Dielectrophoretic Assembly of Gold Nanoparticles in Nanoscale Junctions for Rapid, Miniature Chemiresistor Vapor Sensors

Dielectrophoretic Assembly of Gold Nanoparticles in Nanoscale Junctions for Rapid, Miniature Chemiresistor Vapor Sensors

A method for fabricating integrated arrays of nanoscale chemiresistor vapor sensors using functionalized gold nanoparticles is presented. Controlled placement of nanoparticles was accomplished with dielectrophoresis, achieving localized nanoparticle assembly between 50-nm-thick, 100-nm-wide nanofabr...

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Bibliographic Details
Published in:ACS sensors Vol. 1; no. 4; pp. 444 - 450
Main Authors: Fu, Kan, Chen, Shutang, Zhao, Jing, Willis, Brian G
Format: Journal Article
Language:English
Published: American Chemical Society 22-04-2016
Subjects:
dielectrophoresis
nanodevices
chemiresistors
sensors
gold nanoparticles
nanofabrication
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Summary:A method for fabricating integrated arrays of nanoscale chemiresistor vapor sensors using functionalized gold nanoparticles is presented. Controlled placement of nanoparticles was accomplished with dielectrophoresis, achieving localized nanoparticle assembly between 50-nm-thick, 100-nm-wide nanofabricated electrodes with 50 nm spacing. Each individual sensor comprises an assembly of thiol-functionalized 10-nm-diameter gold nanoparticles, making a total active sensing volume with thickness of 30 to 40 nm and area dimension 50 nm × 50 nm. The small electrode spacing enables contiguous films of just 3 to 4 layers of nanoparticles. Combination of top-down lithographic fabrication and bottom-up directed assembly allows multiple sensors spaced by 200 μm to be fabricated on a single chip. A second set of chemiresistor sensors with larger 20 μm electrode spacing and 200–300 nm film thickness were fabricated for comparison. Nanoscale sensors fabricated using 4 different types of thiolated capping ligands exhibited response sensitivity and selectivity similar to the larger chemiresistor sensors, but with a signal-to-noise degradation to 25% of the micron scale devices. The results demonstrate that nanofabricated sensors with dense arrays of many different types of functionalized nanoparticles can be integrated on a single chip, and it should be possible to create integrated, independent nanoscale sensors separated by only hundreds of nanometers.
ISSN:2379-3694
2379-3694
DOI:10.1021/acssensors.6b00041