order (PFO) model wherein the adsorption rate, denoted by rate constant (k1), increased with an increase in ionic strength (salinity). The equilibrium data were best modelled by the Sips isotherm. GPAL had a higher maximum adsorption capacity (Qms) than GPAC in both aqueous (non-saline) and saline water. The adsorption capacities were increased in saline solution relative to aqueous solutions without NaCl, from 12.4 to 54.1 mg/g and from 57.1 to 92.0 mg/g for GPAC and GPAL, respectively. The adsorption mechanism entailed electrostatic interactions, hydrogen bonding and hydrophobic interactions. Salinity decreased the solubility of MG and increased the hydrophobic interactions and affinity of MG, implied by apparent equilibrium constant (Ka), resulting in increased adsorption density (Qms). These results indicate that alkaline-based geopolymers are better candidates for scavenging MG dye from water, especially in saline environments.",
keywords = "Acid-activation, Adsorption, Alkalination, Laterite, Malachite green, Salinity",
author = "Tome Sylvain and Tamaguelon, {Hermann Dzoujo} and Victor Shikuku and Achile Nana and Etoh, {Marie Annie} and Claus R{\"u}scher and Jacques Etame",
note = "Funding Information: The work presented in the paper has been carried out DAAD postdoc scholarship namely Research Stays for University Academics and Scientists , 2022 Award ID No: 57588362 to the first author and DAAD is greatly acknowledged. The authors are grateful Institut f{\"u}r Mineralogie of Leibniz Universit{\"a}t Hannover for extending all the facility to carry out the different characterization analyses.",
year = "2024",
month = feb,
day = "15",
doi = "10.1016/j.ceramint.2023.11.252",
language = "English",
volume = "50",
pages = "5982--5991",
journal = "Ceramics international",
issn = "0272-8842",
publisher = "Elsevier Ltd.",
number = "4",

}

Download

TY - JOUR

T1 - Elimination of malachite green from aqueous and saline water by laterite-derived Na-polyferrosialate and polyferrophosphosialate geopolymers

T2 - A comparative study

AU - Sylvain, Tome

AU - Tamaguelon, Hermann Dzoujo

AU - Shikuku, Victor

AU - Nana, Achile

AU - Etoh, Marie Annie

AU - Rüscher, Claus

AU - Etame, Jacques

N1 - Funding Information: The work presented in the paper has been carried out DAAD postdoc scholarship namely Research Stays for University Academics and Scientists , 2022 Award ID No: 57588362 to the first author and DAAD is greatly acknowledged. The authors are grateful Institut für Mineralogie of Leibniz Universität Hannover for extending all the facility to carry out the different characterization analyses.

PY - 2024/2/15

Y1 - 2024/2/15

N2 - In this study, two laterites (LA)-based geopolymers were synthesized using alkalination (GPAL) and phosphoric acid-activation (GPAC) approaches and applied to scavenge malachite green (MG) dye from aqueous (non-saline) and saline water. The precursor (LA) and geopolymers were characterized by XRF, XRD, TG/DTA SEM, and FTIR techniques. Alkalination and acid-activation resulted in morphologically distinguishable geopolymers with different porosity structures. The dissolution of mineral phases and chemical composition was dependent on the activation medium, resulting in Na-polyferrosialate and polyferrophosphosialate geopolymers for GPAL and GPAC, respectively. The adsorption kinetics data were best described by the pseudo-first-order (PFO) model wherein the adsorption rate, denoted by rate constant (k1), increased with an increase in ionic strength (salinity). The equilibrium data were best modelled by the Sips isotherm. GPAL had a higher maximum adsorption capacity (Qms) than GPAC in both aqueous (non-saline) and saline water. The adsorption capacities were increased in saline solution relative to aqueous solutions without NaCl, from 12.4 to 54.1 mg/g and from 57.1 to 92.0 mg/g for GPAC and GPAL, respectively. The adsorption mechanism entailed electrostatic interactions, hydrogen bonding and hydrophobic interactions. Salinity decreased the solubility of MG and increased the hydrophobic interactions and affinity of MG, implied by apparent equilibrium constant (Ka), resulting in increased adsorption density (Qms). These results indicate that alkaline-based geopolymers are better candidates for scavenging MG dye from water, especially in saline environments.

AB - In this study, two laterites (LA)-based geopolymers were synthesized using alkalination (GPAL) and phosphoric acid-activation (GPAC) approaches and applied to scavenge malachite green (MG) dye from aqueous (non-saline) and saline water. The precursor (LA) and geopolymers were characterized by XRF, XRD, TG/DTA SEM, and FTIR techniques. Alkalination and acid-activation resulted in morphologically distinguishable geopolymers with different porosity structures. The dissolution of mineral phases and chemical composition was dependent on the activation medium, resulting in Na-polyferrosialate and polyferrophosphosialate geopolymers for GPAL and GPAC, respectively. The adsorption kinetics data were best described by the pseudo-first-order (PFO) model wherein the adsorption rate, denoted by rate constant (k1), increased with an increase in ionic strength (salinity). The equilibrium data were best modelled by the Sips isotherm. GPAL had a higher maximum adsorption capacity (Qms) than GPAC in both aqueous (non-saline) and saline water. The adsorption capacities were increased in saline solution relative to aqueous solutions without NaCl, from 12.4 to 54.1 mg/g and from 57.1 to 92.0 mg/g for GPAC and GPAL, respectively. The adsorption mechanism entailed electrostatic interactions, hydrogen bonding and hydrophobic interactions. Salinity decreased the solubility of MG and increased the hydrophobic interactions and affinity of MG, implied by apparent equilibrium constant (Ka), resulting in increased adsorption density (Qms). These results indicate that alkaline-based geopolymers are better candidates for scavenging MG dye from water, especially in saline environments.

KW - Acid-activation

KW - Adsorption

KW - Alkalination

KW - Laterite

KW - Malachite green

KW - Salinity

UR - http://www.scopus.com/inward/record.url?scp=85179031219&partnerID=8YFLogxK

U2 - 10.1016/j.ceramint.2023.11.252

DO - 10.1016/j.ceramint.2023.11.252

M3 - Article

AN - SCOPUS:85179031219

VL - 50

SP - 5982

EP - 5991

JO - Ceramics international

JF - Ceramics international

SN - 0272-8842

IS - 4

ER -