Microchip capability expanded with new 3D inductor technology
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Smaller is better when it comes to microchips, researchers said, and by using 3D components on a standardized 2D microchip manufacturing platform, developers can use up to 100 times less chip space. A team of engineers has boosted the performance of its previously developed 3D inductor technology by adding as much as three orders of magnitudes more induction to meet the performance demands of modern electronic devices. Engineers introduce a microchip inductor capable of tens of millitesla-level magnetic induction. Using fully integrated, self-rolling magnetic nanoparticle-filled tubes, the technology ensures a condensed magnetic field distribution and energy storage in 3D space all while keeping the tiny footprint needed to fit on a chip.
Traditional microchip inductors are relatively large 2D spirals of wire, with each turn of the wire producing stronger inductance. In a previous study, research group developed 3D inductors using 2D processing by switching to a rolled membrane paradigm, which allows for wire spiralling out of plane and is separated by an insulating thin film from turn to turn. When unrolled, the previous wire membranes were 1 millimetre long but took up 100 times less space than the traditional 2D inductors. The wire membranes reported in this work are 10 times the length at 1 centimetre, allowing for even more turns and higher inductance while taking up about the same amount of chip space.
A longer membrane means more unruly rolling if not controlled," researcher said. "Previously, the self-rolling process was triggered and took place in a liquid solution. However, we found that while working with longer membranes, allowing the process to occur in a vapour phase gave us much better control to form tighter, more even rolls. Another key development in the new microchip inductors is the addition of a solid iron core. "The most efficient inductors are typically an iron core wrapped with metal wire, which works well in electronic circuits where size is not as important of a consideration, But that does not work at the microchip level, nor is it conducive to the self-rolling process, so we needed to find a different way. To do this, the researchers filled the already-rolled membranes with an iron oxide nanoparticle solution using a tiny dropper. Though a significant advance on earlier technology, the new microchip inductors still have a variety of issues that the team is addressing, researcher said.
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