| Summary: | Carbon nanomaterials are a promising class of materials for optoelectronics with low environmental impact. However, dark states limit their photoluminescence (PL) efficiency and thus applicability. In this thesis, hitherto-unrecognised twilight states in graphene nanoribbons are identified, where inter-valley mixing produced by periodic edge modulation and strong electron-phonon coupling are key mechanisms that make conventionally-dark states at least four times brighter, resulting in a 7.7% PL quantum yield. Strong vibron-electron coupling is revealed by the high spectral definition, with the bandgap modulated by coupling to the radial breathing-like mode. Unexpectedly, the predominant phonon modes affect absorption and emission differently, due to the simultaneous presence of Herzberg-Teller and Franck-Condon couplings. The achievement of efficient light emission from carbon nanostructures, both in solutions and thin films, opens the path to their integration into electro-optical circuits, and to the optical investigation and manipulation of topological states in graphenoids. Further, a detailed study of carbon nanotube-ethylene-vinyl acetate (CNT-EVA) transparent conductive films (TCFs) and the connection between processing and optoelectronic film properties is presented, leading to a 100-fold improvement of the electrical conductivity at the same transmittance. The dispersion technique and polymer removal steps are established as crucial steps for improving TCF performance. Changing the composition of the EVA copolymer allows tuning the mechanical and chemical resilience of CNT-EVA films and the films perform well in flexible applications. CNT-EVA films are chemically p-doped with halogenated metals and low-cost dopants identified. The improved CNT-EVA films perform well in transparent touch-sensitive devices and as transport layer in pervoskite photovoltaic (PV) devices, highlighting the potential of hybrid transport layers and opening a pathway for the large-scale application of low-cost CNT-EVA conductive films. Finding ways to stabilise perovskites under ambient conditions is the main challenge to overcome before they can be applied on a large scale. Substantial stability improvement is demonstrated for the pervoskite formamidinium lead iodide (FAPbI3) in single crystals by the addition of methylenediammonium dichloride (MDACl2). This is quantified by Raman spectroscopy which is established as a powerful tool for the characterisation of FAPbI3 by devising the defocused Raman spectroscopy method. The MDACl2 additive reduced the trap density and increased the excited carrier lifetime significantly, whereas the band gap at room temperature appears unaffected by the addition of MDACl2.
|
|---|