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Researchers at the Technical University of Denmark (DTU) are using simulation apps to predict corrosion and design electronics proactively to mitigate or withstand its effects.

By Joseph Carew
May 2026

In pursuit of improved range, greater reliability, and faster charging, electric vehicles are driving the demand for high-voltage electronics. Other applications driving this demand include wind farms, data centers, and server farms, to name a few. As the interest for high-voltage electronics increases, the risks associated with their sudden failure must be considered. Much of what causes high-voltage equipment to malfunction can be linked to the conditions of the climate in which it operates. Specifically, condensation on electronic surfaces caused by humidity can lead to corrosion, which can result in stray leak current and dendrite shorting during Electrochemical Migration (ECM). Predicting, mitigating, and helping proactively design to account for corrosion is the focus of the Centre for Electronic Corrosion (CELCORR) research group at the Technical University of Denmark (DTU). The group's researchers are working with industry partners to develop models and simulation apps that will help in building robust electronics designs. Their goal is to develop knowledge that can be used for manufacturing electronics to withstand humid operating conditions.

Electronic Failure: "It's Not the Heat; It is the Humidity"

Automotive electrification and renewable energy systems rely on electronics at all stages of the energy chain. When these electronics, such as the example PCB in Figure 1, are exposed to the effects of moisture, they can become potential failure points. "Anywhere you are producing, converting, transporting, and using energy, you need these high-power electronic systems that get affected by the humidity," explained Dr. Rajan Ambat, DTU professor and manager of CELCORR. Ambient moisture can seep into the devices and machines that require these electronics and cause unexpected functional issues through corrosion. When these electronics are involved in particularly high-voltage applications (such as wind farms, data centers, electric vehicles, and server farms), failure due to humidity exposure can even lead to fire.

"There might be a situation where somebody installs a solar panel near the seashore or in an area with high humidity, and within a short period of time, a conducive condition forms inside the electronics that results in a failure," Ambat said. "This is why we need to understand exactly how the conducive condition of condensation is created, when the condition is created, and how the system is failing."

Two simulations showing electrolyte potential on a PCB (top) and current density distributions on a PCB (bottom).

Figure 1. The electrolyte potential and current density distributions on a PCB surface (with pinholes).

Identifying corrosion as the underlying cause of some electronic failures is still a challenge. "Fifty percent of failures in electronics are currently branded with an unidentified root cause," Ambat explained. "When engineers open up the system, they do not realize that the failure was due to corrosion, because moisture disappears without leaving any sign of corrosion unless there is ECM dendrite formation." This lack of awareness was a strong motivator for CELCORR, which turned to multiphysics simulation as a supplementary tool to help its partner organizations to better predict humidity-related issues at the design stage.

Modeling Moisture and Measuring Parameter Changes in PCBs

CELCORR believes the best way to identify and avoid electronic failures is to build more effective designs that better prevent corrosion from developing or can withstand a higher humidity load. Its research team applies its expertise in modeling to generate simulation apps that will help partner industries to evaluate safe designs for humidity robustness.

"We are at the intersection of materials science and the electronics industry. We work as a bridge between materials and electronics disciplines, using both kinds of language," Dr. Anish Rao Lakkaraju, a postdoctoral researcher at CELCORR, explained.

To understand potential design issues, Ambat emphasized the importance of virtually breaking down systems to identify where problems may arise. "We need simulation software to analyze potential uses of designs and whether new designs are good or bad," Ambat said.

Using the COMSOL Multiphysics^® software for investigation, the CELCORR research team together with other research partners (Aalborg University) built an example model with a simple PCB geometry that matched both its test circuit boards as well as the design of a device used by one of its partner companies. The team then added a water film layer on top to act as the relative humidity. From there, the team could introduce variation. "We change the layout, geometry, distance between electrodes, thickness of the water film, and conductivity of the water film depending on the conditions," Ambat said.

