Modeling resistance increase in a composite ink under cyclic loading

IF 2.8 4区 工程技术 Q3 MATERIALS SCIENCE, MULTIDISCIPLINARY
Qiushi Li, Euichul Chung, Antonia Antoniou, Olivier N Pierron
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Abstract

The electrical performance of stretchable electronic inks degrades as they undergo cyclic deformation during use, posing a major challenge to their reliability. The experimental characterization of ink fatigue behavior can be a time-consuming process, and models allowing accurate resistance evolution and life estimates are needed. Here, a model is proposed for determining the electrical resistance evolution during cyclic loading of a screen-printed composite conductive ink. The model relies on two input specimen-characteristic curves, assumes a constant rate of normalized resistance increase for a given strain amplitude, and incorporates the effects of both mean strain and strain amplitude. The model predicts the normalized resistance evolution of a cyclic test with reasonable accuracy. The mean strain effects are secondary compared to strain amplitude, except for large strain amplitudes (>10%) and mean strains (>30%). A trace width effect is found for the fatigue behavior of 1 mm vs 2 mm wide specimens. The input specimen-characteristic curves are trace-width dependent, and the model predicts a decrease in N f by a factor of up to 2 for the narrower trace width, in agreement with the experimental results. Two different methods are investigated to generate the rate of normalized resistance increase curves: uninterrupted fatigue tests (requiring ∼6–7 cyclic tests), and a single interrupted cyclic test (requiring only one specimen tested at progressively higher strain amplitude values). The results suggest that the initial decrease in normalized resistance rate only occurs for specimens with no prior loading. The minimum-rate curve is therefore recommended for more accurate fatigue estimates.
循环载荷作用下复合油墨的成型阻力增大
可拉伸电子墨水在使用过程中经历循环变形,其电气性能会降低,这对其可靠性构成了重大挑战。油墨疲劳行为的实验表征可能是一个耗时的过程,并且需要允许精确电阻演变和寿命估计的模型。在此,提出了一种用于确定丝网印刷复合导电油墨在循环加载期间电阻演变的模型。该模型依赖于两条输入样本特征曲线,假设给定应变幅度的归一化电阻增加率恒定,并结合了平均应变和应变幅度的影响。该模型以合理的精度预测了循环试验的归一化电阻演变。除了大应变幅度(>10%)和平均应变(>30%)外,平均应变效应与应变幅度相比是次要的。对于1 mm与2 mm宽试样的疲劳行为,发现了迹线宽度效应。输入样本特性曲线与迹线宽度有关,该模型预测,对于较窄的迹线宽度,Nf将减少多达2倍,这与实验结果一致。研究了两种不同的方法来生成归一化电阻增加曲线的速率:不间断疲劳试验(需要〜6–7次循环试验)和单次中断循环试验(只需要在逐渐升高的应变振幅值下测试一个试样)。结果表明,归一化阻力率的初始下降仅发生在没有预先加载的试样上。因此,建议使用最小速率曲线进行更准确的疲劳估算。
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来源期刊
Flexible and Printed Electronics
Flexible and Printed Electronics MATERIALS SCIENCE, MULTIDISCIPLINARY-
CiteScore
4.80
自引率
9.70%
发文量
101
期刊介绍: Flexible and Printed Electronics is a multidisciplinary journal publishing cutting edge research articles on electronics that can be either flexible, plastic, stretchable, conformable or printed. Research related to electronic materials, manufacturing techniques, components or systems which meets any one (or more) of the above criteria is suitable for publication in the journal. Subjects included in the journal range from flexible materials and printing techniques, design or modelling of electrical systems and components, advanced fabrication methods and bioelectronics, to the properties of devices and end user applications.
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