High-throughput synthesis of high-purity and ultra-small iron phosphate nanoparticles by controlled mixing in a chaotic microreactor

[Display omitted] •Two oscillating feedback microreactors (OFMs) were designed based on chaotic flow.•Premixing was important for enhancing fluid mixing in OFMs.•Almost complete mixing was achieved in flow-focused OFM in 0.16 ms.•Ultra-small FePO4 nanoparticles (9 nm) was prepared at a throughput of...

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Bibliographic Details
Published in:Chemical engineering science 2023-10, Vol.280, p.119084, Article 119084
Main Authors: Shi, Zu-Chun, Wei, Shi-Xiao, Xie, Ting-Liang, Liu, Qiang, Au, Chak-Tong, Yin, Shuang-Feng
Format: Article
Language:English
Subjects:
Chaotic advection
High-throughput
Inlet structures
Iron phosphate nanoparticles
Oscillating feedback microreactor
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Summary:[Display omitted] •Two oscillating feedback microreactors (OFMs) were designed based on chaotic flow.•Premixing was important for enhancing fluid mixing in OFMs.•Almost complete mixing was achieved in flow-focused OFM in 0.16 ms.•Ultra-small FePO4 nanoparticles (9 nm) was prepared at a throughput of 180 mL/min. High-purity FePO4 with small particle size is pivotal for improving electrochemical performance of LiFePO4-based lithium-ion batteries. Here, an oscillating feedback microreactor (OFM) based on chaotic advection was designed to prepare high-quality FePO4 by coprecipitation. Dye-tracer experiments and CFD simulations were adopted to investigate fluid mixing mechanism and to evaluate mixing efficiency in the reactor. The results indicated that a “flow-focused” OFM (FOFM) performed better than a “Y-junction” OFM in mixing performance, owing to enhanced premixing in focused inlet microchannel of the former. The results of Villermaux-Dushman experiments illustrated that almost complete mixing could be achieved in 0.16 ms in FOFM. Accordingly, FePO4 nanoparticles of good quality was synthesized using FOFM, and the particle size can be easily controlled by adjusting flow rate or reactant concentration. High-purity (P/Fe molar ratio: 0.95–1.04) and ultra-small FePO4 nanoparticles (9 nm) with narrow particle size distribution were generated at a high throughput of 180 mL/min.
ISSN:0009-2509
DOI:10.1016/j.ces.2023.119084