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Advantages of Laser Microscopes for Measuring the Roughness of Copper Foil used in 5G PCBs

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Close up of a printed circuit board.

Nicknamed the mother of electronic products, printed circuit boards (PCBs) are critical to modern electronic devices in just about every industry. A key step in manufacturing PCBs is bonding copper foil to a dielectric resin substrate. Before bonding, the copper surface is intentionally roughened to improve its ability to bond with the dielectric material. However, rough copper foils cause a loss in conductivity, which can negatively impact how the circuit board functions. In addition, conductor loss significantly increases as the current frequency increases due to what’s known as the skin effect. In high-frequency 5G electronics, this can be a problem.

What Is the Skin Effect?

The skin effect is the tendency of a high-frequency alternating current to flow through the conductor’s outer layer, or skin. The higher the current’s density (or frequency), the closer it flows to the surface. High-frequency currents flowing near the surface lead to a smaller skin depth. When the skin depth corresponding to the circuit’s operating frequency is lower than or equal to the copper foil surface roughness, the signal propagates on the copper foil surface.

Since 5G technology uses a current frequency higher than 4G or 3G, its skin depth is lower, and its current density is higher. However, rough surfaces can negatively affect the current’s transmission path. The rougher the copper foil’s surface is, the longer the signal transmission path and the greater the conductor loss. We can’t use perfectly smooth copper foil because some roughness is required to bond the foil to the substrate, so copper foil roughness must be carefully controlled—it should be rough enough to adhere well to the substrate but smooth enough to minimize transmission loss.

Surface Roughness Testing

The conventional method for measuring surface roughness uses a stylus that is dragged across the sample’s surface. However, the stylus can damage sensitive surfaces—like copper foil—and your measurement data is limited by the diameter of the stylus tip.

Laser scanning confocal microscopes are preferred tools for roughness measurement because they offer many advantages over conventional measurement methods.

4 Advantages of Laser Microscopes for Measuring Surface Roughness

No contact required

As their name implies, laser microscopes use laser light to collect data, so nothing physical touches the sample. This eliminates the problem of scratching or damaging your sample during testing using a stylus. A laser microscope also has the advantage of being able to make accurate roughness measurements no matter the sample’s surface condition.

A stylus was dragged across this sample's surface, leaving a linear mark.

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OLS5100 laser microscope

Finer roughness measurement data

A conventional stylus’s tip radius is only about 2 to 10 μm, making it difficult for it to capture roughness data at the microscopic level. The laser on our OLS5100 laser scanning microscope has a radius of only 0.2 μm, so it can capture much finer surface roughness data that a stylus cannot measure.

Diagram showing that the thicker tip radius of a stylus produces less fine thickness measurement data.

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A diagram showing how the very small radius of a laser microscope's laser beam enables it to capture very fine roughness measurement data.

Comprehensive sample information

A stylus can obtain only one type of information—roughness. In contrast, our laser microscope can simultaneously obtain three types of information—laser images, color images, and 3D feature data. Combining these data can give you a better understanding of the surface roughness.

3D measurement data captured using an OLS5100 laser microscope.

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Laser and color images of surface roughness captured using an OLS5100 laser microscope.

Automated inspections

Another advantage of laser confocal microscope’s is the ability to automate part of the inspection workflow, improving reproducibility and minimizing operator-to-operator variability. For copper foil roughness measurement, the OLS5100 laser microscope ca n automate the inspection workflow from data acquisition to report creation. Just press the Start button, and you can perform fine profile measurements at the sub-micron level.

A screenshot of the OLS5100 software showing its macro function.

To make the device even smarter, the microscope software’s macro function enables a computer to control a range of microscope operations so that you can test and analyze samples quickly and accurately.

Related Content

Surface Roughness Measurement: Practical Tips to Get Started

On-Demand Webinar: Roughness Parameters—How to Select the Most Meaningful One?

Roughness Measurement with the LEXT Laser Scanning Microscope


Get In Touch
Applications Engineer, Industrial Microscopes

Qian Jiang’s focus is on product sales and applications in the optical microscopy industry. Through her deep understanding of microscopy applications, she develops solutions for 5G electronic component and medical equipment manufacturers, pharmaceutical production plants, and several other industries.

lipiec 20, 2022
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