Ambat and his team generate data on the effect of these variations and can identify which has the greatest impact on the device's performance and whether any alterations can improve the device's anticorrosion robustness. "We assume there is condensation forming on the electronic surfaces (Figure 2) and compute the electrochemical leak current for different design elements," Ambat said. "The value of the computed electrochemical current between the parts will give us an indication of whether the PCB will be affected or not."

A simulation of a water film condensation effect on a PCB.

Figure 2. A 10-µm water film condensation effect on an example PCB.

Altering the design elements and solving the model equations again and again allows the team to better understand what makes a design effective. "Now, we are at the current form of the model, and we are quite happy with where the physics are at this point," Lakkaraju said. This modeling, however, was just the first part of CELCORR's overarching goal of illuminating the destructive potential of corrosion in electronics and the best ways to avoid it.

Using Simulation Apps to Test Real-World Designs

To open up and ease access to these models, CELCORR used the Application Builder in COMSOL Multiphysics^® to create simulation applications for the members of the industrial consortium. Built with a simple 3D circuit board geometry with two oppositely biased electrodes and a water layer to replicate corrosion-causing moisture, the apps provide a pared-back, straightforward interface where users can vary model inputs. "We focused on fundamental aspects," Lakkaraju said. "We boiled down our partners' overarching concerns to create two apps with very simple geometries and the simplistic stuff that can be varied over multiple parameters."

The simple simulation apps shown in Figures 3 and 4 are designed to show companies how the distance between the electrodes and the thickness of the moisture layer affect the leak current through the water film depending on different parameters. By analyzing multiple design elements and parameters, users can determine the relative benefits of certain design elements on the humidity robustness. "The apps we have built have really helped because they give the electronics engineers a plug-and-play sort of approach," Lakkaraju explained.

The user interface for one of CELCORR's simulation app, which includes input fields for electrode width, electrode depth, electrode height, water layer height, pitch distance, electrolyte conductivity, and anode voltage. An angled view of the model is shown.

Figure 3. The UI of CELCORR's standalone app showing the inputs that users can alter.

"By using this app [Figure 3], companies have unlimited freedom to work with these sorts of variables," Lakkaraju added. "This would be quite difficult to recreate in real life with physical design and testing, and the companies we work with are quite happy with the level of accuracy the app can provide."

The user interface for one of CELCORR's simulation app, with a streamline plot in the Graphics window.

Figure 4. The UI of one of the simulation apps showing a streamline plot with inputs such as the cathode voltage and blockage length.

Looking Forward: Complex, High-Voltage Modeling

Alongside its collaboration with the industry consortium, CELCORR is also working toward improving the world's general understanding of corrosion's impact on electronics. To do this, Ambat and his team are undertaking multiple projects, including actively adding greater complexity to their models. In a tertiary current distribution model they are building, the team is drilling down into each of the basic inputs used in a secondary current distribution model, zooming in to examine the effects of the set of even more detailed inputs each basic input comprises.

"The next point is to study what each of these detailed inputs does," Lakkaraju said. In particular, the team is examining mass transport properties and the chemical reactions’ rate constants.

In addition to these ongoing studies, CELCORR is expanding the scope of its research to investigate corrosion in high-power, high-voltage systems. Thanks to a 2024 grant from the Grundfos Foundation, CELCORR was able to establish the Centre for Climate Robust Electronics Design (CRED). The center's lab facilities and expertise are being developed to address the humidity-robustness requirements of today's high-voltage and high-power electronic equipment. "Using CELCORR’s uniquely deep understanding of materials and corrosion, we are equipped to find the root cause and provide knowledge for environmentally robust designs," said Ambat.

For all of its investigation, CELCORR continues to rely on the agility of the COMSOL Multiphysics^® software. As Lakkaraju explained, "It is really quite nice how a model can be adapted to a variety of combinations of materials, geometries, and parameters and how the software allows you to keep building on from there."