posted on 2021-01-04, 13:07authored bySizhuo Yang, Daniel Streater, Christian Fiankor, Jian Zhang, Jier Huang
2D covalent organic frameworks (COFs)
have emerged as a promising
class of organic luminescent materials due to their structural diversity,
which allows the systematic tuning of organic building blocks to optimize
emitting properties. However, a significant knowledge gap exists between
the design strategy and the fundamental understanding of the key structural
parameters that determine their photophysical properties. In this
work, we report two highly emissive sp2-C-COFs and the
direct correlation of the structure (conjugation and aggregation)
with their light absorption/emission, charge transfer (CT), and exciton
dynamics, the key properties that determine their function as luminescent
materials. We show that white light can be obtained by simply coating
COFs on an LED strip or mixing the two COFs. Using the combination
of time-resolved absorption and emission spectroscopy as well as computational
prediction, we show that the planarity, conjugation, orientation of
the dipole moment, and interlayer aggregation not only determine the
light-harvesting ability of COFs but also control the exciton relaxation
pathway and photoluminescent quantum yield.