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Microsystem Technologies
Erschienen in: Microsystem Technologies 4-5/2014

01.04.2014 | Technical Paper

Component design and testing for a miniaturised autonomous sensor based on a nanowire materials platform

verfasst von: Giorgos Fagas, Michael Nolan, Yordan M. Georgiev, Ran Yu, Olan Lotty, Nikolay Petkov, Justin D. Holmes, Guobin Jia, Björn Eisenhawer, Annett Gawlik, Fritz Falk, Naser Khosropour, Elizabeth Buitrago, Montserrat Fernández-Bolaños Badia, Francois Krummenacher, Adrian M. Ionescu, Maher Kayal, Adrian M. Nightingale, John C. de Mello, Erik Puik, Franc van der Bent, Rik Lafeber, Rajesh Ramaneti, Hien Duy Tong, Cees van Rijn

Erschienen in: Microsystem Technologies | Ausgabe 4-5/2014

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Abstract

We present the design considerations of an autonomous wireless sensor and discuss the fabrication and testing of the various components including the energy harvester, the active sensing devices and the power management and sensor interface circuits. A common materials platform, namely, nanowires, enables us to fabricate state-of-the-art components at reduced volume and show chemical sensing within the available energy budget. We demonstrate a photovoltaic mini-module made of silicon nanowire solar cells, each of 0.5 mm2 area, which delivers a power of 260 μW and an open circuit voltage of 2 V at one sun illumination. Using nanowire platforms two sensing applications are presented. Combining functionalised suspended Si nanowires with a novel microfluidic fluid delivery system, fully integrated microfluidic–sensor devices are examined as sensors for streptavidin and pH, whereas, using a microchip modified with Pd nanowires provides a power efficient and fast early hydrogen gas detection method. Finally, an ultra-low power, efficient solar energy harvesting and sensing microsystem augmented with a 6 mAh rechargeable battery allows for less than 20 μW power consumption and 425 h sensor operation even without energy harvesting.
Vorheriger Artikel Estimation of squeeze film damping in artificial hair-sensor towards the detection-limit of crickets’ hairs
Nächster Artikel Development of a novel piezoresistive thin film sensor system based on hydrogenated carbon

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Metadaten
Titel
Component design and testing for a miniaturised autonomous sensor based on a nanowire materials platform
verfasst von
Giorgos Fagas
Michael Nolan
Yordan M. Georgiev
Ran Yu
Olan Lotty
Nikolay Petkov
Justin D. Holmes
Guobin Jia
Björn Eisenhawer
Annett Gawlik
Fritz Falk
Naser Khosropour
Elizabeth Buitrago
Montserrat Fernández-Bolaños Badia
Francois Krummenacher
Adrian M. Ionescu
Maher Kayal
Adrian M. Nightingale
John C. de Mello
Erik Puik
Franc van der Bent
Rik Lafeber
Rajesh Ramaneti
Hien Duy Tong
Cees van Rijn
Publikationsdatum
01.04.2014
Verlag
Springer Berlin Heidelberg
Erschienen in
Microsystem Technologies / Ausgabe 4-5/2014
Print ISSN: 0946-7076
Elektronische ISSN: 1432-1858
DOI
https://doi.org/10.1007/s00542-014-2100-4

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