Individual strings of conducting carbon cones and discs in a polymer matrix: Electric field‐induced alignment and their use as a strain sensor |
| |
| Authors: | Henrik Høyer Matti Knaapila Jakob Kjelstrup‐Hansen Xuhai Liu Geir Helgesen |
| |
| Affiliation: | 1. Physics Department, Institute for Energy Technology, NO‐2027 Kjeller, Norway;2. NanoSYD, Mads Clausen Institute, University of Southern Denmark, DK‐6400 S?nderborg, Denmark;3. Department of Physics, University of Oslo, NO‐0316 Oslo, Norway |
| |
| Abstract: | We demonstrate micromechanical strain sensors with integrated readout based on carbon nanocones and discs (CNCs) which are aligned into a string‐like formation using an alternating electric field and studied by AC impedance spectroscopy and electromechanical methods. The CNC particles are first dispersed into a polymer matrix with a particle fraction of 0.1 vol %. This value is well below the percolation threshold (~ 2 vol %), which suppresses particle aggregation and facilitates transparency allowing the use of an UV‐curable polymer. Alignment was carried out with a 1 kHz, 4 kV/cm electric field and is a consequence of dielectrophoretic effect. It develops in minutes and makes the initially insulating, nonaligned material conductive. This is followed by UV curing of the polymer matrix, which renders a solid state device. The stretching of the aligned strings in the cured polymer leads to a reversible piezoresistive effect, and a gauge factor of about 50 is observed. This is in a sharp contrast to CNC films with particle fraction above percolation threshold (13 vol %), which are conductive but not sensitive to stretching. The strings are Ohmic in nature and moreover show higher DC conductivity (22–500 S/m) compared to identically prepared carbon black strings (1–22 S/m). © 2011 Wiley Periodicals, Inc. J Polym Sci Part B: Polym Phys, 2011 |
| |
| Keywords: | composite materials conducting polymers microelectromechanical systems sensors/biosensors stimuli‐responsive materials |
|
|
