3D-printed microfluidic system for the in situ diagnostics and screening of nanoparticles synthesis parameters

IF 2.8 Q2 ENGINEERING, ELECTRICAL & ELECTRONIC
V.V. Shapovalov , S.V. Chapek , A.A. Tereshchenko , A.N. Bulgakov , A.P. Bagliy , V.V. Volkov , P.V. Konarev , M.A. Soldatov , S.A. Soldatov , A.A. Guda , A.V. Soldatov
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引用次数: 1

Abstract

Fine tuning of the material properties requires many trials and errors during the synthesis. The metal nanoparticles undergo several stages of reduction, clustering, coalescence and growth upon their formation. Resulting properties of the colloidal solution thus depend on the concentrations of the reagents, external temperature, synthesis protocol and qualification of the researcher determines the reproducibility and quality. Automatized flow systems overcome the difficulties inherent for the conventional batch approaches. Microfluidic systems represent a good alternative for the high throughput data collection. The recent advances in 3D-printing made complex topologies in microfluidic devices cheaper and easily customizable. However, channels of the cured photopolymer resin attract metal ions upon synthesis and create crystallization centers. In our work we present 3D-printed system for the noble metal nanoparticle synthesis in slugs. Alternating flows of oil and aqueous reaction mixtures prevent metal deposition on the channel walls. Elongated droplets are convenient for optical and X-ray diagnostics using conventional methods. We demonstrate the work of the system using Ag nanoparticles synthesis for machine-learning assisted tuning of the plasmon resonance frequency.

Abstract Image

3d打印微流控系统用于纳米颗粒合成参数的原位诊断和筛选
材料特性的微调需要在合成过程中进行多次试验和误差。金属纳米颗粒在形成时经历还原、聚集、聚结和生长的几个阶段。因此,胶体溶液的最终性质取决于试剂的浓度、外部温度、合成方案和研究人员的资格决定了再现性和质量。自动化流动系统克服了传统分批方法固有的困难。微流体系统代表了高通量数据收集的一个很好的替代方案。3D打印的最新进展使微流体设备中的复杂拓扑结构更便宜且易于定制。然而,固化的光聚合物树脂的通道在合成时吸引金属离子并产生结晶中心。在我们的工作中,我们提出了在蛞蝓中合成贵金属纳米颗粒的3D打印系统。油和水性反应混合物的交替流动防止金属沉积在通道壁上。细长液滴便于使用传统方法进行光学和X射线诊断。我们展示了使用Ag纳米颗粒合成用于机器学习辅助调谐等离子体共振频率的系统的工作。
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来源期刊
Micro and Nano Engineering
Micro and Nano Engineering Engineering-Electrical and Electronic Engineering
CiteScore
3.30
自引率
0.00%
发文量
67
审稿时长
80 days
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