How Solder Mask is Applied on PCBs: Factory Tour & Process Explanation
WHAT THIS VIDEO COVERS
In this factory tour video, we explore the Solder Mask Process (also known as the green oil process), one of the most vital stages in modern PCB fabrication.
The shiny green coating you see on most circuit boards is solder mask - a protective polymer layer applied over the copper traces. It serves multiple critical functions: preventing unintended solder bridges during assembly, protecting against oxidation and environmental damage, and improving electrical insulation between conductors.
The video walks through the complete application process, from surface preparation and mask application to exposure, development, and final curing. You'll see real manufacturing equipment and understand why precise control in this stage directly impacts signal integrity, yield rates, and product reliability.
Proper solder mask application is especially important for complex designs such as HDI PCBs, multilayer boards, and applications requiring high reliability like medical device PCBs, automotive electronics, and aerospace systems.
Whether you're designing 4-layer PCBs, rigid-flex boards, or preparing for PCB assembly, understanding the solder mask process helps you make better DFM decisions and avoid costly production issues.
This video delivers practical insights that bridge design intent with real-world manufacturing execution.
KEY HIGHLIGHTS
- Protective Function: Solder mask prevents solder shorts, protects copper from oxidation, and defines precise soldering areas for SMT and through-hole components.
- Application Process: Involves clean surface prep, mask coating (screen printing or photo-imageable), UV exposure, development, and thermal curing for durability.
- Manufacturing Impact: Directly affects assembly yield, long-term reliability, and performance in demanding applications like automotive, medical, and industrial control systems.
FAQ
Q1: Why is solder mask usually green on PCBs?
A1: Green is the industry standard because it offers excellent contrast for AOI (Automated Optical Inspection), good heat resistance during reflow, and cost efficiency. Other colors (red, blue, black, white) are available but may have different performance characteristics.
Q2: How does solder mask thickness affect PCB performance?
A2: Thicker solder mask provides better protection but can impact fine-pitch component soldering and impedance control. Proper thickness control is critical for HDI and high-frequency designs to maintain signal integrity and reliability.
Q3: When should you consider special solder mask requirements?
A3: Special requirements (thicker mask, specific colors, or higher resolution) are common in high TG PCBs, heavy copper designs, LED lighting boards, or applications with extreme environmental exposure.
That shiny green layer on a PCB is called solder mask.And without it, your circuit board would fail much more easily.
Today, we're diving deep into one of the most critical steps in PCB manufacturing — the Solder Mask Process, also known as the green oil process.
This seemingly simple layer prevents solder bridges, protects copper traces from oxidation, and ensures your electronics work reliably for years. In this video, I'll walk you through the entire solder mask workflow step by step, from raw board to finished product. Let's go inside the factory!
First, let's understand the basics.
Solder Mask, or Solder Resist, is a thin protective coating applied over the copper traces on a printed circuit board.
Its main jobs are preventing accidental solder bridges between closely spaced pads during assembly.
Protecting copper from oxidation, moisture, dust, and mechanical damage.
Providing electrical insulation.
And giving the board its signature look and color.
While green is the most common and cost-effective color, you'll also see black, white, blue, red, and even yellow boards.
The most widely used type today is Liquid Photo-Imageable (LPI) Solder Mask. Other types include dry film and screen-printing ink. The typical thickness is between 10 to 15 micrometers.
Now, let's see how it's actually applied in a real production line.
Step 1: Surface Preparation (Pretreatment)
Before anything else, the board must be perfectly clean. The copper surface is micro-etched and roughened to improve adhesion. Any contamination here can cause the solder mask to peel off later.
Step 2: Solder Mask Ink Coating
Next, the liquid solder mask ink is applied evenly over the entire board—usually on both sides. The viscosity and coating thickness must be tightly controlled for uniform coverage.
However, if your design requires Via Plugging—where the guide holes must be filled to prevent solder from wicking through—factories will add a specialized step right here.
Using a custom laser-drilled aluminum stencil a dedicated machine forces high-viscosity ink deep into the vias before the rest of the board is printed. This ensures a stable via filling rate of over 95%, guaranteeing excellent reliability and a neat final appearance.
Step 3: Pre-baking (Tack Dry)
The coated board goes into an oven at around 70–80°C. This step evaporates solvents and makes the ink non-tacky, preparing it for exposure. Timing is critical — too long or too hot, and the next steps will fail.
Step 4: Exposure – The Most Important Step
This is where the magic happens. Since we use Laser Direct Imaging (LDI) technology, the solder mask is exposed directly by a high-precision laser — no photomask or film is needed. This delivers much higher accuracy and better registration, especially for fine-pitch designs.
The laser selectively shines UV light onto the board. The exposed solder mask undergoes a photochemical reaction and becomes polymerized — meaning it hardens and becomes insoluble.
This step defines two fundamental concepts in PCB design: Solder Mask Opening and Solder Mask Covering.
The component pads where components will be soldered must remain unexposed and soft, creating an 'Opening' so they can be washed away later. Meanwhile, the traces that need long-term protection are fully exposed to UV light, 'Covering' the copper with a rock-solid shield.
Step 5: Developing
Next is Developing. The board is washed with an alkaline solution, usually sodium carbonate. The unexposed soft solder mask is washed away, revealing the clean copper pads.
Step 6: Final Curing
Finally, the board goes through Final Curing.It is baked at a higher temperature—typically around 150°C for one to two hours. This fully cross-links the polymers, giving the solder mask its ultimate mechanical strength, high insulation resistance, and the ability to withstand the intense heat of reflow soldering.
After curing, the board moves on to silkscreen, surface finish, electrical testing, and routing.
Although it's often hidden under components, the solder mask layer plays a vital role in the reliability and performance of every electronic device we use.From surface prep to final curing, every step must be precisely controlled.
If you enjoyed this deep dive into PCB manufacturing, please like, subscribe, and comment below: what other PCB process would you like me to explain next — lamination, or flying probe testing?
Thanks for watching, and I'll see you in the next video!
