The real cost to manufacture a PCB encompasses everything that goes into making the product: the materials and other value-added supplies, machine and personnel costs, and most importantly, your quality. A hard look at real costs seems wholly appropriate.
Traditional electroless copper and electroless copper immersion gold have been primary PCB plating methods for decades. But alternative plating metals and processes have been introduced over the past few years as miniaturization and advanced packaging continue to develop. extra fine copper powder
In this issue of PCB007 Magazine, we discuss technology roadmaps and what they mean for our businesses, providing context to the all-important question: What is my company’s technology roadmap?
Electroless copper plating involves immersing the laminate in a series of baths that include a catalyst (usually palladium) followed by an alkaline, chelated solution of copper. Copper is thereby chemically bonded to all surfaces that are immersed. This chemically bonded coating is rather thin, but it allows electrical current to flow across the dielectric, which enables electroplating. Figure 2 depicts the through-hole immediately after electroless copper plating (technically it is not a plating process since electrical current is not used).
Figure 2: Electroless plating on the hole wall.
Figure 2 shows that a very thin layer of copper is deposited over the through-hole. Electroplating is next. Figure 3 depicts the through-hole after electroplating.
Figure 3: Electrolytic plating over electroless copper.
The through-hole now has a solid coating of copper that is both electrically and mechanically robust.
The Shadow® process performs the same basic function as the electroless plating process, which is to create a conductive bridge across the insulating layers so that electroplating can be performed.
The drilled copper laminate is immersed in a solution with conductive carbon particles. The carbon will adhere to the entire surface, creating a very thin, fragile layer. A micro-etch is then performed that removes the carbon from the copper material, so that only the dielectric areas remain coated, as shown in figure 4:
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