Ceramic PCB

Ceramic PCB

What is Ceramic PCB?

The Structure of Ceramic PCB

Ceramic PCB Properties

Ceramic PCB Types

Materials for Ceramic PCB

Ceramic PCB Advantages

Ceramic PCB Disadvantages

Ceramic PCB Applications

Choose SMTFAB as Your Ceramic PCB Fabricator

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Frequently Asked Questions

Ceramic PCB from SMTFAB for Excellent Electrical Properties

Ceramic PCBs are specialized circuit boards that offer superior thermal conductivity, mechanical strength, and electrical insulation compared to traditional FR4 materials. Widely used in high-power and high-frequency applications, these boards are ideal for industries such as aerospace, automotive, medical devices, and telecommunications. SMTFAB Ceramic PCBs support multilayer configurations, thick copper builds, and premium surface finishes. Engineered under strict IPC and RoHS compliance, SMTFAB’s Ceramic PCBs provide a robust solution for demanding electronic environments.

This is a PCB that uses a ceramic base material instead of the fiberglass. In this PCB, copper foil is bonded directly to the surface of ceramics. This is done at high temperatures, which makes the connection strong and stable. These ceramic materials have excellent thermal conductivity, which helps move heat away from the components quickly and evenly.

Ceramic PCBs are used in electronics that deal with high heat. Examples include automotive sensors, power devices, and LED lighting. These boards keep temperatures under control.

While ceramic PCBs are fantastic when it comes to managing heat and ensuring reliability, they do come with some downsides. For one, they tend to be pricier to manufacture and are generally more fragile compared to regular boards. However, if your project requires top-notch thermal performance and consistent operation, ceramic PCBs are definitely a solid and trustworthy choice to think about.

Ceramic Material

This PCB’s main part is the ceramic substrate. This base layer supports all the other components. The choice of ceramic material—such as alumina, aluminum nitride, or beryllium oxide—directly impacts the performance.

Conductors

Copper and other conductive metals are used on the ceramic substrate. These conductive layers form the electrical circuits and pathways that enable signals to travel.

Max Temperature Use

Ceramic PCBs are exceptional in their ability to withstand high temperatures. This PCB can handle temperatures anywhere from 150°C to over 1000°C. This makes them ideal for applications where heat management is a critical factor.

Thermal Conductivity

One of the most remarkable things about Ceramic PCBs is how well they handle heat. These ceramic materials boast an impressive thermal conductivity that can range from 20 W/mK to more than 200 W/mK. This heat management capability is significantly better than what you’d find in traditional FR4 boards.

Breakdown Voltage

Ceramic materials also offer high dielectric strength. This provides excellent electrical insulation, which is crucial in preventing electrical failures. Has a breakdown voltages ranging from 10 kV/mm to over 20 kV/mm.

Thermal Conductivity

Ceramic PCBs move heat away from parts quickly. FR4 PCBs just can’t keep up here. When your board stays cool, it runs better. Parts last longer. Failures drop. Strong thermal conductivity means your board stays efficient under pressure.

Dielectric Constant (Dk)

Ceramic boards also handle signals well. A higher dielectric constant allows faster signal transmission. You can also shrink the board size, which saves space.

CTE & Temperature Resistance

Ceramic doesn’t expand much with heat. That’s important. When parts expand too much, they can break or shift. Ceramic PCBs stay stable even up to 350°C. That’s more than double what FR4 can handle.

Durability & Reliability

These boards are also strong. They’re rigid, solid, and built for tough use. You’ll find them in vehicles, satellites, or industrial machines because they don’t fail easily. Your electronics lasts longer, even in harsh environments.

LAM PCBs – Laser Activation Metallization PCBs use a high-energy laser to bond metal directly to the ceramic surface. The laser basically melts and links the two materials together. This gives you a clean, smooth finish and a strong connection. LAM PCBs are getting more popular now, especially when you need both durability and precision.

