Inkjet printed chemical sensor array based on polythiophene conductive polymers

Sauvé, Geneviève; Cooper, Jessica A; Zhang, Rui; Revelli, Joseph C.; Kusne, Aaron G; Li, Bo; Kowalewski, Tomasz Aleksander; Weiss, Lee E.; McCullough, Richard D; Fedder, Gary K; Lambeth, David N; Snyder, Jay L.; Santhanam, Suresh; Schultz, Lawrence; Jeffries-EL, Malika; Iovu, Mihaela C.

doi:10.1016/j.snb.2006.09.064

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Inkjet printed chemical sensor array based on polythiophene conductive polymers

Author(s): Bo Li , Suresh Santhanam , Lawrence Schultz , Malika Jeffries-EL , Mihaela C. Iovu , Genevieve Sauvé , Jessica Cooper , Rui Zhang , Joseph C. Revelli , Aaron G. Kusne , Jay L. Snyder , Tomasz Kowalewski , Lee E. Weiss , Richard D. McCullough , Gary K. Fedder , David N. Lambeth

Publication date Created: May 2007

Publication date (Print): May 2007

Journal: Sensors and Actuators B: Chemical

Publisher: Elsevier BV

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High-Resolution Inkjet Printing of All-Polymer Transistor Circuits

H Sirringhaus, T Kawase, R. Friend … (2000)

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Chemical detection with a single-walled carbon nanotube capacitor.

E. S. Snow, F Perkins, E. Houser … (2005)

We show that the capacitance of single-walled carbon nanotubes (SWNTs) is highly sensitive to a broad class of chemical vapors and that this transduction mechanism can form the basis for a fast, low-power sorption-based chemical sensor. In the presence of a dilute chemical vapor, molecular adsorbates are polarized by the fringing electric fields radiating from the surface of a SWNT electrode, which causes an increase in its capacitance. We use this effect to construct a high-performance chemical sensor by thinly coating the SWNTs with chemoselective materials that provide a large, class-specific gain to the capacitance response. Such SWNT chemicapacitors are fast, highly sensitive, and completely reversible.