Bright Circularly Polarized Mechanoluminescence from 0D Hybrid Manganese Halides

Hybrid metal halides (HMHs) with efficient circularly polarized luminescence (CPL) have application prospects in many fields, due to their abundant host–guest structures and high photoluminescence quantum yield (PLQY). However, CPLs in HMHs are predominantly excited by light or electricity, limiting their use in multivariate environments. It is necessary to explore a novel excitation method to extend the application of chiral HMHs as smart stimuli‐responsive optical materials. In this work, an enantiomeric pair of 0D hybrid manganese bromides, [H2(2R,4R)‐(+)/(2S,4S)‐(−)‐2,4‐bis(diphenylphosphino)pentane]MnBr4 [(R/S)‐1] is presented, which exhibits efficient CPL emissions with near‐unity PLQYs and high dissymmetry factors of ± 2.0 × 10−3. Notably, (R/S)‐1 compounds exhibit unprecedented and bright circularly polarized mechanoluminescence (CPML) emissions under mechanical stimulation. Moreover, (R/S)‐1 possess high mechanical force sensitivities with mechanoluminescence (ML) emissions detectable under 0.1 N force stimulation. Furthermore, this ML emission exhibits an extraordinary antithermal quenching effect in the temperature range of 300–380 K, which is revealed to originate from a thermal activation energy compensation mechanism from trap levels to Mn(II) 4T1 level. Based on their intriguing optical properties, these compounds as chiral force‐responsive materials are demonstrated in multilevel confidential information encryption. Circularly polarized mechanoluminescence (CPML) emissions are achieved in 0D chiral Mn‐based hybrid manganese halides with large conjugate ligands. These compounds exhibit highly bright and sensitive green CPML emissions with an extraordinary antithermal quenching effect, and then are demonstrated as chiral stimuli‐responsive materials in multilevel confidential information encryption.