Exploiting the combination of 3D polymer printing and inkjet Ag-nanoparticle printing for advanced packaging

M. Krivec; A. Roshanghias; A. Abram; A. Binder

doi:10.1016/j.mee.2016.12.021

Exploiting the combination of 3D polymer printing and inkjet Ag-nanoparticle printing for advanced packaging

M. Krivec, A. Roshanghias, A. Abram, A. Binder

Publikation: Beitrag in Fachzeitschrift › Artikel › Begutachtung

Abstract

A rapid advanced packaging concept, consisting of 3D photopolymer printing and Ag nanoparticle printing, was investigated for the construction of a simple radio frequency identification (RFID) package with integrated surface acoustic wave transponder (SAW). An acrylate-type SAW package housing was printed with a multi-jet 3D printer and the corresponding antenna for the wireless read-out was manufactured via inkjet printing of Ag nanoparticle ink. The corresponding Ag structure had a thickness of about 2 μm with a sheet resistance of 250 mΩ sq− 1 after the photonic sintering processing. The chip-on-board and flip-chip packaging concepts were pursued for connecting the antenna structure to the chip pads. The SAW package prototype in a flip-chip configuration showed a significant signal to noise ratio (SNR) of about 30 dB via antenna-bridged radio frequency link at a moderate distance of 3 cm.

Originalsprache	Englisch
Seiten (von - bis)	1-5
Seitenumfang	5
Fachzeitschrift	Microelectronic Engineering
Jahrgang	176
DOIs	https://doi.org/10.1016/j.mee.2016.12.021
Publikationsstatus	Veröffentlicht - 25 Mai 2017

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10.1016/j.mee.2016.12.021

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title = "Exploiting the combination of 3D polymer printing and inkjet Ag-nanoparticle printing for advanced packaging",

abstract = "A rapid advanced packaging concept, consisting of 3D photopolymer printing and Ag nanoparticle printing, was investigated for the construction of a simple radio frequency identification (RFID) package with integrated surface acoustic wave transponder (SAW). An acrylate-type SAW package housing was printed with a multi-jet 3D printer and the corresponding antenna for the wireless read-out was manufactured via inkjet printing of Ag nanoparticle ink. The corresponding Ag structure had a thickness of about 2 μm with a sheet resistance of 250 mΩ sq− 1 after the photonic sintering processing. The chip-on-board and flip-chip packaging concepts were pursued for connecting the antenna structure to the chip pads. The SAW package prototype in a flip-chip configuration showed a significant signal to noise ratio (SNR) of about 30 dB via antenna-bridged radio frequency link at a moderate distance of 3 cm.",

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AU - Krivec, M.

AU - Roshanghias, A.

AU - Abram, A.

AU - Binder, A.

PY - 2017/5/25

Y1 - 2017/5/25

N2 - A rapid advanced packaging concept, consisting of 3D photopolymer printing and Ag nanoparticle printing, was investigated for the construction of a simple radio frequency identification (RFID) package with integrated surface acoustic wave transponder (SAW). An acrylate-type SAW package housing was printed with a multi-jet 3D printer and the corresponding antenna for the wireless read-out was manufactured via inkjet printing of Ag nanoparticle ink. The corresponding Ag structure had a thickness of about 2 μm with a sheet resistance of 250 mΩ sq− 1 after the photonic sintering processing. The chip-on-board and flip-chip packaging concepts were pursued for connecting the antenna structure to the chip pads. The SAW package prototype in a flip-chip configuration showed a significant signal to noise ratio (SNR) of about 30 dB via antenna-bridged radio frequency link at a moderate distance of 3 cm.

AB - A rapid advanced packaging concept, consisting of 3D photopolymer printing and Ag nanoparticle printing, was investigated for the construction of a simple radio frequency identification (RFID) package with integrated surface acoustic wave transponder (SAW). An acrylate-type SAW package housing was printed with a multi-jet 3D printer and the corresponding antenna for the wireless read-out was manufactured via inkjet printing of Ag nanoparticle ink. The corresponding Ag structure had a thickness of about 2 μm with a sheet resistance of 250 mΩ sq− 1 after the photonic sintering processing. The chip-on-board and flip-chip packaging concepts were pursued for connecting the antenna structure to the chip pads. The SAW package prototype in a flip-chip configuration showed a significant signal to noise ratio (SNR) of about 30 dB via antenna-bridged radio frequency link at a moderate distance of 3 cm.

KW - Additive manufacturing

KW - Inkjet printing

KW - Rapid advanced packaging

KW - SAW package

UR - https://www.mendeley.com/catalogue/231c1dd7-c752-3ec0-b253-da26ba5aba8e/

U2 - 10.1016/j.mee.2016.12.021

DO - 10.1016/j.mee.2016.12.021

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EP - 5

JO - Microelectronic Engineering

JF - Microelectronic Engineering

ER -

Exploiting the combination of 3D polymer printing and inkjet Ag-nanoparticle printing for advanced packaging

Abstract

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