Abstract
Pure organics with room temperature
phosphorescence (RTP) are urgently demanded in advanced optoelectronic and
bioelectronic applications. However, currently reported phosphors are mostly
aromatics and restricted to blue to orange colors. It remains an enormous
challenge to achieve red and near-infrared (NIR) RTP, particularly for those
from nonaromatics. Here we demonstrate a series of cyclic imides derived from
succinimide, which can emit red (665, 690 nm) and even NIR (745 nm) RTP with
outstanding efficiencies of up to 9.2%, despite their rather limited molecular
conjugations. Such unique emission should be ascribed to the presence of the
imide unit and heavy atoms, effective molecular clustering, and the electron
delocalization of halogens, which not only greatly facilitate intersystem
crossing, but also afford significantly extended through-space conjugation and
rigidified conformations. These results pave the way to the rational
construction of red and NIR nonconventional luminophores through synergistic
clustering and halogen effects.
Supplementary materials
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