4.7 Article

Uptake the rare earth elements Nd, Ce, and La by a commercial diatomite: kinetics, equilibrium, thermodynamic and adsorption mechanism

Journal

JOURNAL OF MOLECULAR LIQUIDS
Volume 389, Issue -, Pages -

Publisher

ELSEVIER
DOI: 10.1016/j.molliq.2023.122862

Keywords

Diatomite; Rare earth elements; Mass transfer; Desorption; Ion-exchange

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This study focuses on the application and evaluation of diatomite as an adsorbent for Nd3+, Ce3+, and La3+ rare earth elements (REEs). The results show that diatomite has a porous and cylindrical structure with a specific surface area of 150 m2/g. The diatomite can effectively adsorb cationic REEs, with the uptake percentage increasing in the order of La3+, Ce3+, and Nd3+. Kinetic and equilibrium processes were best described by the Avrami-fractional order (AFO) and Liu isotherm model, respectively. The research demonstrates that diatomite is a sustainable and low-cost adsorbent for REEs recovery from synthetic and real effluents.
This study addresses the application and evaluation of diatomite as a low-cost, natural, abundant, and highly efficient adsorbent of Nd3+, Ce3+, and La3+ rare earth elements (REEs). The results revealed that the diatomite was porous and cylindrical, with a specific surface area of 150 m2/g. The diatomite displayed a point of zero charge equal to 1.8, maintaining its surface negatively charged at pH values higher than 1.8, which was beneficial for cationic REEs uptake. At pH 1, all three REEs had their lowest uptake values; at pHs 2-6, the REEs removal efficiency practically did not change. The uptaken percentage increased in the order of La3+ (50%), Ce3+ (77%), and Nd3+ (92%), influenced by the electronegativity of the ions. The Avrami-fractional order (AFO) and Liu isotherm model better fit the kinetic and equilibrium process (qmax = La3+ (22.8 mg g-1), Ce3+ (56.2 mg g-1), and Nd3+ (100.9 mg g-1)). Since the diatomite is highly porous, pore filling/pore-surface diffusion was the main mechanism for REEs adsorption, as well as ion exchange and chelation. The reusability tests revealed that the diatomite could be reused 8 times without losing performance. This research shows that diatomite is an efficient strategy for designing effective, low-cost, sustainable adsorbents to recover REEs from synthetic and real effluents.

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