Organic Cation Conformational Flexibility Governs Mechanical Response in Organic-Inorganic Hybrid Materials

Abstract

Organic-inorganic hybrids, that couple the structural design flexibility of organics and the rigidity of inorganic lattices, are gaining attention as next-generation stimuli-responsive materials for adaptive actuation applications. Understanding and controlling mechanical responses in organic-inorganic hybrids is vital for the development of smart materials. Herein, we designed and introduced five-and six-membered ring cations with distinct conformational rigidities to obtain two hybrid halide crystals, (Hmpy)PbI 3 (1, Hmpy = 2-hydroxymethyl-pyrrolidinium) and (Hmpi)PbI 3 (2, Hmpi = 2-hydroxymethylpiperidinium). Compound 1 exhibits a moderate reversible deformation of 5% with pronounced shape-locking. In contrast, compound 2 shows a large reversible deformation up to 17%. Structural and variable-temperature Raman analyses establish the adaptability of organic cations as the governing factor for ferroelastic strain modulation, operating through controlled ring dynamics and lattice slippage mechanisms. These results establish a clear structure-mechanics relationship: conformational rigidity promotes shape-locking, while enhanced conformational flexibility enables greater actuation freedom. Decoding the structural code behind mechanical response offers a rational basis for designing adaptive crystals with shape memory function.