Abstract
Powder-based techniques are gaining increasing interest for the fabrication of microstructures on planar substrates. A typical approach comprises the filling of a mold pattern with micron-sized particles of the desired material, and their fixation there. Commonly powder-loaded pastes or inks are filled into the molds. To meet the smallest dimensions and highest filling factors, the utilization of dry powder as the raw material is more beneficial. However, an appropriate automated technique for filling a micro mold pattern with dry micron-sized particles is missing up to now. This paper presents a corresponding approach based on the superimposition of high- and low-frequency oscillations for particle mobilization. Rubber balls are utilized to achieve dense packing. For verification, micromagnets are created from 5 µm NdFeB powder on 8” Si substrates, using the novel automated mold filling technique, as well as an existing manual one. Subsequent atomic layer deposition is utilized to agglomerate the loose NdFeB particles into rigid microstructures. The magnetic properties and inner structure of the NdFeB micromagnets are investigated. It is shown that the novel automated technique outperforms the manual one in major terms.
Highlights
Powder-based techniques are of particular interest for microelectromechanical systems (MEMS), since they allow the creation of three-dimensional (3D) structures with dimensions between tens and hundreds of microns, from a broad range of materials
Paowder-based techniques are of particular interest for microelectromechanical sys-tems (MEMS), since they allow the creation of threedimensional (3D) structures with di-mensions between tens and hundreds of microns, from a broad range of materials
A mold pattern was created by deep reactive ion etching (DRIE) of the 725-μm-thick Si substrate on a SPTS Pegasus using deep reactive ion etching (DRIE) of the 725-μm-thick Si substrate on a SPTS Pegasus using a resist mask
Summary
Powder-based techniques are of particular interest for microelectromechanical systems (MEMS), since they allow the creation of three-dimensional (3D) structures with dimensions between tens and hundreds of microns, from a broad range of materials. The filling of a mold pattern within a planar substrate with particle-loaded inks or pastes by spin coating, squeegee coating, or molding and subsequent solidification of the matrix material by heat treatments, for example, is widely applied [4]. After filling the dry powder into a micro mold pattern (step I), the 2 of loose particles must be fixated permanently using a dedicated technique (step II). An adequate method for step thefabrication filling of micro molds powder, is still missed. Step I: fill spreading of dry powder substrate with micro mold pattern basically comprises two steps. Dry films on flat surfaces, or for tape casting (see Figure 2a,b). It is shown that the novel automated technique outperforms the manual one in major aspects
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