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| Naji, M. |
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Gojdka, Björn
Fraunhofer Society
in Cooperation with on an Cooperation-Score of 37%
Topics
Publications (6/6 displayed)
- 2022Investigation of Wafer-Level Fabricated Permanent Micromagnets for MEMScitations
- 2022Towards Robust Thermal MEMS: Demonstration of a Novel Approach for Solid Thermal Isolation by Substrate-Level Integrated Porous Microstructurescitations
- 2012Vapour phase deposition of highly crystalline self-poled piezoelectric nylon-11citations
- 2012New Concepts for Functional 0-3 Nanocomposites and Magnetic Field Sensors ; Neue Konzepte für funktionelle 0-3 Nanokomposite und Magnetfeldsensoren
- 2012A critical evaluation of the 0–3 approach for magnetoelectric nanocomposites with metallic nanoparticlescitations
- 2012Highly versatile concept for precise tailoring of nanogranular composites with a gas aggregation cluster sourcecitations
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article
Investigation of Wafer-Level Fabricated Permanent Micromagnets for MEMS
Abstract
Monolithic integration of permanent micromagnets into MEMS structures offers many advantages in magnetic MEMS applications. A novel technique called PowderMEMS, based on the agglomeration of micron-sized powders by atomic layer deposition (ALD), has been used to fabricate permanent micromagnets on 8-inch wafers. In this paper, we report the fabrication and magnetic characterization of PowderMEMS micromagnets prepared from two different NdFeB powder particle sizes. A remanence of 423 mT and intrinsic coercivity of 924 mT is achieved at the low ALD process temperature of 75 °C, making this process compatible with MEMS technology. The magnetic reversible mechanism in the micromagnets is discussed with the help of the Wohlfarth equation. To ensure the operability of such integrated micromagnets in different application environments, we conducted a set of experiments to systematically investigate the thermal and corrosive stability. NdFeB micromagnets with larger powder particle size (d50 = 25 μm) exhibit high thermal stability in air. Furthermore, the corrosion stability of the micromagnets is significantly improved by an additional silicon oxide passivation layer deposited by plasma-enhanced chemical vapor deposition (PECVD). The presented results demonstrate the durability of PowderMEMS micromagnets, enabling their application in various fields, e.g., microfluidics, sensors, actuators, and microelectronics. ; 13 ; 5