Title :
Integrated Magnetic Nanoinductors
Author :
Seilis, Aaron ; Moghadas, Hamid ; Moez, Kambiz ; Daneshmand, Mojgan
Author_Institution :
Ciena Corp., Ottawa, ON, Canada
Abstract :
This paper demonstrates the feasibility of the realization of on-chip inductors for use in microwave and millimeter-wave devices using ultraminiaturized on-chip vertical nanohelices. The inductors are constructed by depositing a thin film of closely packed, vertically aligned Nickel nanohelices. The film is fabricated using a CMOS-compatible glancing angle physical vapor deposition method. The resulting nanostructured inductors are characterized from 10 to 70 GHz and are found to have inductances of 6 pH/μm2, 60 times larger than conventional on-chip planar spiral inductors. A quality factor of three is measured and the results indicate that it continues to improve above 70 GHz, while inductance values remain relatively constant. The proposed nanostructured inductors can significantly reduce the chip area, and consequently the cost, of radio frequency and millimeter-wave integrated circuits. In addition, the nanostructured inductors offer significantly larger operation bandwidth than on-chip planar structures operating at frequencies above 100 GHz.
Keywords :
CMOS integrated circuits; magnetic circuits; magnetic devices; microwave integrated circuits; millimetre wave integrated circuits; nanostructured materials; thin film circuits; thin film inductors; vapour deposition; CMOS-compatible glancing angle physical vapor deposition method; frequency 10 GHz to 70 GHz; integrated magnetic nanoinductor; microwave device; millimeter-wave device; millimeter-wave integrated circuit; nanostructured inductor; on-chip inductor; on-chip planar spiral inductor; on-chip planar structure; packaging; quality factor; radiofrequency integrated circuit; thin film deposition; ultraminiaturized on-chip vertical nanohelices; vertically aligned nickel nanohelices; Arrays; Conductivity; Inductance; Inductors; Nickel; System-on-chip; Wires; Glancing angle deposition; inductors; magnetic materials; millimeter-wave measurements; millimeter-wave measurements.;
Journal_Title :
Components, Packaging and Manufacturing Technology, IEEE Transactions on
DOI :
10.1109/TCPMT.2015.2426111
