Cocrystal engineering with a noncovalent assembly feature by simple constituent units has
inspired great interest and has emerged as an efficient and versatile route to construct …

Chemical versatility and compatibility with a vast array of processing techniques has led to
the incorporation of organic semiconductors in various electronic and opto-electronic …

Organic cocrystal engineering refers to two or more organic molecules stoichiometrically
combined and held together by noncovalent intermolecular interactions, which differs from …

Harvesting the narrow bandgap excitons of charge‐transfer (CT) complexes for the
achievement of near‐infrared (NIR) emission has attracted intensive attention for its …

Cocrystal engineering, involving the assembly of two or more components into a highly
ordered solid-state superstructure, has emerged as a popular strategy for tuning the …

Decreasing the energy loss is one of the most feasible ways to improve the efficiencies of
organic photovoltaic (OPV) cells. Recent studies have suggested that non‐radiative energy …

Organic semiconducting single crystals are perfect for both fundamental and application‐
oriented research due to the advantages of free grain boundaries, few defects, and minimal …

Two-photon excited near-infrared fluorescence materials have garnered considerable
attention because of their superior optical penetration, higher spatial resolution, and lower …

Crystal engineering can be regarded as the highly ordered and complicated supramolecular
synthesis of functional crystalline solids by control of intermolecular interactions. As one of …

The recent progress of charge‐transfer complexes (CTCs) for application in many fields,
such as charge transport, light emission, nonlinear optics, photoelectric conversion, and …