Litcius/Paper detail

Single-component-based multicolor emissions enabled by symmetry breaking

Simin Lin, Xubin Wang, Hao Li, Jiancheng Zhou, Ruijuan Wen, Jun Ma, Shiwei Yin, Ling‐Ya Peng, Haonan Peng, Yu Fang

2025Nature Communications8 citationsDOIOpen Access PDF

Abstract

Excitation-dependent multicolor emission from a single-component system, independent of aggregation, remains a fundamental challenge due to inherent difficulties in innovative principles. Herein, we propose a molecular symmetry-breaking strategy to enrich electronic processes, enabling the molecule to exhibit excitation-dependent multicolor emissions from one chemical entity. A star-shaped molecule, 1,3,5-(4-tert-butylphenyl-o-carboranyl-4-phenyl)benzene (Ph-3CP) is designed, where spatial restriction induces inequivalence among three bulky, non-planar branches. This asymmetry gives rise to a broad excitation-dependent emission range of nearly 175 nm across solution, amorphous, and crystalline states. Crystallization from different solvents successfully traps distinct asymmetric conformers of Ph-3CP, providing direct experimental evidence for the predicted symmetry-breaking structures from theoretical calculations. Structure-property relationship studies further reveal two distinct relaxation pathways that dominate the emission behavior of this molecular system. Leveraging these properties, we develop a single-component fluorescence sensor array that enables rapid and selective identification of chlorinated hydrocarbon vapors. This work provides a general strategy for designing multifunctional luminescent materials through symmetry-controlled excited-state engineering.

Topics & Concepts

Component (thermodynamics)Symmetry breakingPhysicsComputer scienceBiological systemBiologyQuantum mechanicsLuminescence and Fluorescent MaterialsAdvanced Optical Sensing TechnologiesOcular and Laser Science Research
Single-component-based multicolor emissions enabled by symmetry breaking | Litcius