Laser Marking in the Electronics and Semiconductor Industry

When it comes to semiconductor manufacturing, precision, efficiency, and compliance are key considerations. As the industry evolves, the need for effective identification and compliance solutions has never been greater.

Luckily, electronic marking and semiconductor laser marking technology have been up to the challenge. It provides an innovative solution to the way semiconductor components are labeled and tracked throughout their lifecycle. Because of this, manufacturers worldwide have reaped the benefits and improved their operations.

The following will provide an overview of electronic marking technology in the semiconductor industry. We will look at applications of laser marking machines, like a fiber laser marker or a UV laser marker, how semiconductor laser marking helps with compliance and traceability, and how laser marking technology has become a valuable tool for manufacturers.

Direct Part Marking in the Semiconductor Industry

Semiconductor laser marking is a process that uses a laser marking system to mark semiconductor devices with identifying numbers, barcodes, or logos. The laser marking system directs a beam of high-energy light at the semiconductor device, which heats the surface of the device and causes it to change color. This change in color is used to create the markings that can provide part branding or traceability.

Semiconductor laser marking is an important part of the semiconductor manufacturing process, as it allows for the easy identification of semiconductor devices. In addition, semiconductor laser marking can be used for other purposes, such as part marking and barcoding.

IC packages

Crystal oscillators

Wafers

Moulded packages

Glass epoxy PCB

Wire sheath

Epoxy package

Flexible PCB

Semiconductor manufacturing is the process used to create semiconductor devices, which are electronic components made from semiconductor materials. These materials are typically silicon-based but can also be made from other materials such as germanium, gallium arsenide, or silicon-germanium. The parts are commonly used in computers, hand-held electronic devices (e.g., mobile phones, tablets, and electronic book readers), wearable devices, and consumer electronics.

This manufacturing process starts with wafer fabrication, in which these materials are purified and shaped into thin disks called wafers. These wafers are then subjected to a series of complex processes that add electrical components such as transistors and other circuit elements. Also, many parts require laser marking before they are packaged and shipped to the customer.

Semiconductor manufacturing is a highly complex and precise process, and even small changes in the fabrication process can significantly impact the finished product's performance. That said, using precise and professional equipment is paramount, including the right semiconductor laser marking systems.

These laser marking machines are used to create semiconductor devices such as semiconductor chips, wafers, printed circuit boards (PCBs), integrated circuits (ICs), and other semiconductor devices.

Laser Etching Electronic Components

Considered a subset of laser engraving but not to be confused with its unique process, laser etching entails melting surface material. This creates a process of heating, cooling, and expansion that leaves a detailed mark. The precision and uniformity behind electronic marking are unmatched, but certain characteristics of etching separate the process from the rest.

Here are a few notable characteristics of laser etching:

  • A faster process compared to engraving.
  • Known for relatively shallow markings.
  • Non-contact to help avoid mechanical stressors.
  • Capable of high or low contrast markings on small and large electronic components.
  • Combines efficiency with consistently readable quality in individual and bulk production.

These few examples cover many angles that have helped propel and innovate within the laser marking semiconductor industry. In the same vein, numerous marking technologies deliver unique benefits and processes for etching tasks. From hybrid to UV laser markers, manufacturers can approach etching semiconductors and electronics in a customized way that fits their production needs.

However, aside from its undeniable versatility, etching isn't always the first choice for some manufacturers. There's more than one reason that several laser marking processes, technologies, and techniques exist. Although there are quite a few similarities, it's helpful to understand the core differences in laser engraving applications and processes.

Laser Engraving Electronic Components

Featuring a slightly different process, laser engraving is a part of electronic marking that vaporizes the material's surface while removing layers. This works to create depth in the mark for designs, logos, barcodes, and more for electronic and semiconductor components.

Another standout point is that the final quality can withstand many other manufacturing processes that are common with electronics. A few examples in this context include:

  • E-coating
  • Various heat treatments
  • Shot blasting
  • Electroplating

When it comes to the technologies used for engraving, a variety of electronic marking systems are available to provide different processes and results. For example, many manufacturers utilize fiber laser markers for semiconductor engraving. This is primarily due to its laser wavelength, which is well suited for engraving metal surfaces, as long as they are not heat sensitive.

