Abstract
Different conducting polymers form a special class of
materials with the potential for many applications in
organic electronics and functional materials. These
polymers can be electronically conducting or
semiconducting due to a conjugated polymer backbone, or
alternatively possess conductivity due to mobile protons
or other ions. This thesis discusses such conducting
polymers and shows ways how they can be processed by
printing and how the nanostructure allows controlling
their electrical properties.
The printability of conducting polymers, studied in paper
I, has opened up new fields for their use in electronics.
We showed that conducting polymers like polyaniline can
be printed with industrial printers and high speed (up to
100 m/min) on paper achieving 60 µm resolution.
One of the most promising fields for conducting polymers
is sensor applications. Papers II and III show how
polyaniline can be utilised to detect changes in
temperature and moisture by selecting suitable
counter-ions. Melting of the counter-ion side chains was
found to induce a reversible change in conductivity. On
the other hand, humidity triggered an irreversible change
in conductivity due to crystallisation and
phase-separation of the counterion.
Paper IV studies the effect of polymer microstructure in
resistive memory devices. Even though the structure of
polymers often has a significant effect on the electrical
properties, in this case the polymer-electrode interface
was found to be dominating.
Finally, paper V shows that highly self-assembled
polymer complexes may be achieved by utilising ionic
liquids. The polymer-ionic liquid complex forms a
surprisingly well organised nanophase-separated structure
that provides pathways for proton conduction.
This thesis takes a step from the laboratory towards
applications of conducting polymers and gives insight
into utilisation and processing of functional materials
to be used in organic electronics components and devices.
Original language | English |
---|---|
Qualification | Doctor Degree |
Awarding Institution |
|
Supervisors/Advisors |
|
Place of Publication | Espoo |
Publisher | |
Print ISBNs | 978-951-38-7408-7 |
Electronic ISBNs | 978-951-38-7409-4 |
Publication status | Published - 2010 |
MoE publication type | G5 Doctoral dissertation (article) |
Keywords
- conducting polymers
- Polyaniline
- printed electronics
- functional counter-ion