Abstract
Processing from solution is a crucial aspect of organic semiconductors, as it is at the heart of the promise of easy and inexpensive manufacturing of devices. Introducing alkyl side chains is an approach often used to increase solubility and enhance miscibility in blends. The influence of these side chains on the electronic structure, although highly important for a detailed understanding of the structure-function relationship of these materials, is still barely understood. Here, we use time-resolved electron paramagnetic resonance spectroscopy with its molecular resolution to investigate the role of alkyl side chains on the polymer PCDTBT and a series of its building blocks with increasing length. Comparing our results to the non-hexylated compounds allows us to distinguish four different factors determining exciton delocalization. Detailed quantum-chemical calculations (DFT) allows us to further interpret our spectroscopic data and to relate our findings to the molecular geometry. Alkylation generally leads to more localized excitons, most prominent only for the polymer. Furthermore, singlet excitons are more delocalized than the corresponding triplet excitons, despite the larger dihedral angles within the backbone found for the singlet-state geometries. Our results show TREPR spectroscopy of triplet excitons to be well suited for investigating crucial aspects of the structure-function relationship of conjugated polymers used as organic semiconductors on a molecular basis.
Highlights
Semiconductors have revolutionized our way of life and are currently ubiquitous materials for various devices and applications
We investigated the impact of side chains on the film morphology using a series of PCDTBT polymers with increasing degree of alkyl side chains, allowing us to distinguish between effects on electronic structure and morphology [55]
We have investigated the effect of adding alkyl side chains to the electronic structure of the underlying polymer in great detail
Summary
Semiconductors have revolutionized our way of life and are currently ubiquitous materials for various devices and applications Most of these devices still consist of inorganic compounds, mostly silicon. The big advantages of organic semiconductors over their more conventional inorganic counterparts are their mechanical flexibility [4,5,6,7], simple and inexpensive processing from solution [8], and variability due to well-developed protocols of synthetic chemistry This renders wearable electronics [9,10], as well as large-area electronic devices [11] and flexible displays [12] viable, to name just a few potential applications
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