Litcius/Paper detail

Organic cation conformational flexibility governs mechanical response in organic–inorganic hybrid materials

Ya‐Wen Yang, Ke Xu, Zining Zhou, Ming‐Liang Jin, Ryo Tsunashima, Takayoshi Nakamura, Chao‐Yang Chai, Qiong Ye

2025Chemical Science5 citationsDOIOpen Access PDF

Abstract

(2, Hmpi = 2-hydroxymethyl-piperidinium). 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.

Topics & Concepts

Rigidity (electromagnetism)Flexibility (engineering)Materials scienceSlippageRational designStructural rigidityRaman spectroscopyLattice (music)NanotechnologyChemical physicsDeformation (meteorology)Molecular dynamicsHybrid materialShape-memory alloyConformational changeAdaptabilityCrystallographyMoleculeDesign elements and principlesMaterial DesignChemistryFolding (DSP implementation)Hybrid systemStructural stabilityPerspective (graphical)NanocrystalArtificial musclePolymer composites and self-healingAdvanced Materials and MechanicsDielectric materials and actuators