Qu Jing, Ouyang Liangqi, Kuo Chin-Chen, Martin David C
Department of Materials Science & Engineering, University of Delaware, Newark, DE 19716, USA.
Department of Materials Science & Engineering, University of Delaware, Newark, DE 19716, USA.
Acta Biomater. 2016 Feb;31:114-121. doi: 10.1016/j.actbio.2015.11.018. Epub 2015 Dec 1.
Conjugated polymers such as poly(3,4-ethylenedioxythiphene) (PEDOT) are of interest for a variety of applications including interfaces between electronic biomedical devices and living tissue. The mechanical properties, strength, and adhesion of these materials to solid substrates are all vital for long-term applications. We have been developing methods to quantify the mechanical properties of conjugated polymer thin films. In this paper, the stiffness, strength and the interfacial shear strength (adhesion) of electrochemically deposited PEDOT and PEDOT-co-1,3,5-tri[2-(3,4-ethylene dioxythienyl)]-benzene (EPh) were studied. The estimated Young's modulus of the PEDOT films was 2.6±1.4GPa, and the strain to failure was around 2%. The tensile strength was measured to be 56±27MPa. The effective interfacial shear strength was estimated with a shear-lag model by measuring the crack spacing as a function of film thickness. For PEDOT on gold/palladium-coated hydrocarbon film substrates an interfacial shear strength of 0.7±0.3MPa was determined. The addition of 5mole% of a tri-functional EDOT crosslinker (EPh) increased the tensile strength of the films to 283±67MPa, while the strain to failure remained about the same (2%). The effective interfacial shear strength was increased to 2.4±0.6MPa.
This paper describes methods for estimating the ultimate mechanical properties of electrochemically deposited conjugated polymer (here PEDOT and PEDOT copolymers) films. Of particular interest and novelty is our implementation of a cracking test to quantify the shear strength of the PEDOT thin films on these solid substrates. There is considerable interest in these materials as interfaces between biomedical devices and living tissue, however potential mechanisms and modes of failure are areas of continuing concern, and establishing methods to quantify the strengths of these interfaces are therefore of particular current interest. We are confident that these results will be useful to the broader biological materials community and are worthy of broader dissemination.
共轭聚合物,如聚(3,4 - 亚乙基二氧噻吩)(PEDOT),在包括电子生物医学设备与活组织之间的界面等多种应用中具有吸引力。这些材料的机械性能、强度以及与固体基材的附着力对于长期应用都至关重要。我们一直在开发量化共轭聚合物薄膜机械性能的方法。本文研究了电化学沉积的PEDOT和PEDOT - 共 - 1,3,5 - 三[2 - (3,4 - 亚乙基二氧噻吩基)] - 苯(EPh)的刚度、强度和界面剪切强度(附着力)。PEDOT薄膜的估计杨氏模量为2.6±1.4GPa,断裂应变约为2%。测得的拉伸强度为56±27MPa。通过测量裂纹间距作为薄膜厚度的函数,用剪切滞后模型估计有效界面剪切强度。对于在金/钯涂层碳氢化合物薄膜基材上的PEDOT,确定的界面剪切强度为0.7±0.3MPa。添加5摩尔%的三官能团EDOT交联剂(EPh)将薄膜的拉伸强度提高到283±67MPa,而断裂应变保持大致相同(2%)。有效界面剪切强度提高到2.4±0.6MPa。
本文描述了估计电化学沉积共轭聚合物(此处为PEDOT和PEDOT共聚物)薄膜极限机械性能的方法。特别令人感兴趣和新颖的是我们实施的一种开裂试验,以量化这些固体基材上PEDOT薄膜的剪切强度。作为生物医学设备与活组织之间的界面,这些材料引起了相当大的兴趣,然而潜在的失效机制和模式仍是持续关注的领域,因此建立量化这些界面强度的方法目前尤为重要。我们相信这些结果将对更广泛的生物材料领域有用,值得更广泛地传播。