Covalent organic frameworks for optical applications

Linking molecules into extended crystalline networks to construct covalent organic frameworks (COFs) added in variety to the readily thriving research on molecule-based solid-state materials, featured by classic polymers and molecular crystals. Compared to the development of COFs for gas separation, energy storage, and conversion, where the porosity feature of COFs is utilized, the optical applications, such as fluorescence, white light emission, and photodynamic therapy, involving the molecular and crystalline feature of COFs, are much less explored. In this review, we focused on the optical properties of COFs, and how do these macroscopic properties correlate with the microscopic structure of COFs. Other than the influence from organic functional groups in previous reviews on COFs, here, three critical structure factors, the connection, orientation, and alignment of the molecular building blocks, are outlined and associated with the optical properties of COFs. We also analyze the properties of COFs from both energy and dynamic aspects in an attempt to provide further insight into the possible underlying mechanism. At the end of this review, we also discuss the remaining challenges and future directions for the design of COFs for optical applications, and unveil the potential of COFs toward this direction.

Automated summary

This review focuses on the optical properties of covalent organic frameworks (COFs) and how they correlate with the microscopic structure of COFs. It explores the relationship between key structural factors like connection, orientation, and alignment of molecular building blocks, and the optical properties of COFs. Additionally, the properties of COFs are analyzed from both energy and dynamic aspects to provide insights into the possible underlying mechanisms.