Pacemakers are medical devices that make sure that someone's heart beats the way it should. If the heart rhythm is off, the pacemaker delivers a surge of electricity to bring the heart back into rhythm. The pacemaker takes effort into account and delivers faster pulses when needed. For example, when you’re exercising. For these electric pulses, the pacemaker needs a capacitor to rapidly charge and discharge. This provides a high enough electric charge to reset the heart.

Billions of charges
Researcher Minh Duc Nguyen and his colleagues worked on a new design strategy for these capacitors to improve their energy storage, decrease the amount of energy lost every time it is charged or discharged, and increase the number of times they can reliably charge and discharge. “It needs to keep up with your heartbeat, so it should be able to charge and discharge up to billions of times. Otherwise, you’ll have to replace the pacemaker every few months”, explains Nguyen.

Efficient capacitor
Nguyen and his team work on a type of capacitor that uses multiple thin layers of different materials. By adding layers they were able to increase the efficiency to over 90%. This means it loses less than 10% of the electric charge used for charging. That is two times less energy loss compared to the usual designs. It functions in a wide temperature range of 25–200 °C and can charge and discharge up to 10 billion times. Enough to do it once every second for over 300 years.

Design optimisation rules
The researchers deduced design optimisation rules for the combination of materials they used. “These rules are expected also to be useful for optimizing other multilayer systems and are therefore very relevant for further increasing the energy storage density of capacitors”, they write in their publication. Paving the way for even better capacitors.

More information
Dr. Minh Duc Nguyen is a senior researcher at Inorganic Materials Science (IMS, Faculty of Science and Technology/MESA+), led by Prof. Guus Rijnders. His research focuses on the fabrication of ferroelectric and piezoelectric thin films for biomass sensors, vibrational energy harvesters and pulsed-power energy storage capacitors. The research entitled ‘Towards Design Rules for Multilayer Ferroelectric Energy Storage Capacitors – A Study Based on Lead-Free and Relaxor-Ferroelectric/Paraelectric Multilayer Devices’ was published in the prestigious scientific journal Advanced Materials.
DOI: https://doi.org/10.1002/adma.202402070