Peer-Reviewed Journal Details
Mandatory Fields
Fagas, G.,Nolan, M.,Georgiev, Y. M.,Yu, R.,Lotty, O.,Petkov, N.,Holmes, J. D.,Jia, G. B.,Eisenhawer, B.,Gawlik, A.,Falk, F.,Khosropour, N.,Buitrago, E.,Badia, M. F. B.,Krummenacher, F.,Ionescu, A. M.,Kayal, M.,Nightingale, A. M.,de Mello, J. C.,Puik, E.,van der Bent, F.,Lafeber, R.,Ramaneti, R.,Tong, H. D.,van Rijn, C.
2014
April
Microsystem Technologies-Micro-and Nanosystems-Information Storage and Processing Systems
Component design and testing for a miniaturised autonomous sensor based on a nanowire materials platform
Validated
()
Optional Fields
20
4-54-5
971
988
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 mm(2) area, which delivers a power of 260 mu W 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 mu W power consumption and 425 h sensor operation even without energy harvesting.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 mm(2) area, which delivers a power of 260 mu W 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 mu W power consumption and 425 h sensor operation even without energy harvesting.
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Grant Details