Gas sensing of colloidal polyaniline in a chemoresistor consisting of nanometer electrodes

The high conductivity of colloid-conducting polymers is explained by the networking structures and the hopping mechanisms of the metallic particles [1,2,4]. To observe how the metallic region and the networking structures differ in sensing NH 3 gas, E-beam lithography and electromigration were used...

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Bibliographic Details
Published in:Microelectronic engineering 2011-09, Vol.88 (9), p.3035-3042
Main Authors: Park, S.Y., Bae, M.S., Jeon, I.D., Lee, J.J.
Format: Article
Language:English
Subjects:
Applied sciences
Chemoresistor
Colloid Pani
Colloids
Condensed matter: electronic structure, electrical, magnetic, and optical properties
Condensed matter: structure, mechanical and thermal properties
Diffusion in solids
Electric potential
Electro migration
Electrodes
Electromigration
Electronic structure and electrical properties of surfaces, interfaces, thin films and low-dimensional structures
Electronics
Exact sciences and technology
Gaps
Gas sensor
General equipment and techniques
Hopping mechanism
Instruments, apparatus, components and techniques common to several branches of physics and astronomy
Lithography
Metal particles
Microelectronic fabrication (materials and surfaces technology)
Nanometer electrode
Networking structure
Nonlinearity
Physics
Semiconductor electronics. Microelectronics. Optoelectronics. Solid state devices
Sensors
Sensors (chemical, optical, electrical, movement, gas, etc.)
remote sensing
Surface double layers, schottky barriers, and work functions
Transport properties of condensed matter (nonelectronic)
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Summary:The high conductivity of colloid-conducting polymers is explained by the networking structures and the hopping mechanisms of the metallic particles [1,2,4]. To observe how the metallic region and the networking structures differ in sensing NH 3 gas, E-beam lithography and electromigration were used to make chemoresistors with nanometer-gap electrodes. Colloid Pani was coated on a nanometer gap as a reaction matrix for the gas. The I– V curves were measured in a vacuum and the NH 3 gas was nonlinear. In sensors with a gap of less than 10 nm, there was a two- or threefold increase in the conductivity, and the work function decreased from 600 meV in a vacuum to 250 meV in NH 3 gas. In contrast, the conductivity of sensors with gaps of 200 and 500 nm decreased to 1/1000 in the NH 3 gas environment. The decrease of the conductivity can be explained by electron–hole annihilation, which appears to occur on the surface of the secondary particles. With comb-type electrodes, the operating voltage can be decreased by three orders of magnitude. In electrodes with 200 and 500 nm gaps, the I– V has a step-type response to NH 3 gas.
ISSN:0167-9317
1873-5568
DOI:10.1016/j.mee.2011.05.003