Ceramic vs. FR4 Multilayer PCBs: When to Use Either and How

Zachariah Peterson
|  Created: September 7, 2018  |  Updated: January 18, 2024
Ceramic vs. FR4 Multilayer PCBs: When to Use Either and How

Ceramic materials electronics are specialty materials used as PCB insulators and as substrates for IC packages. Today, ceramic production capacity for PCBs is easy to access from overseas vendors, and these materials see significant use in aerospace and automotive industries.

Ceramic PCBs offer particular advantages over FR4 boards, although there is no single “ceramic” material. The current set of commercialized ceramic materials for PCBs are alumina (Al2O3), aluminum nitride (AlN), beryllium oxide (BeO), boron nitride (BN), and silicon carbide (SiC); the first three in this list are most common as their fabrication procedure has been adapted from the IC packaging world.

If you’re considering when to use a ceramic PCB substrate instead of a standard FR4 PCB, read this guide to learn more about the usage of these materials.

Ceramic vs. FR4 Material Properties

There are two big differences between ceramic materials and epoxy-resin materials (such as FR4 or related organic materials):

Obviously there are other material differences that affect processing and operation, such as differences in dielectric constant, CTE value, and glass transition temperature. But for the most part, the main selection criteria that drives usage of ceramic PCBs is the above two material properties.

Thermal Conductivity

The biggest difference between FR4 and ceramic materials is their thermal conductivity. FR4 has very low thermal conductivity compared to the ceramic materials used for a circuit. If you are familiar with chemistry and physics, you may know that thermally conductive materials tend to also be good electrical conductors. Ceramics buck this trend, meaning their electrical conductivity is still low enough that these boards can be used for PCB substrates.

Ceramic material

Thermal conductivity

Alumina

~20x FR4

Aluminum nitride and silicon carbide

~100x FR4

Beryllium oxide and boron nitride

Greater than 100x FR4

Dielectric Constant

Dielectric constant values for ceramics generally vary wildly from very low values to very high values. For example, the only way small case ceramic capacitors can reach meaningful capacitance values is with ceramics that have very high Dk values. Similarly, in PTFE laminates, ceramic fillers are used to tune the dielectric constant of the material

Ceramic material

Dielectric constant

Alumina

9.0 to 10.0

Aluminum nitride

8.6 to 9.0

Silicon carbide

~9.66 (Cubic SiC: ~9.72)

Beryllium oxide

~6.76

Boron nitride

3.3 to 3.8 at low frequencies

Aside from boron nitride, all the values presented above are higher than FR4 dielectric constant and are comparable to some ceramic-filled PTFE laminates used in RF devices. The higher-Dk ceramic materials can be useful in many instances, such as in RF systems requiring printed circuits operating at low frequencies. In these devices, a higher Dk value allows the physical size of the circuit to be smaller because signal wavelengths are smaller when Dk is larger.

The point not mentioned above is loss tangent and dispersion, which can very significantly. Loss tangent data in various frequency ranges can be found in the research literature, some of which is free online. Note that the dispersion can be very large for ceramic materials; for example, in boron nitride, the dielectric constant rises to ~4.5 near 9 GH, a level of dispersion which is significantly larger than what is seen in FR4 laminates.

Multilayer Ceramic PCB Manufacturing

1. Tape Casting and Hole Formation

First, ceramic powders are mixed with organic binding agents and cast into the board shape with tape. This is a doctor blade process with a stencil (can be a taped stencil) that allows the thickness to be controlled within a specific stencil area. Once the ceramic slurry dries and hardens, holes are punched into the unfired ceramic to form room for vertical interconnects. Via sizes in ceramic substrates can be of similar size as those used in organic substrates.

2. Metal Paste Screen Printing

The metallization process for ceramic PCBs requires the use of a conductive paste to define traces and vertical interconnects in each layer (usually silver or gold paste). Copper pastes are also available for screen-printed electronics (such as transparent PET substrates); contact your manufacturer if copper is a preferred material. For fine-line designs on ceramic substrates, the printed feature size and resolution will be limited by the screen printer’s capabilities.

Metal screen print

3. Stackup and Co-firing

Once the ceramic layers have been printed, they are stacked in the appropriate order and the entire stack is fired in an oven. The firing temperature required to bake the ceramic board can reach near 1000 °C, which matches the sintering temperature of the material of gold and silver pastes. Multiple ramp and soak cycles may be required to fully crystallize the ceramic material to its required crystal state. Once completed, the fabricated PCB can have a solder mask applied, and it will be inspected before assembly.

Ceramic kiln

Your ceramic PCB might be fired in an oven like this

To summarize, there are a few major instances where ceramic PCBs are desirable:

  • In very high temperature operating environments, where the PCB will act like a heat spreader
  • In environments where the mechanical rigidity is needed to withstand vibration
  • In RF systems where smaller circuit sizes are desired at low frequencies

The extensive design, simulation, and analysis features in Altium Designer® give you the power to build PCBs from any material, including ceramics. Now you can download a free trial and find out if Altium Designer is right for you. Talk to an Altium expert today if you want to learn more.

About Author

About Author

Zachariah Peterson has an extensive technical background in academia and industry. He currently provides research, design, and marketing services to companies in the electronics industry. Prior to working in the PCB industry, he taught at Portland State University and conducted research on random laser theory, materials, and stability. His background in scientific research spans topics in nanoparticle lasers, electronic and optoelectronic semiconductor devices, environmental sensors, and stochastics. His work has been published in over a dozen peer-reviewed journals and conference proceedings, and he has written 2500+ technical articles on PCB design for a number of companies. He is a member of IEEE Photonics Society, IEEE Electronics Packaging Society, American Physical Society, and the Printed Circuit Engineering Association (PCEA). He previously served as a voting member on the INCITS Quantum Computing Technical Advisory Committee working on technical standards for quantum electronics, and he currently serves on the IEEE P3186 Working Group focused on Port Interface Representing Photonic Signals Using SPICE-class Circuit Simulators.

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