Etching defines what your PCB layout can and cannot achieve. Understanding the relationship between copper thickness, trace width, and spacing is not optional — it directly affects what your board costs and who can make it.
How Etching Works — Downward and Sideways # The etchant does not only remove copper downward. It simultaneously attacks laterally — inward beneath the etch resist at the edges of every copper structure. This lateral attack is called undercut. The etch medium itself can be alkaline or acidic depending on the process — both attack copper selectively through the use of photo and metal resists as protective layers.
Every laminate material discussed in this series so far — standard FR4, High-Tg FR4, polyimide — shares a common selection logic. You choose among them based on thermal performance, mechanical requirements, and environmental resistance. Electrical properties rarely drive the decision because at the frequencies where these materials are used, the differences are manageable.
PTFE-based laminates exist in a different category entirely. They are selected primarily for their electrical properties — specifically their ability to transmit high-frequency signals with minimal loss and maximum dimensional consistency.
One of the most persistent misconceptions about PTFE-based PCB laminates comes from handling the material. Pick up a sheet of Rogers RO4350B or RT/duroid 5880 and compare it to a sheet of standard FR4. The PTFE laminate feels different — slightly softer, with a quality that engineers sometimes describe as rubbery or compliant. Bend it gently and it flexes slightly before springing back.
This tactile impression leads directly to a dangerous assumption: that PTFE can be used in flexible PCB applications, or treated with more mechanical freedom than a rigid board.
Flex PCB specifications are among the most frequently underspecified documents in electronics procurement. Buyers write “flex PCB, polyimide base” and assume the supplier will fill in the rest correctly. Sometimes they do. Often they do not — and the failure mode is a board that cracks, delaminates, or develops intermittent opens after a few thousand flex cycles.
Understanding why polyimide behaves the way it does, and why the protective layer choices matter as much as the base material, is the foundation of a correct flex PCB specification.
Material selection for a PCB is rarely driven by electrical requirements alone. The operating environment — temperature, humidity, chemical exposure, thermal cycling — defines the boundary conditions within which the laminate must perform reliably over its service life. Choosing a material adequate for the bench but wrong for the field is one of the most consistent sources of premature failure in electronic assemblies.
The Four Laminate Families # For the purposes of environmental selection, the relevant laminate families are:
When buyers specify FR4 High-Tg on an RFQ, they often do so because a datasheet or engineer told them to. Fewer understand why it behaves differently from standard FR4 — and why that difference matters when a board heats up under load, goes through lead-free soldering, or operates in a demanding environment.
The answer lies not in the glass fibres or mineral fillers, but in the epoxy resin chemistry itself.