Analytic circuit model for thermal drying behavior of electronic inks

IF 1.9 Q3 ENGINEERING, ELECTRICAL & ELECTRONIC
G. Maroli, S. Boyeras, H. Giannetta, S. Pazos, J. Gak, A. Oliva, M. Volpe, P. Julián, F. Palumbo
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引用次数: 1

Abstract

Understanding the sintering process of conductive inks is a fundamental step in the development of sensors. The intrinsic properties (such as thermal conductivity, resistivity, thermal coefficient, among others) of the printed devices do not correspond to those of the bulk materials. In the field of biosensors porosity plays a predominant role, since it defines the difference between the geometric area of the working electrode and its electrochemical surface area. The analysis reported so far in the literature on the sintering of inks are based on their DC characterization. In this work, the shape and distribution of the nanoparticles that make up the silver ink have been studied employing a transmission electron microscopy. Images of the printed traces have been obtained through a scanning electron microscope at different sintering times, allowing to observe how the material decreases its porosity over time. These structural changes were supported through electrical measurements of the change in the trace impedance as a function of drying time. The resistivity and thermal coefficient of the printed tracks were analyzed and compared with the values of bulk silver. Finally, this work proposes an analytical circuit model of the drying behavior of the ink based on AC characterization at different frequencies. The characterization considers an initial time when the spheric nanoparticles are still surrounded by the capping agent until the conductive trace is obtained. This model can estimate the characteristics that the printed devices would have, whether they are used as biosensors (porous material) or as interconnections (compact material) in printed electronics.
电子墨水热干燥行为的解析电路模型
了解导电油墨的烧结过程是传感器发展的基本步骤。印刷器件的固有特性(如导热性、电阻率、热系数等)与大块材料的特性不对应。在生物传感器领域,孔隙率起着主导作用,因为它决定了工作电极的几何面积与其电化学表面积之间的差异。迄今为止在文献中报道的关于油墨烧结的分析都是基于它们的直流特性。在这项工作中,利用透射电子显微镜研究了组成银墨水的纳米颗粒的形状和分布。在不同的烧结时间,通过扫描电子显微镜获得了印刷痕迹的图像,可以观察到材料是如何随着时间的推移而减少孔隙率的。这些结构变化是通过电测量的变化,在走线阻抗作为干燥时间的函数支持。分析了印刷轨迹的电阻率和热系数,并与体银的值进行了比较。最后,本研究提出了一个基于不同频率交流特性的油墨干燥行为的分析电路模型。表征考虑球形纳米颗粒仍被封盖剂包围的初始时间,直到获得导电痕迹。该模型可以估计印刷设备将具有的特性,无论它们是用作生物传感器(多孔材料)还是用作印刷电子产品中的互连(紧凑材料)。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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