Aleksandra Fiołek, Tomasz Cudak, Kazimierz Kowalski, Tomasz Moskalewicz
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引用次数: 0
摘要
本研究调查了各种机械和化学表面处理对 316L 不锈钢基材上电泳沉积(EPD)的海藻酸钠涂层的附着强度和表面特性的影响。XPS 和 TEM 结果表明,基底存在含有元素的氧化层,厚度从 1 纳米到 45 纳米不等,具体取决于所使用的处理方法。大多数基底都具有较高的粗糙度和亲水性(与水的 CA 值为 62.8-82.6 度)。在相同的工艺参数下,即 5 V 和 300 秒,沉积出了形态一致的海藻酸钠涂层。与基底(含水 CA 为 62.8-82.6 度)相比,所有涂层都表现出更高的亲水性(含水 CA 为 29.5-49.7 度)。蚀刻和阳极氧化基底上的涂层显示出最高的附着强度(4B 级),这归功于极低的氧化层厚度和特定的基底表面形貌。机械互锁被认为是这些涂层的主要附着机制。这项研究为优化表面处理以提高海藻酸钠涂层与广泛用于临时骨植入物的不锈钢基底的附着力提供了启示。获得的结果还将有助于提高海藻酸钠复合涂层与钢基底的附着力。
Effect of Stainless Steel Substrate Preparation on the Adhesion Strength and Morphology of Electrophoretically Deposited Sodium Alginate Coatings
In this study, the influence of various mechanical and chemical surface treatments on the adhesion strength and surface properties of sodium alginate coatings electrophoretically deposited (EPD) on 316L stainless steel substrates was investigated. XPS and TEM results revealed the presence of oxide layers containing elements from the substrates, with thicknesses varying from 1 to 45 nm, depending on the treatment used. Most substrates exhibited high roughness and hydrophilic properties (CA with water 62.8–82.6 deg). Sodium alginate coatings with uniform morphology were deposited with the same process parameters, i.e., 5 V and 300 s. The surface topography of the coatings was closely related to that of the substrate on which they were deposited. All coatings exhibited higher hydrophilicity (CA with water 29.5–49.7 deg) compared to the substrates (CA with water 62.8–82.6 deg). The coatings on the etched and anodized substrates demonstrated the highest adhesion strength (class 4B), attributed to the very low oxide layer thickness and the specific substrate surface topography. Mechanical interlocking was identified as the primary adhesion mechanism for these coatings. This work provides insight into optimizing surface treatments for improved adhesion of sodium alginate coatings to stainless steel substrates widely used for temporary bone implants. The results obtained will also be helpful in providing high adhesion of sodium alginate-based composite coatings to steel substrates.