Title :
Permeability Enhancement by Multilayer Ferromagnetic Composites for Magnetic-Core On-Chip Inductors
Author :
Shah, Umer ; Liljeholm, Jessica ; Ebefors, Thorbjorn ; Oberhammer, Joachim
Author_Institution :
Dept. of Micro & Nanosyst., KTH R. Inst. of Technol., Stockholm, Sweden
Abstract :
This letter reports about unpatterned ferromagnetic NiFe/AlN multilayer composites used as advanced magnetic core materials for on-chip and interposer integrated inductances. The proposed composite structure reduces RF induced currents and thus pushes the permeability cutoff to beyond 3.7 GHz, which is by a factor of 7.1 higher than for homogeneous NiFe layers of same thickness. To the best knowledge of the authors, we achieve the highest effective relative permeability of 28 at 1 GHz, highest ferromagnetic resonance frequency and highest inductance enhancement factor above 1 GHz ever reported for devices based on on-chip unpatterned NiFe magnetic cores. A single loop inductor is also implemented as a technology demonstrator, achieving an inductance enhancement of 4.8 and a quality factor enhancement of 4.5 at 400 MHz.
Keywords :
Q-factor; aluminium compounds; composite materials; ferromagnetic materials; ferromagnetic resonance; inductors; iron alloys; magnetic cores; multilayers; nickel alloys; permeability; NiFe-AlN; ferromagnetic resonance frequency; frequency 1 GHz; frequency 3.7 GHz; frequency 400 MHz; inductance enhancement factor; magnetic core materials; magnetic core on-chip inductors; multilayer ferromagnetic composites; permeability enhancement; quality factor enhancement; III-V semiconductor materials; Inductance; Inductors; Magnetic multilayers; Magnetic resonance; Nonhomogeneous media; Permeability; Magnetic materials; NiFe multilayer composite; micromachined inductors; microstrip; permeability; permittivity;
Journal_Title :
Microwave and Wireless Components Letters, IEEE
DOI :
10.1109/LMWC.2014.2341037
