Miniaturized Liquid Crystal Slow Wave Phase Shifter Based on Nanowire Filled Membranes

This letter presents the realization of a miniaturized liquid crystal slow wave phase shifter at <inline-formula> <tex-math notation="LaTeX">V </tex-math></inline-formula>-band. It is based on a microstrip topology, where the ground plane is realized by a porous alu...

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Published inIEEE microwave and wireless components letters Vol. 28; no. 8; pp. 681 - 683
Main Authors Jost, Matthias, Gautam, Jay S. K., Gomes, Leonardo G., Reese, Roland, Polat, Ersin, Nickel, Matthias, Pinheiro, Julio M., Serrano, Ariana L. C., Maune, Holger, Rehder, Gustavo P., Ferrari, Philippe, Jakoby, Rolf
Format Journal Article
LanguageEnglish
Published IEEE 01.08.2018
Institute of Electrical and Electronics Engineers
Subjects
Copper
Dielectrics
Electric power
Engineering Sciences
Glass
liquid crystal (LC)
Microstrip
millimeter-wave
Phase measurement
phase shifter
Phase shifters
slow wave
Transmission line measurements
5G
slow wave
liquid crystal (LC)
millimeter-wave
phase shifter
Online AccessGet full text
ISSN1531-1309
1558-1764
DOI10.1109/LMWC.2018.2845938

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Abstract This letter presents the realization of a miniaturized liquid crystal slow wave phase shifter at <inline-formula> <tex-math notation="LaTeX">V </tex-math></inline-formula>-band. It is based on a microstrip topology, where the ground plane is realized by a porous alumina membrane filled with metallic nanowires, all of them being connected with each other by a metallic ground plane at the membrane's back. While the magnetic field can pass the nanowires almost unperturbed, the electric field is confined in between the signal electrode and the tips of the nanowires. After deembedding, the meander line phase shifter shows a matching always better than −10 dB, while exhibiting an insertion loss between 1.5 and 2.5 dB from 40 to 67 GHz. This results in a figure-of-merit for passive phase shifters of 33 dB to 45°/dB, accompanied with a phase shift of 55°-100°.
AbstractList This letter presents the realization of a miniaturized liquid crystal slow wave phase shifter at <inline-formula> <tex-math notation="LaTeX">V </tex-math></inline-formula>-band. It is based on a microstrip topology, where the ground plane is realized by a porous alumina membrane filled with metallic nanowires, all of them being connected with each other by a metallic ground plane at the membrane's back. While the magnetic field can pass the nanowires almost unperturbed, the electric field is confined in between the signal electrode and the tips of the nanowires. After deembedding, the meander line phase shifter shows a matching always better than −10 dB, while exhibiting an insertion loss between 1.5 and 2.5 dB from 40 to 67 GHz. This results in a figure-of-merit for passive phase shifters of 33 dB to 45°/dB, accompanied with a phase shift of 55°-100°.
This letter presents the realization of a miniaturized liquid crystal slow wave phase shifter at V -band. It is based on a microstrip topology, where the ground plane is realized by a porous alumina membrane filled with metallic nanowires, all of them being connected with each other by a metallic ground plane at the membrane's back. While the magnetic field can pass the nanowires almost unperturbed, the electric field is confined in between the signal electrode and the tips of the nanowires. After deembedding, the meander line phase shifter shows a matching always better than -10 dB, while exhibiting an insertion loss between 1.5 and 2.5 dB from 40 to 67 GHz. This results in a figure-of-merit for passive phase shifters of 33 dB to 45°/dB, accompanied with a phase shift of 55°-100°.
Author Nickel, Matthias
Jost, Matthias
Gomes, Leonardo G.
Rehder, Gustavo P.
Serrano, Ariana L. C.
Maune, Holger
Polat, Ersin
Jakoby, Rolf
Pinheiro, Julio M.
Gautam, Jay S. K.
Reese, Roland
Ferrari, Philippe
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  organization: Institute for Microwave Engineering and Photonics, Technische Universitaet Darmstadt, Darmstadt, Germany
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Keywords 5G
slow wave
liquid crystal (LC)
millimeter-wave
phase shifter
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Snippet This letter presents the realization of a miniaturized liquid crystal slow wave phase shifter at <inline-formula> <tex-math notation="LaTeX">V...
This letter presents the realization of a miniaturized liquid crystal slow wave phase shifter at V -band. It is based on a microstrip topology, where the...
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SubjectTerms Copper
Dielectrics
Electric power
Engineering Sciences
Glass
liquid crystal (LC)
Microstrip
millimeter-wave
Phase measurement
phase shifter
Phase shifters
slow wave
Transmission line measurements
Title Miniaturized Liquid Crystal Slow Wave Phase Shifter Based on Nanowire Filled Membranes
URI https://ieeexplore.ieee.org/document/8396292
https://hal.science/hal-01985323
Volume 28
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