Litcius/Paper detail

Regulating the Piezoelectricity of Cyclic Dipeptide-Based Supramolecular Materials through Co-Assembly Strategy

Xin Su, Shuaijie Liu, Xuewen Gong, Xiaoyu Tong, Lingling Li, Yehong Huo, Qingxi Liu, Yuehui Wang, Mei‐Ling Tan, Qi Li, Shijin Zhang, Wei Ji

2025Journal of the American Chemical Society13 citationsDOI

Abstract

Supramolecular co-assembly can modulate the architecture of molecular assemblies, thereby influencing their electromechanical properties. However, the relationship between supramolecular packing and electromechanical response of co-assemblies remains largely unexplored, posing a challenge in designing high-performance bioinspired piezoelectric materials. Herein, we combined experiments and theoretical calculations to systematically explore the regulation of supramolecular packing and electromechanical properties of cyclic l -aspartyl- l -aspartyl (cyclo-DD (LL))-based assemblies through co-assembling with pyridine derivatives. Crystal structures indicated that intermolecular hydrogen bonding between the carboxyl group of the cyclic dipeptide and the pyridine ring resulted in a markedly different molecular organizations and packing modes of co-assemblies. Density functional theory calculations revealed that increasing the molecular length of the pyridine derivatives enhanced the polarization effect and piezoelectric response of the cyclo-DD (LL)-based co-assemblies due to the reduced structural symmetry. Notably, the maximum piezoelectric coefficient of the cyclo-DD (LL)/4,4′-trimethylenedipyridine (TDP) co-assembly was predicted to be 140.8 pC/N, representing the highest value among peptide-based co-assemblies. Furthermore, cyclo-DD (LL)/TDP co-assembly based piezoelectric nanogenerator could generate stable open-circuit voltages over 3 V under an applied mechanical force of 50 N. For the first time, peptide-based co-assemblies were utilized as active piezoelectric materials to successfully power a display screen. Moreover, the effect of chirality on the piezoelectricity of cyclic dipeptide-based co-assemblies was investigated. This work presents an effective co-assembly strategy to manipulate the piezoelectric response of bioinspired cyclic dipeptide-based assemblies, advancing the development of high-performance piezoelectric molecular materials for sustainable energy harvesting systems.

Topics & Concepts

ChemistryDipeptideSupramolecular chemistryPiezoelectricityCombinatorial chemistryNanotechnologyStereochemistryCrystallographyPeptideCrystal structureBiochemistryComposite materialMaterials sciencePolydiacetylene-based materials and applicationsSupramolecular Self-Assembly in MaterialsAdvanced Sensor and Energy Harvesting Materials