Title :
Wafer-level fabrication of high-power-density MEMS passives based on silicon molding technique
Author :
Li, Jiping ; Ngo, Khai D T ; Lu, Guo-Quan ; Xie, Huikai
Author_Institution :
Dept. of Electr. & Comput. Eng., Univ. of Florida, Gainesville, FL, USA
Abstract :
This paper reports a novel MEMS fabrication technology that can integrate toroidal inductors or transformers into silicon substrate. Such toroidal windings are realized by electroplating copper to form 200 μ-deep through-silicon vias (TSVs) and 60 μ-thick copper lines on both sides of the silicon substrate. Meanwhile, the magnetic core is formed by filling deep silicon trenches with a composite of magnetic powders and a polymer. A 13 × 13 × 0.32 mm3 toroidal inductor with a measured inductance of 160 nH has been fabricated. The Q factor of this inductor is 10.5 at 14 MHz. Toroidal transformers with Polyimide as the dielectric material between stacked windings were also fabricated.
Keywords :
copper; dielectric materials; electroplating; elemental semiconductors; micromechanical devices; moulding; polymers; silicon; three-dimensional integrated circuits; MEMS fabrication technology; Q factor; TSV; copper; deep silicon trenches; dielectric material; electroplating; frequency 14 MHz; high-power-density MEMS passives; magnetic core; magnetic powder; polyimide; polymer; silicon molding technique; silicon substrate; size 200 micron; size 60 micron; through-silicon vias; toroidal inductor; toroidal transformer; toroidal windings; wafer-level fabrication; Copper; Inductors; Magnetic cores; Polyimides; Silicon; Substrates; Windings;
Conference_Titel :
Integrated Power Electronics Systems (CIPS), 2012 7th International Conference on
Conference_Location :
Nuremberg
Print_ISBN :
978-3-8007-3414-6
