Application aspects of joint anaphoresis/substrate anodization in production of biocompatible ceramic coatings

IF 1 4区化学 Q4 CHEMISTRY, MULTIDISCIPLINARY

Journal of The Serbian Chemical Society Pub Date : 2023-01-01 DOI:10.2298/jsc230118034b

Katarina Bozic, M. Pavlovic, G. Šekularac, Stefan Panic, Marijana Pantovic-Pavlovic

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引用次数: 1

Abstract

Electrophoretic deposition (EPD) can occur as a cataphoretic deposition - the coating is deposited on the cathode, and anaphoretic deposition - the coating is deposited on the anode. The primary purpose of EPD is to obtain compact and uniform organic/inorganic coatings of the desired thickness and adhesion on metal surfaces by applying an electric field to the particles of coating precursor. EPD basic principles for coatings deposition concerning fundamental explanations and considerations of practical parameters of the process are presented. Cataphoretic deposition has become popular because it can apply organic coatings to complex structures that are otherwise very difficult to coat. These coatings were found to improve the characteristics of the substrate, such as biocompatibility, appearance and the resistance to the corrosion processes. The key EPD parameters are composition, pH value and viscosity of deposition medium, as well as zeta potential of the particles, electric field strength, etc. A special survey is given to the process of anaphoretic deposition, which is relatively new, and its advantages over cataphoretic deposition are discussed. Through the process of joint anaphoresis/substrate anodization process, the surface of the substrate is simultaneously anodized and modified by incorporation of the foreign particles into the anodic layer. Resulting coatings of mixed composition of better adhesion and corrosion resistance with respect to cataphoretically-deposited coatings are obtained.

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复合电泳/基材阳极氧化在生物相容性陶瓷涂层生产中的应用

电泳沉积(EPD)可以发生为射射沉积-涂层沉积在阴极上，和回射沉积-涂层沉积在阳极上。EPD的主要目的是通过对涂层前驱体的颗粒施加电场来获得所需厚度和附着力的致密和均匀的有机/无机涂层。介绍了EPD涂层沉积的基本原理、基本解释和实际工艺参数的考虑。弹射沉积已经变得流行，因为它可以将有机涂层涂在复杂的结构上，否则很难涂覆。这些涂层改善了基材的生物相容性、外观和耐腐蚀性能。关键的EPD参数是沉积介质的组成、pH值、粘度，以及颗粒的zeta电位、电场强度等。特别介绍了相对较新的回射沉积工艺，并讨论了其相对于回射沉积的优点。通过联合阳极电泳/衬底阳极氧化工艺，通过将异物颗粒掺入阳极层，同时对衬底表面进行阳极氧化和修饰。所得到的混合组合物的涂层相对于射镀涂层具有更好的附着力和耐腐蚀性。

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来源期刊

Journal of The Serbian Chemical Society 化学-化学综合

CiteScore

1.80

自引率

0.00%

发文量

审稿时长

1 months

期刊介绍： The Journal of the Serbian Chemical Society -JSCS (formerly Glasnik Hemijskog društva Beograd) publishes articles original papers that have not been published previously, from the fields of fundamental and applied chemistry: Theoretical Chemistry, Organic Chemistry, Biochemistry and Biotechnology, Food Chemistry, Technology and Engineering, Inorganic Chemistry, Polymers, Analytical Chemistry, Physical Chemistry, Spectroscopy, Electrochemistry, Thermodynamics, Chemical Engineering, Textile Engineering, Materials, Ceramics, Metallurgy, Geochemistry, Environmental Chemistry, History of and Education in Chemistry.