DPC PCBs – Direct Plate Copper PCBs use something called physical vapor deposition. It’s a process done in a vacuum that plates thin layers of copper onto the ceramic. The copper can be really thin or quite thick—anywhere from 10 to 140 microns. DPC is great for high heat and high-frequency designs.

DBC PCBs – Direct Bonded Copper PCBs form a solid link between copper and ceramic using heat and a touch of oxygen. This method is often used when you need thicker copper—up to 350 microns. It’s ideal for power electronics where heat and current levels are high.

LTCC PCBs – Low-Temperature Co-fired Ceramic PCBs mix ceramic with glass. This mixture is shaped, dried, and printed with circuits, then baked at around 850 to 900 °C. Gold is usually used for the traces. LTCC is great when you want compact, multilayer boards that stay stable over time.

HTCC PCBs – High-Temperature Co-fired Ceramic PCBs skip the glass altogether. They’re made with raw ceramic and baked at very high heat—about 1600 to 1700 °C. Metals like tungsten or molybdenum are used for the traces since they can take the heat. These are perfect for extreme environments.

Thick Film Ceramic PCB – This one’s all about oxidation control. After coating the ceramic base with copper, gold, or silver, the board is baked at 1000 °C in a nitrogen atmosphere. That protects the materials from breaking down. You can even print resistors and capacitors right onto the board.

Al2O3

Aluminum Oxide, also called Alumina, is the most commonly used ceramic material in PCBs. It’s tough, affordable, and easy to work with. You’ll usually see it in white, but the color can shift depending on its purity—from pink to almost brown. What makes Alumina so useful is its balance of electrical insulation, decent thermal conductivity, and low cost.

AlN

Aluminum Nitride is one of the best ceramic materials and types you can get for thermal performance. It’s a high-end choice, with thermal conductivity values that can reach up to 300 W/m·K. Plus, it has a low coefficient of thermal expansion, which makes it behave similarly to silicon.

BeO

Beryllium Oxide—also known as Beryllia—offers incredibly high thermal conductivity. In fact, it’s only second to diamond when it comes to moving heat efficiently. It’s also a great electrical insulator and can handle extreme temperatures.

SiC

Silicon Carbide is known for its hardness and ability to withstand very high temperatures. It has great thermal conductivity and can handle extreme environments without breaking down. You’ll often find it used in power electronics and high-frequency applications.

Hybrid Ceramic

Hybrid Ceramic PCBs combine different ceramic materials—or sometimes mix ceramic with other substrates—to balance performance and cost. These are customized solutions. So, if your project has unique requirements that one material alone can’t meet, a hybrid setup might be the answer.

1. Great at handling heat – Ceramic PCBs move heat fast. Some materials go up to 330 W/m·K. That’s over 20 times better than FR-4. Your parts stay cooler, longer.
2. Stay stable under heat – These boards don’t swell or shrink much. Even when temps change fast, they stay strong and steady.
3. Protect your parts from heat damage – Ceramic doesn’t let heat spread too easily. That means your board’s tiny parts stay safe.
4. Resist wear and chemicals – Ceramic is inorganic. It won’t break down quickly. It also resists most harsh chemicals.
5. Handle complex circuits – You can stack more layers on ceramic PCBs. It won’t crack or flex. This makes them perfect for heavy-duty use.
6. Work well at high frequencies – Need clean signals at fast speeds? Ceramic can handle it. That’s why it’s used in telecom, medical, and aerospace gear.
7. Better value long term – Sure, they cost more than the regular FR4, but they last longer and need fewer repairs. That saves you money over time.

1. Delicate and fragile – Ceramic is brittle, so it can crack easily. This means extra care is needed during assembly and testing.
2. Expensive – They cost more than FR-4. The materials and production require special equipment, making it more expensive.
3. Brittleness – Ceramic PCBs are more likely to shatter under stress. This can be a problem if the board needs to endure rough handling.
4. Design Change Challenges – Making changes to ceramic PCBs can be tricky. You’ll need to consider the material properties carefully.
5. Requires careful handling – Due to their fragility, ceramic PCBs need to be handled gently during transport and installation to avoid damage.
6. Less availability – Compared to FR-4 PCBs, ceramic PCBs are not as easy to find. Call us to confirm the availability of this PCB.

