Towards a Carbon Nanotube Intermodulation Product Sensor for Nonlinear Energy Harvesting

Towards a Carbon Nanotube Intermodulation Product Sensor for Nonlinear Energy Harvesting

It is critically important in designing RF receiver front ends to handle high power jammers and other strong interferers. Instead of blocking incoming energy or dissipating it as heat, we investigate the possibility of redirecting that energy for harvesting and storage. The approach is based on chan...

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Main Authors: Mitchell B. Lerner, Brett Goldsmith, John Rockway, Israel Perez
Format: Article
Language:English
Published: Hindawi Limited 2015-01-01
Series:Journal of Sensors
Online Access:http://dx.doi.org/10.1155/2015/983697
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spelling doaj-0facb9c0c7934a4f996cfb525e3f14032020-11-25T00:59:46ZengHindawi LimitedJournal of Sensors1687-725X1687-72682015-01-01201510.1155/2015/983697983697Towards a Carbon Nanotube Intermodulation Product Sensor for Nonlinear Energy HarvestingMitchell B. Lerner0Brett Goldsmith1John Rockway2Israel Perez3Functional Nano Devices Lab, System of Systems and Platform Design Division, SPAWAR Systems Center Pacific, 53560 Hull Street, San Diego, CA 92152, USAFunctional Nano Devices Lab, System of Systems and Platform Design Division, SPAWAR Systems Center Pacific, 53560 Hull Street, San Diego, CA 92152, USAFunctional Nano Devices Lab, System of Systems and Platform Design Division, SPAWAR Systems Center Pacific, 53560 Hull Street, San Diego, CA 92152, USAFunctional Nano Devices Lab, System of Systems and Platform Design Division, SPAWAR Systems Center Pacific, 53560 Hull Street, San Diego, CA 92152, USAIt is critically important in designing RF receiver front ends to handle high power jammers and other strong interferers. Instead of blocking incoming energy or dissipating it as heat, we investigate the possibility of redirecting that energy for harvesting and storage. The approach is based on channelizing a high power signal into a previously unknown circuit element which serves as a passive intermodulation device. This intermodulation component must produce a hysteretic current-voltage curve to be useful as an energy harvester. Here we demonstrate a method by which carbon nanotube transistors produce the necessary hysteretic I-V curves. Such devices can be tailored to the desired frequency by introducing functional groups to the nanotubes. These effects controllably enhance the desired behavior, namely, hysteretic nonlinearity in the transistors’ I-V characteristic. Combining these components with an RF energy harvester may one day enable the reuse of inbound jamming energy for standard back end radio components.http://dx.doi.org/10.1155/2015/983697
collection DOAJ
language English
format Article
sources DOAJ
author Mitchell B. Lerner
Brett Goldsmith
John Rockway
Israel Perez
spellingShingle Mitchell B. Lerner
Brett Goldsmith
John Rockway
Israel Perez
Towards a Carbon Nanotube Intermodulation Product Sensor for Nonlinear Energy Harvesting
Journal of Sensors
author_facet Mitchell B. Lerner
Brett Goldsmith
John Rockway
Israel Perez
author_sort Mitchell B. Lerner
title Towards a Carbon Nanotube Intermodulation Product Sensor for Nonlinear Energy Harvesting
title_short Towards a Carbon Nanotube Intermodulation Product Sensor for Nonlinear Energy Harvesting
title_full Towards a Carbon Nanotube Intermodulation Product Sensor for Nonlinear Energy Harvesting
title_fullStr Towards a Carbon Nanotube Intermodulation Product Sensor for Nonlinear Energy Harvesting
title_full_unstemmed Towards a Carbon Nanotube Intermodulation Product Sensor for Nonlinear Energy Harvesting
title_sort towards a carbon nanotube intermodulation product sensor for nonlinear energy harvesting
publisher Hindawi Limited
series Journal of Sensors
issn 1687-725X
1687-7268
publishDate 2015-01-01
description It is critically important in designing RF receiver front ends to handle high power jammers and other strong interferers. Instead of blocking incoming energy or dissipating it as heat, we investigate the possibility of redirecting that energy for harvesting and storage. The approach is based on channelizing a high power signal into a previously unknown circuit element which serves as a passive intermodulation device. This intermodulation component must produce a hysteretic current-voltage curve to be useful as an energy harvester. Here we demonstrate a method by which carbon nanotube transistors produce the necessary hysteretic I-V curves. Such devices can be tailored to the desired frequency by introducing functional groups to the nanotubes. These effects controllably enhance the desired behavior, namely, hysteretic nonlinearity in the transistors’ I-V characteristic. Combining these components with an RF energy harvester may one day enable the reuse of inbound jamming energy for standard back end radio components.
url http://dx.doi.org/10.1155/2015/983697
work_keys_str_mv AT mitchellblerner towardsacarbonnanotubeintermodulationproductsensorfornonlinearenergyharvesting
AT brettgoldsmith towardsacarbonnanotubeintermodulationproductsensorfornonlinearenergyharvesting
AT johnrockway towardsacarbonnanotubeintermodulationproductsensorfornonlinearenergyharvesting
AT israelperez towardsacarbonnanotubeintermodulationproductsensorfornonlinearenergyharvesting
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