UCLA researchers in the Department of Electrical Engineering have developed a novel batch microfabrication technique for microscale shielding layers, simultaneously pushing the limits of minimum size, maximum shielding factor, flexibility, and cost.
Compact electromagnetic shielding paves the way for a new generation of high precision systems, such as for atomic, molecular, and optical (AMO) technology, where long term stability of atomic sensors is desirable for timing and navigation. Magnetic shields are conventionally machined single or multi-layer structures, resulting in costly and bulky shields best suited for macro-scale enclosures. There exists a need for a microfabrication process that allows cost and time effective fabrication for micro-scale magnetic shields.
UCLA researchers in the Department of Electrical Engineering have developed a novel microfabrication technique for rapid and automated alternating electrodeposition between Permalloy and copper baths for batch microfabrication of microscale shielding layers, leveraging parallelism to simultaneously push the limits of minimum size, maximum shielding factor, flexibility, time and cost. The invented microfabrication technique achieved the largest reported shielding factor of 4500, and the first ever chip-scale shielding factor of 100 using batch microfabrication.
|United States Of America||Published Application||20190244831||08/08/2019||2018-014|
magnetic shielding, electro-plated shielding, batch microfabrication, chip-scale fabrication, AMO, shielding factor, parallel, electromagnet, atomic sensor, multi-layer