Versatile Induction of Efficient Organic‐Based Room‐Temperature Phosphorescence via Al‐DMSO Matrices Encapsulation

It is still difficult to design efficient organic‐based room‐temperature phosphorescence (RTP). Here a facile strategy is reported to tailor efficient RTP by encapsulating trace amount of aromatic‐acid‐based phosphors within crystalline solvento matrices [Al(DMSO)6]X3 (X− = Cl− or Br−, DMSO = dimethyl sulfoxide, (CH3)2SO) in situ. The resultant single crystal complexes feature bright long‐lasting afterglows with maximum RTP peaks ranging from 430 to 580 nm and the best lifetime up to 1.9 s, as well as the highest yellow RTP quantum yield of 58.3%. The enhanced intersystem crossing and the suppression of nonradiation decay derived from the tight matrices are responsible for the appreciable RTP. White‐light emission is further realized in both prompt state and delayed state. In this case, data encryption and decryption applications are successfully performed by using these complexes. The design and construction strategy embodied here render this approach promising for the exploitation of versatile RTP species for specific applications. The doping of aromatic‐acid‐based phosphors within solvento matrices leads to solid complexes featuring excellent room‐temperature phosphorescence properties: with maximum peaks in the range of 430–580 nm, the best lifetime of ≈1.9 s, and the highest yellow phosphorescence efficiency of 58.3%. Both prompt and delayed white‐light emission phenomena can be observed via mixed doping strategies, enabling enhanced data‐security applications.