posted on 2019-06-26, 00:00authored byAndreas
C. Jakowetz, Ture F. Hinrichsen, Laura Ascherl, Torben Sick, Mona Calik, Florian Auras, Dana D. Medina, Richard H. Friend, Akshay Rao, Thomas Bein
Covalent organic frameworks (COFs)
are a highly versatile group
of porous materials constructed from molecular building blocks, enabling
deliberate tuning of their final bulk properties for a broad range
of applications. Understanding their excited-state dynamics is essential
for identifying suitable COF materials for applications in electronic
devices such as transistors, photovoltaic cells, and water-splitting
electrodes. Here, we report on the ultrafast excited-state dynamics
of a series of fully conjugated two-dimensional (2D) COFs in which
different molecular subunits are connected through imine bonds, using
transient absorption spectroscopy. Although these COFs feature different
topologies and chromophores, we find that excited states behave similarly
across the series. We therefore present a unified model in which charges
are generated through rapid singlet–singlet annihilation and
show lifetimes of several tens of microseconds. These long-lived charges
are of particular interest for optoelectronic devices, and our results
point toward the importance of controlling the singlet–singlet
annihilation step in order to increase the yield of separated charges.