Low electric field induction in BaTiO3-epoxy nanocomposites

Raghvendra Kumar Mishra, Danning Li, Iva Chianella, Saurav Goel, Saeid Lotfian, Hamed Yazdani Nezhad
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Abstract

Epoxy is widely used material, but epoxy has limitations in terms of brittleness in failure, and thus researchers explore toughening and strengthening options such as adding a second phase or using electromagnetic fields to tailor toughness and strength, on demand and nearly instantaneously. Such approach falls into the category of active toughening but has not been extensively investigated. In this research, Si-BaTiO3 nanoparticles were used to modify the electro-mechanical properties of a high-performance aerospace-grade epoxy so as to study its response to electric fields, specifically low field strengths. To promote uniform dispersion and distribution, the Si-BaTiO3 nanoparticles were functionalised with silane coupling agents and mixed in the epoxy Araldite LY1564 at different content loads (1, 5, 10 wt%), which was then associated with its curing agent Aradur 3487. Real-time measurements were conducted using Raman spectroscopy while applying electric fields to the nanocomposite specimens. The Raman data showed a consistent trend of increasing intensity and peak broadening under the increasing electric field strength and Si-BaTiO3 contents. This was attributed to the BaTiO3 particles’ dipolar displacement in the high-content nanocomposites (i.e., 5 wt% and 10 wt%). The study offers valuable insights on how electric field stimulation can actively enhance the mechanical properties in epoxy composites, specifically in relatively low fields and thin, high-aspect-ratio composite layers which would require in-situ mechanical testing equipped with electric field application, an ongoing investigation of the current research.

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batio3 -环氧纳米复合材料的低电场感应性能
环氧树脂是一种被广泛使用的材料,但环氧树脂在失效时具有脆性方面的局限性,因此研究人员探索了增韧和强化的选择,如添加第二相或使用电磁场来定制韧性和强度,根据需要,几乎是即时的。这种方法属于活性增韧的范畴,但尚未得到广泛的研究。在本研究中,使用Si-BaTiO3纳米颗粒修饰高性能航空级环氧树脂的机电性能,以研究其对电场,特别是低场强的响应。为了促进均匀的分散和分布,硅烷偶联剂将Si-BaTiO3纳米颗粒功能化,并以不同的含量(1、5、10 wt%)混合在环氧树脂aralite LY1564中,然后与固化剂Aradur 3487相结合。在对纳米复合材料样品施加电场的同时,利用拉曼光谱进行实时测量。随着电场强度和Si-BaTiO3含量的增加,拉曼光谱的强度和峰展宽趋势一致。这是由于BaTiO3颗粒在高含量纳米复合材料中的偶极位移(即5 wt%和10 wt%)。该研究为电场刺激如何积极提高环氧复合材料的力学性能提供了有价值的见解,特别是在相对较低的电场和薄的、高纵横比的复合材料层中,这需要现场力学测试,并配备电场应用,这是目前正在进行的一项研究。
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