胶体二氧化硅网络的生长动力学和结构:原位 RheoSAXS 研究

Konstanse Kvalem Seljelid, Osvaldo Trigueiro Neto, Andrew Ndubuisi Akanno, Bruno Telli Ceccato, Rini Padinjakkara Ravindranathan, Namrah Azmi, Leide P. Cavalcanti, Ingebret Fjelde, Kenneth Dahl Knudsen, Jon Otto Fossum
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引用次数: 0

摘要

硅胶应用广泛,从化妆品、食品科学到油气回收,无所不包。为了进行适当的设计和应用,全面了解凝胶在不同情况下形成的基本机制非常重要。我们使用 RheoSAXS 研究了胶体二氧化硅凝胶的生长和结构,研究了二氧化硅浓度、NaCl 浓度、温度和剪切速率的影响。此外,还将 SAXS 与强磁场相结合,研究了磁性微颗粒和磁场对凝胶结构发展的影响。结果表明,改变活化剂浓度对凝胶动力学的影响最大,这里的活化剂是氯化钠,其次是二氧化硅浓度和温度。此外,还观察到了微小的结构影响,硅浓度较低和氯化钠浓度较高时产生的凝胶团尺寸较大。施加剪切力会导致二氧化硅的结构和宏观行为发生重大变化,使凝胶无法达到停滞状态,而是形成粘性液体。施加磁场似乎会抑制较大团簇的形成。随着磁性微颗粒浓度的增加,也观察到了同样的效果。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Growth kinetics and structure of a colloidal silica-based network: in situ RheoSAXS investigations

Growth kinetics and structure of a colloidal silica-based network: in situ RheoSAXS investigations

Silica gels have a multitude of applications ranging from cosmetics and food science to oil and gas recovery. For proper design and application, it is important to have a thorough understanding of the underlying mechanisms of gel formation under different circumstances. The growth and structure of colloidal silica gels has been investigated using RheoSAXS to study the effect of silica concentration, NaCl concentration, temperature and shear rate. Additionally, SAXS in combination with a strong magnetic field has been applied to investigate the effect of magnetic microparticles and magnetic field on the development of the gel structure. Results indicate that the strongest effect on the gel kinetics are achieved by altering the activator concentration, here in the form of NaCl, followed by silica concentration and temperature. Small structural effects were also observed, with larger cluster sizes being produced at lower silica concentration and at higher NaCl concentration. Applying shear caused major changes both in structure as well as the macroscopic behavior of the silica, preventing the gel from reaching an arrested state, instead forming a viscous liquid. Applying a magnetic field appears to suppress the formation of larger clusters. The same effect is observed for increasing magnetic microparticle concentrations.

Graphical Abstract

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