Abstract
AbstractThe search of compounds emitting in the near‐infrared (NIR) has been accelerated owing to their use in biomedical and telecommunications applications. In this regard, nanographenes (NGs) are attractive materials adequate for integration with other technologies, which have recently demonstrated amplified spontaneous emission (ASE) and lasing across the visible spectrum. Here, the optical and ASE properties of four‐zigzag edged NGs of the [m,n]peri‐acenoacene family are reported, whose size is increased through conjugation extension by varying n (from 3 to 5) while keeping m = 2. Results show that such 1D conjugation extension method is more efficient in terms of shifting the photoluminescence (PL) to the infrared (PL at 710 nm in the larger compound, PP‐Ar) than through 2D conjugation extension as in previously reported NGs (PL at 676 nm with the largest compound FZ3, with n = 3 and m = 4). Additionally, PP‐Ar shows dual‐ASE (at 726 and 787 nm), whose origin is elucidated through Raman and transient absorption spectroscopies. These compounds’ potential for red and NIR lasing is demonstrated through the fabrication of distributed feedback lasers with top‐layer resonators. This study paves the way towards the development of stable low‐cost all‐plastic NIR lasers.
Highlights
Conjugated organic materials have been extensively investigated, proving to be suitable for a variety of optoelectronic applications, for example, solar cells, field-effect transistors, and light-emitting diodes, among others
The analyzed samples consist of PS thin films with either the PBEh3c optimized structures of both PP-Ar (TT-Ar) or PP-Ar dispersed at 1 wt%
High PL quantum yield values are found for TT-Ar and PP-Ar, reaching up to 72%, which are similar values to those reported for the previous FZ series of NGs
Summary
Conjugated organic materials have been extensively investigated, proving to be suitable for a variety of optoelectronic applications, for example, solar cells, field-effect transistors, and light-emitting diodes, among others. Waveguide losses are minimized and the ASE performance-optimized.[27,28] Results for the previously reported FZ1 (hereinafter called AA-Ar, for coherence in nomenclature) will be included in figures and discussions to help in the comparisons.[22]
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