Details

Autor(en) / Beteiligte

• Stepien, Lukas
• Roch, Aljoscha
• Tkachov, Roman
• Leupolt, Beate
• Han, Li
• van Ngo, Nong
• Leyens, Christoph

Titel

Thermal operating window for PEDOT:PSS films and its related thermoelectric properties

Ist Teil von

• Synthetic metals, 2017-03, Vol.225, p.49-54

Ort / Verlag

Lausanne: Elsevier B.V

Erscheinungsjahr

2017

Quelle

Alma/SFX Local Collection

Beschreibungen/Notizen

• [Display omitted] •The operating window of PEDOT:PSS was investigated for 50h.•PEDOT:PSS degradation can be divided to morphological and chemical processes.•Morphological degradation of PEDOT:PSS follows an granular metal structure model.•Results were additional chemical degradation occurs can be fitted by an extended model.•UV–vis-IR measurements indicate a chemical degradation at 120°C by loss of absorption on the bipolaron and polaron region. The intrinsically conducting polymer PEDOT:PSS is widely used and has found high recognition due to its excellent electrical conductivity. Its potential applications cover many fields, e.g. thermoelectric energy conversion. Therefore we compared the thermoelectric properties ofpristine and DMSO treated PEDOT:PSS films at potential operating temperatures. Here we observed the electrical degradation of the film up to complete failure. Further, the thermal aging of PEDOT:PSS still lacks of understanding. It is pointed out that PEDOT:PSS films show a complex degradation mechanism which includes a morphological and a chemical part. In the range of room temperature and ∼160°C PEDOT:PSS films follow the known exponential degradation which imposes morphological degradation, while at higher temperatures this law is not suitable to match the experimental data. Thus we extended the known exponential equation by an additional exponential degradation term which shows good agreement with the experimental data. The optical absorption spectrum indicates a loss in bipolaron and polaron charge carriers, which reflects the degradation behavior. It can be seen that changes in the optical absorption spectrum after isothermal annealing for more than 50h occur at temperatures around 120°C, which marks the transition from morphological to chemical degradation.