Investigation of chemical de-burring and subsequent plasma cleaning of mechanically punched micro via array fabricated in LCP substrate

M. K. Chowdhury, Li Sun, S. Cunningham, A. Malshe
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Abstract

The purpose of this paper is to present new findings in process variability for wet chemical etching and subsequent plasma cleaning of mechanically punched micro vias fabricated in liquid crystal polymer (LCP) substrate. It was observed that the micro-mechanical punching process tends to form a LCP burr inside the through via, and form a copper burr on the bottom copper layer. The bottom copper layer is pre-laminated in ULTRALAM 3850, supplied by Rogers Corporation. An experimental procedure was designed to remove LCP and copper burr by chemical etching method. It was found that the conventional method of etching polymeric materials by strong base like KOH or NaOH does not work for LCP due to its high chemical resistance. Hence, the LCP surface had to be functionalized by using a strong oxidizer (NaKMnO4) before starting conventional chemical etching by a strong base solution. A systematic approach has been developed to etch out the LCP and copper burr formation during the punching process. After examining three different experimental matrices it was found that a sequential treatment by oxidizer (NaKMnO4), etchant (NaOH), and neutralizer (3%H2SO4 + 3%H2O2) gave the best results during the etching process. Considerable improvements were made on LCP and copper burr removal process using the wet chemical treatments including the development of an oxygen plasma treatment to clean the carbonated LCP debris produced during chemical etching. It was found that a subsequent oxygen plasma treatment after the wet chemical processes provided the cleanest through vias for interconnection on LCP substrates.
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LCP基板机械穿孔微孔阵列化学去毛刺及等离子体清洗研究
本文的目的是介绍在液晶聚合物(LCP)衬底上制造的机械穿孔微孔的湿化学蚀刻和随后的等离子清洗过程变异性的新发现。结果表明,微机械冲孔工艺容易在通孔内部形成LCP毛刺,在底部铜层形成铜毛刺。底部铜层是预层压ULTRALAM 3850,由罗杰斯公司提供。设计了化学蚀刻法去除LCP和铜毛刺的实验流程。由于LCP具有较高的耐化学性,传统的强碱(如KOH或NaOH)刻蚀聚合物材料的方法不适用于LCP。因此,在使用强碱溶液进行常规化学蚀刻之前,必须使用强氧化剂(NaKMnO4)将LCP表面功能化。针对冲孔过程中铜毛刺的形成,提出了一种系统的蚀刻方法。在考察了三种不同的实验基质后,发现在蚀刻过程中,氧化剂(NaKMnO4)、蚀刻剂(NaOH)和中和剂(3%H2SO4 + 3%H2O2)的顺序处理效果最好。采用湿法化学处理方法对LCP和铜毛刺去除工艺进行了相当大的改进,包括开发了一种氧等离子体处理方法来清洁化学蚀刻过程中产生的碳化LCP碎屑。研究发现,湿法化学处理后的后续氧等离子体处理为LCP衬底上的互连提供了最干净的通孔。
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