For those who are new to the topic or simply searching for the most effective process for their needs, it's understandable if there's some trouble in picking a side. Thanks to modern laser marking technologies, you don't always have to choose one over the other. Not only are many laser markers capable of engraving and etching numerous materials, but their efficiency promotes interchangeable manufacturing processes. This gives businesses more flexibility on the production floor.

The full scope of laser engraving applications in the realm of electronics and semiconductors goes a long way. You can say the same for etching processes. Both marking techniques are highly flexible to a variety of marking needs when it comes to semiconductors and a never-ending list of electronics.

Micro and 2D Code marking on IC Chips

Until recently, IC chips were only marked with lot codes. However, a growing need for encoded data has prompted many manufacturers to start using 2D codes. These 2D codes provide unique identification and offer a wealth of encoded data, including batch information, production details, and other relevant information. This transition reflects the industry's commitment to using advanced marking technologies to meet changing requirements and ensure product integrity.

Here are a few common methods for micro and 2D code marking that a semiconductor laser marking machine might use:

Micromarking

Laser markers have a very small beam spot, making them perfect for applications with a limited marking area. Micromarking - which is typically impossible for most systems - can be accomplished with the right laser. Various marking styles can also be selected, from shallow marking to deep engraving. Because of the minuscule sizes of semiconductor components, it enables tasks that were once deemed unattainable by conventional marking systems.

Marking silicon wafer

Silicon wafers are delicate components that require precise marking. It's vital to keep surface damage to a minimum when marking a finished wafer. If not, dust and debris can form. Damage during the marking process can lead to contamination risks, compromising the quality and performance of the finished wafers. That's why UV and green lasers are the optimal wavelengths for these applications. They provide the controlled marking that is needed without causing surface damage.

Marking LED ceramic package

The compact nature of LED ceramic packages poses unique challenges for traditional marking methods. Due to space limitations, ceramic packages often use 2D codes to contain all the necessary traceability information. By incorporating 2D codes on LED ceramic packages, manufacturers can easily embed batch information, production details, and other critical data. This streamlines the tracking and identification process, enhances supply chain visibility and quality assurance efforts, and ensures compliance with industry standards.

Plating and Coating IC Chip Removal

KEYENCE’s 3-Axis laser markers can mark the top surface of IC chips and remove plating or coatings within the same process. Since the laser accurately scans only along the edges of the IC, flash burrs over the leads can be removed without causing damage to the inside of the package.

Removal of gold plating on terminals

To prevent solder wicking, lasers are used to remove the gold plating from connector terminals.
In the past, masks were used to avoid unnecessary plating. Today, connectors are smaller and thinner, and the pitches between the terminals are narrower. Consequently, it has become common practice to apply plating and then remove it with a laser for micron accuracy.

Removal of thin-film coil coating

Previously, removers or edged tools were generally used to remove thin-film coating from coils. Now, laser markers have become useful because they require no consumables and ensure stable results.

Resin coating removal

Chemicals are often used to remove resins on defective molds so that the molds can be analyzed. However, chemicals can damage the internal circuit and require multiple man-hours of work. Using a laser marker to remove resin saves running costs and time.

Benefits of Laser Marking Semiconductor Parts

In the semiconductor industry, semiconductor laser marking is used extensively for part marking. This is because semiconductor laser marking machines offer many advantages over other types of machines.

For example, semiconductor laser marking machines can mark very small parts with a high degree of accuracy. This is a critical requirement of an electronic marking system since the tiny semiconductor components demand microscopic detail.

In addition, semiconductor laser marking machines are very fast, so they can mark large quantities of parts in a short period of time. This allows manufacturers to produce a large quantity of parts within short time frames, which is often needed to meet demand and production schedules.

The process is also highly versatile, allowing for a wide range of semiconductor part designs and markings. This includes silicon wafers, crystal oscillators, lead frames, and IC packages.

