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Silica Nanoparticle-Based Platform for Rare Earth Element Recovery and Separation Yuxuan Dai

Dissertations & Theses @ University of Pennsylvania Available online

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Format:
Book
Thesis/Dissertation
Author/Creator:
Dai, Yuxuan, author.
Contributor:
University of Pennsylvania. Chemical and Biomolecular Engineering., degree granting institution.
Language:
English
Subjects (All):
0542.
0640.
0652.
0794.
Local Subjects:
0542.
0640.
0652.
0794.
Physical Description:
1 electronic resource (124 pages)
Contained In:
Dissertations Abstracts International 87-09A
Place of Publication:
Ann Arbor : ProQuest Dissertations and Theses, 2025
Language Note:
English
Summary:
Rare earth elements (REEs) are essential for clean energy technologies including batteries for electrical vehicles, wind turbines and LED screens due to their unique magnetic, optical, and electronic properties. Efficient methods for their recovery and separation are urgently needed to meet the growing demands of a rapidly evolving green economy worldwide. However, current separation technologies, such as liquid-liquid extraction (LLE), suffer from harmful environmental impacts, scalability limitations and high energy costs, due to the similar physiochemical properties of REEs and the dependence on organic solvents. These environmental, operational, and economic challenges motivate the development of sustainable, selective, and scalable REE separations.Nanostructured materials, such as those incorporating silica nanoparticles (SiO2 NPs), are promising materials to incorporate into REE separations due to their high surface area, tunable surface chemistry and environmental compatibility. Their scale offers several advantages, including high surface-to-volume ratio, integration into dynamic architectures, and stabilization of complex structures. These features offer new opportunities for designing alternative methods for REE recovery and separation methods which do not have the drawbacks of existing approaches.This thesis focuses on developing a SiO2 NP-based platform for REE separation, building from fundamental understanding to practical applications. We investigate the fundamental interactions between SiO2 NPs and REEs across the full pH range of pH 3 - 10, identifying and mapping the transition of three distinct interaction modes with a combinational of technical tools. We demonstrate the intrinsic, size dependent selectivity, with SiO2 NPs favoring smaller, more charge dense heavy REEs (HREEs) over larger light REEs (LREEs) in both binary and ternary mixtures under competitive conditions. Our results also show reversible selective adsorption of REEs on SiO2 NP surfaces, enabling ligand-free separation processes.Building upon this mechanistic understanding, we integrate the SiO2 NP-based platform into three separation processes: (i) solid phase extraction, where SiO2 NPs act as adsorbents that enable size-dependent selectivity and reversible capture and release via simple pH-swings, (ii) froth flotation, where SiO2 NPs serve as REE carrier and foam stabilizer, and (iii) bicontinuous interfacially jammed emulsion gels, where the nanoparticle-stabilized interfaces enable high interfacial area for REE adsorption. This work provides a foundation for developing sustainable REE separation strategies with nanoparticles
Notes:
Advisors: Stebe, Kathleen J.; Lee, Daeyeon Committee members: Radhakrishnan, Ravi; Kim, Dohyung
Source: Dissertations Abstracts International, Volume: 87-09, Section: A.
Ph.D. University of Pennsylvania 2025
Vendor supplied data
Local Notes:
School code: 0175
ISBN:
9798276005461
Access Restriction:
Restricted for use by site license

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