Molecular insertion regulates the donor-acceptor interactions in cocrystals for the design of piezochromic luminescent materials

Abstract: Developing a universal strategy to design piezochromic luminescent materials with desirable properties remains challenging. Here, we report that insertion of a non-emissive molecule into a donor (perylene) and acceptor (1,2,4,5-tetracyanobezene) binary cocrystal can realize fine manipulation of intermolecular interactions between perylene and 1,2,4,5-tetracyanobezene (TCNB) for desirable piezochromic luminescent properties. A continuous pressure-induced emission enhancement up to 3 GPa and a blue shift from 65… Show more

“…On exposure to DCM, the PL spectrum of Y‐phase crystalline powder redshifted to 591 nm with the orange fluorescence (Figure S11), which was very close to that of O‐phase crystals. Thus, it was speculated that the presence of solvent molecules may explain the redshift of PL spectra [5b, 11] …”

Piezochromic Tetracoordinate Boron Complex: Blue‐Shifted and Enhanced Luminescence

“…On exposure to DCM, the PL spectrum of Y‐phase crystalline powder redshifted to 591 nm with the orange fluorescence (Figure S11), which was very close to that of O‐phase crystals. Thus, it was speculated that the presence of solvent molecules may explain the redshift of PL spectra [5b, 11] …”

Piezochromic Tetracoordinate Boron Complex: Blue‐Shifted and Enhanced Luminescence

“…With the development of supramolecular chemistry and crystal engineering, multi-component molecular materials such as cocrystals have been extensively studied. 12–17 Organic cocrystals are usually assembled by two or more different molecules in a clear stoichiometric ratio through non-covalent interactions, such as hydrogen bonds, halogen bonds, and π–π stacking interactions. 12,18,19 Cocrystal engineering can avoid complex synthetic procedures, and it is easy to manipulate non-covalent interactions between molecules to achieve adjustable functional properties, providing a good platform for revealing the structure–property relationship at the molecular level.…”

Enhanced luminescence of single-benzene fluorescent molecules through halogen bond cocrystals

“…2 The scope of organic charge transfer cocrystals was initially limited to electronic applications; however, they have been recognized for multiple optical applications recently. Charge transfer cocrystals have been utilized for aggregation induced emission enhancement (AIEE), 3 white light emission, 4 two photon emission, 5 piezochromic emission enhancement, 6 room temperature phosphorescence, 7 thermally activated delayed fluorescence (TADF), 8 active optical waveguides, 9 optical data storage, 10 bio-imaging, 11 and stimuli responsive fluorophores. 12 Combining the intrinsic semiconductor nature with charge transfer emission in CT cocrystals makes them ideal candidates for organic light emitting transistors (OLETs) 13 and photoconductors.…”

Unravelling supramolecular features and opto-electronic properties of a binary charge transfer cocrystal of a blue fluorescent di-carbazole and TFT