Additionally, semiconductor laser marking is an environmentally friendly alternative to other part marking processes, such as labels or screen printing, because it does not use any consumables. As a result, semiconductor laser marking machines are an essential part of the semiconductor industry.

Specific Applications of Laser Etching and Engraving Within the Semiconductor Sector

While the topic of the semiconductor industry is quite broad, etching and engraving serve more of a purpose than just identification alone. From individual components to the packaging they’re shipped in, both semiconductor etching and engraving are being actively used as we speak. For a more in-depth look at specific applications, the bullet points below offer some active use cases of the electronic marking processes.

  • Numerous EV laser marking applications
  • Tamper evidence, as well as anti-counterfeiting for semiconductors and individual components
  • Reliable identification and part traceability
  • Making changes to surface materials for better adhesion, reflectivity, and more
  • Branding and product customization
  • Creating marks that can withstand other harsh machining processes without losing clarity
  • Marking PCB boards and cutting electrical insulation foils that segment components
  • Precision markings for surface mount devices (SMDs)

This list would just continue from there, supported by more points that highlight the capacity and flexibility of the laser marking semiconductor industry. It’s important to mention that getting the most out of these laser marking processes requires working with reliable technology and topical experts.

This is where our support at KEYENCE comes into play. We can help bridge your understanding and application of laser marking technologies, as well as the many manufacturing processes they’re capable of.

KEYENCE - The Right Laser Marking Partner for the Semiconductor Industry

KEYENCE manufactures and develops custom laser marking systems for the semiconductor industry. We serve as an extension of your team to help you improve and automate your factory. Additionally, our knowledgeable team and trained sales force can help solve challenging and technical problems related to semiconductor part marking.

Ready to improve your semiconductor-related processes? Contact us today or view our laser marking systems to learn how we can help.

Application Video

FAQs about Laser Marking in the Semiconductor Industry

What types of lasers are used in wafer manufacturing?

Two of the most common types of lasers used in wafer manufacturing are near-infrared and UV lasers. Historically, near-infrared lasers have been the industry standard, but new developments in UV systems have shifted the needle in their favor.

Why do semiconductor wafers need to be laser-marked?

Traceability is the driving factor behind laser marking in this industry. Semiconductors go through many steps prior to distribution, so it is important to have 100% traceability to ensure each procedure has been met and faulty products are separated before reaching the customer.

What are the challenges of laser marking in the semiconductor industry?

As advancements in this industry continue, components also shrink in size. This level of intricacy highlights the need for premium beam control and limited heat-affected zones. In addition to increasing demand for precision, the general application scope tends towards a more technical need. KEYENCE stands alone in providing local product specialists to work with your team to see how lasers could benefit your process.

How are lasers used in semiconductor manufacturing?

Historically, lasers have been used to mark content for traceability or branding purposes. Recent advancements have opened the door to a new realm of applications when it comes to laser processing. The same lasers used for traceability have the capability to precisely alter surface properties or remove material making lasers a versatile tool for semiconductor manufacturers.

What types of materials can be laser-marked in semiconductor manufacturing?

Laser marking can be performed on a wide range of materials, including silicon, silicon carbide, gallium arsenide, and various types of metals and ceramics.

How does laser marking contribute to quality control in semiconductor manufacturing?

Laser marking provides a permanent and legible mark on semiconductor wafers and components. This ensures accurate identification and traceability throughout the manufacturing process. As a result, it helps to prevent errors, reduce waste, and maintain quality standards.

What factors should be considered when selecting a laser marking system for semiconductor manufacturing?

When choosing an electronic marking system, you should consider laser wavelength, power output, marking speed, beam quality, and the ability to achieve precise marking. Additionally, compatibility with existing manufacturing processes and integration capabilities are important considerations.

Can laser marking be used for other applications besides traceability in semiconductor manufacturing?

Yes, semiconductor laser marking has a wide range of applications beyond traceability, including surface texturing, micro-machining, microstructuring, and surface modification. These capabilities make laser marking a versatile tool for semiconductor manufacturers looking to enhance product performance and functionality.

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