• Military applications
• Space program components
• High-power laser applications
• High-Current LEDs
• Industrial power equipment
• Printers
• IC arrays
• Semiconductor refrigeration devices
• Audio amplifiers
• High power transistors and transistor arrays
• Solar cell substrates

When you need high-quality ceramic PCBs, SMTFAB is a solid choice. As a trusted ceramic PCB supplier, our Ceramic PCB manufacturing capability covers a wide range of materials and processes. We use Al2O3, AIN, ZTA, and Si3N4 substrates, each offering unique advantages like excellent thermal conductivity and high-temperature resistance. Whether you need insulation, chemical resistance, or low thermal expansion, we have the right option for your project.

We specialize in various types of ceramic PCBs, including DPC, DBC, AMB, LTCC, and HTCC. Our layers can range from single to multi-layer designs. We offer a variety of surface treatments, including OSP, ENIG, immersion silver, and hard gold, to enhance your ceramic board’s durability.

With over 20 years of experience, we at SMTFAB, guarantee top-notch ceramic PCB fabrication for any application. Send us your Gerber files, and BOM, and our team will provide professional free DFM checks to ensure your design is suitable for production.

At SMTFAB, we specialize in high-quality Ceramic PCB manufacturing, offering unmatched thermal conductivity, high-temperature resistance, and exceptional durability. Our advanced manufacturing process utilizes premium substrates so your PCBs perform reliably even under extreme conditions. Whether you need single or multi-layer designs, we provide customizable solutions tailored to your specific needs. From precision drilling to a variety of surface treatments, we guarantee precision and performance in every board. With over 20 years of expertise, SMTFAB is your trusted partner for reliable, high-performance ceramic PCBs. Choose SMTFAB for superior quality and exceptional service every time.

• SMTFAB’s Ceramic PCBs are manufactured using high-performance substrates.
• Supports manufacturing multilayer ceramic and accommodates thick copper.
• Surface finishes include Immersion Silver, Immersion Gold, and Nickel Palladium Gold.
• Superior thermal and mechanical stability.
• Manufactured within adherence of IPC & ROHS Standards.

Ceramic and FR4 PCBs differ mainly in thermal conductivity and cost. Ceramic PCBs provide excellent heat dissipation, making them ideal for high-power applications like LEDs and power supplies. They can handle higher temperatures and are made from materials like alumina and aluminum nitride.

FR4 PCBs, on the other hand, are more affordable and commonly used for general applications where heat isn’t a major issue. Made from glass-reinforced epoxy laminate, they are suitable for lower temperature ranges (up to 115°C).

Ceramic PCBs typically range from 0.25mm to 3.0mm in thickness. However, they can be made thinner or thicker based on your needs. For most consumer electronics, the standard PCB thickness is 1.6mm (or 0.063 inches).

The thickness of ceramic PCBs depends on the application. For high-power or high-heat applications, a thicker board might be needed for better heat dissipation. If you’re working on something more standard, thinner ceramic options could be the way to go.

Ceramic PCBs are impressive when it comes to handling extreme temperatures, often reaching up to 800°C. Some materials, such as aluminum nitride, can even withstand even higher temperatures. This makes them an excellent choice for applications where heat is a major concern. On the other hand, FR4 PCBs, which are widely used in various electronics, can only manage around 170°C.

Ceramic materials like alumina and aluminum nitride are renowned for their ability to resist high temperatures. They also boast a lower Coefficient of Thermal Expansion (CTE) compared to FR4, meaning they’re less prone to warping or distorting when temperatures fluctuate. For instance, alumina offers thermal conductivity between 18 and 36 W/mK, whereas aluminum nitride can exceed an impressive 150 W/mK.