Table 3.
Properties of common PEDOT:PSS based conductive polymer composites.
| Conductive Polymer Composite | Resistivity, Ω cm (Resistance, Ω/sq) | Properties | Manufacturing Technique | Proposed Application | Ref. |
|---|---|---|---|---|---|
| GO/rGO filled PVA/PEDOT: PSS |
107 | Highly flexible free-standing | Solvent casting | Strain sensor | [67] |
| PEDOT:PSS/PU | (35−240) | Highly flexible, stretchable | Electrospinning | Strain sensor | [2] |
| PEDOT:PSS/Bacteria | 103a | 20 times more steady-state current than native biofilms baseline with signal level of 6.31 μA/cm3 | Embedding bacteria into electro-polymerized PEDOT:PSS on carbon felt anodes | Bioelectronics | [66] |
| PEDOT:PSS/PU | 1.26 × 10−2 | Sensitivity to different stimuli including strain, ambient temperature and/or air flow high electrical conductivity | Dispersion mixing | Stretchable self-powered sensors | [38] |
| PEDOT:PSS/graphene | (25) | Strong resistance against fatigue upon repeated folding-unfolding | Spray coating | Data storage and transmission, biosensors and actuators | [68] |
| 3D Graphene/PEDOT:PSS | 4.1 × 10−2 | Good resistance retention capability under deformations | Graphene networks coated by PEDOT:PSS | Next-generation stretchable electronics | [69] |
| CNT/PEDOT:PSS | 3 × 10−3 | Good thermoelectric performance | Vacuum assisted filtration method and H2SO4 treatment | Flexible thermoelectric generator | [70] |
a The unit for the value of Ref. [66] is Ω.