Magneti Ljubljana’s research while affiliated with University of Ljubljana and other places

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Publications (1)

Fig. 1. Optical micrographs of the as-cast microstructures of samples 1–5 ( f 1⁄4 Nd 2 Fe 14 B). 
Fig. 2. Effect of processing temperature on the intrinsic coercivity.
Fig. 3. Effect of processing temperature on the remanent magnetization.
Fig. 4. SEM microstructure of (a) alloy 3, sintered at 800 1 C, and (b) alloy 4, sintered at 800 1 C. 
Fig. 5. Effect of reducing the thickness of the samples on the coercivity.

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100-μm-thick Nd–Fe–B magnets for MEMS applications produced via a low-temperature sintering route
  • Article
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October 2006

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340 Reads

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13 Citations

Journal of Magnetism and Magnetic Materials

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Magneti Ljubljana

Magnetic micro-actuators and systems (MAGMAS) require tiny permanent magnets with dimensions of hundreds of micrometers. Such magnets need to have the highest possible energy density, which means Nd–Fe–B magnets are the most appropriate type. Most bottom-up fabrication techniques are either too slow or too expensive; top-down techniques involving machining tend to result in surface damage and a loss of magnetic properties. In this study, we have looked at very neodymium-rich Nd–Fe–B powders that allow us to sinter 100-mm-thick samples to full density at temperatures as low as 800 1C. These very thin magnets have coercivities of up to 1000 kA m À1 and are suitable for MAGMAS-type applications.

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Citations (1)

... Development and size reduction are moving forward in small electronic devices such as MEMS (Micro Electro Mechanical Systems) devices and miniaturized motors comprising of film magnets thicker than several ten microns have been developed. [1][2][3] We have already prepared isotropic rare-earth thick films (≤1200 μm) by using Pulsed Laser Deposition (PLD) method and applied them to small electronic devices. [4][5][6] On the other hand, we have fabricated anisotropic rare-earth film magnets by substrate heating. ...

Reference:

Effect of laser power on structural and magnetic properties of anisotropic Nd-Fe-B film magnets prepared by PLD method
100-μm-thick Nd–Fe–B magnets for MEMS applications produced via a low-temperature sintering route

Journal of Magnetism and Magnetic Materials

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Magneti Ljubljana