Understanding CTE in PCB: Challenges and Solutions - TechSparks (2025)

In high school physics, we learned about the phenomenon of “thermal expansion and contraction”: when the temperature rises, objects expand, and when the temperature drops, they contract. This principle is not only observed in daily life, such as when metal pipes shrink in cold weather or asphalt roads crack in high heat, but also plays a crucial role in the manufacturing and operation of electronic products, especially in the design and production of printed circuit boards (PCB).

PCB manufacturing involves several high-temperature processes, from lamination to reflow soldering, and final testing. Each temperature change causes materials to expand and contract, leading to stress that could result in electrical issues. Therefore, understanding and managing the coefficient of thermal expansion (CTE) is key to improving PCB reliability and performance.

Understanding CTE in PCB: Challenges and Solutions - TechSparks (1)

The purpose of this article is to systematically analyze the basic concept of CTE in PCB, the challenges posed by differences in material CTE, and how to address these challenges through material selection, design optimization, and thermal management strategies.

Basic Concepts of the CTE

CTE is a physical quantity that describes the change in length, area, or volume of a material per unit temperature change. It is defined as the ratio of the change in length per unit temperature increase of 1°C. Its formula is:

CTE = ΔL / L ΔT

Where L is the initial length of the material, ΔL is the change in length, and ΔT is the temperature change. CTE is typically measured in 10^−6/°C, indicating the number of micrometers a material will expand per meter of length for every 1°C increase in temperature.

The CTE value of a material is influenced by various factors, including chemical composition, crystal structure, and temperature range. Metals generally have a higher CTE, while ceramics and epoxy resin substrates have lower CTE. Additionally, some materials may experience significant changes in CTE over different temperature ranges. For example, the glass transition temperature (Tg) is a critical point, where the CTE of materials, especially PCB substrates, can increase sharply.

Coefficient of Thermal Expansion in PCB

Z-Axis Expansion and Through-Hole Reliability

In PCB structures, the expansion of substrate materials along the Z-axis is significantly higher than that along the XY-axis. For example, in the case of FR4, its Z-axis CTE may dramatically increase to 50–200 ppm/°C near the Tg, while the XY-axis CTE is only around 15 ppm/°C. This uneven expansion creates significant tensile stress on the copper plating inside PCB PTH holes. After multiple thermal cycles, the copper plating may develop stress cracks or delamination.

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Impact of Thermal Cycling

Thermal cycling also has a significant impact on the structural integrity of PCB materials. Each temperature cycle causes materials to expand and contract, and this repetitive change gradually weakens the mechanical strength of solder joints and through-holes. In high-reliability applications (such as aerospace or medical devices), temperature variations may span extreme ranges (-65°C to +125°C), requiring more stringent thermal expansion management for the PCB. Tests show that thermal cycling above Tg is particularly detrimental to PCB. The damage from one thermal overload cycle may be equivalent to the cumulative effect of several normal thermal cycles in the future.

CTE Matching and Material Selection

Substrate Material Selection

To ensure the long-term stability of PCB, selecting the right substrate material is crucial. When choosing materials, their thermal expansion characteristics at different temperatures, as well as the CTE matching with other components, are important factors. For example, FR4, the most commonly used PCB substrate, has a moderate CTE, but when exposed to significant temperature changes, its Z-axis expansion may cause severe stress accumulation. Therefore, in high-reliability applications, materials such as polyimide (PI) or ceramic substrates are often chosen, as they exhibit lower CTE in high-temperature environments and can effectively reduce problems caused by thermal expansion mismatches.

Challenges of CTE Matching

CTE matching between materials is a critical issue in PCB design. If the CTE difference between the substrate and components is too large, it may lead to cracks and connection failures when temperature changes occur. As a result, designers need to find a balance between the CTE of different materials when selecting components and substrates. For example, during packaging, materials with high thermal conductivity and good CTE matching are often used to ensure thermal expansion coordination between components and the substrate. CTE matching is especially important for certain packages, such as BGA (Ball Grid Array) or CSP (Chip-Scale Packaging), where components are particularly sensitive to temperature changes.

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Choosing the Right Solder

The choice of solder also directly impacts PCB thermal expansion performance. Traditional solders, such as lead-tin alloys, are good at resisting temperature variations. However, due to environmental regulations, many manufacturers have switched to lead-free solders. While lead-free solders meet environmental requirements, they generally have a higher CTE. Therefore, when using lead-free solders, it’s crucial to optimize the soldering process and ensure that the thermal expansion characteristics of the material match the PCB substrate and components.

Design Strategies to Reduce CTE Differences

Using Multi-Layer PCB Design

Multi-layer PCB is an effective strategy to reduce the impact of CTE differences. In multi-layer design, carefully designing the thermal expansion match between substrate layers can effectively reduce stress accumulation caused by temperature differences. For example, using substrate materials with different CTE for different layers can achieve thermal expansion balance between the layers, thus improving the overall reliability of the PCB.

Adopting Thermal Management Technologies

Thermal management plays an important role in reducing the impact of CTE differences. By designing heat sinks, thermal vias, and other structures, generated heat can be effectively dissipated during operation, preventing uneven expansion caused by localized overheating. Good thermal management not only improves the thermal expansion performance of components but also extends the lifespan of electronic devices.

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Optimizing Soldering Processes

Optimizing soldering processes is critical to reducing solder joint fatigue. By controlling soldering temperature, time, and the rate of temperature change during soldering, solder joint thermal stress can be reduced effectively. Additionally, using appropriate solder materials, such as those with low expansion rates, can reduce solder joint stress, improving their reliability.

Ending

In PCB design, managing the differences in the coefficient of thermal expansion (CTE) is crucial for ensuring the reliability and performance of electronic devices. Material selection, soldering processes, and thermal management strategies are effective ways to minimize problems caused by CTE differences. As electronic devices continue to evolve towards higher integration, smaller sizes, and greater performance, addressing the challenges posed by CTE differences will become an increasingly important issue in future PCB design.

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Understanding CTE in PCB: Challenges and Solutions - TechSparks (2025)

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