Litcius/Paper detail

Exciton interactions in helical crystals of a hydrogen-bonded eumelanin monomer

Devika Sasikumar, Kavya Vinod, Jeswin Sunny, Mahesh Hariharan

2022Chemical Science16 citationsDOIOpen Access PDF

Abstract

Sohncke space group) incorporate enantiomeric zig-zag helical stacks arranged in a herringbone fashion with respect to each other. Each of the zig-zag helical stacks originates from a bifurcated hydrogen bonding interaction between the hydroxyl substituents in adjacent DHI chromophores which act as the backbone structure for the helical assembly. Fragment-based excited state analysis performed on the DHI crystalline assembly demonstrates exciton delocalization along the DHI units that connect each enantiomeric helical stack while, within each stack, the excitons remain localized. Fascinatingly, over the time evolution for generation of single-crystals of the DHI-monomer, mesoscopic double-helical crystals are formed, possibly attributed to the presence of covalently connected DHI trimers in chloroform solution. The oligomeric DHI (in line with the chemical disorder model) along with the characteristic crystalline packing observed for DHI provides insights into the broadband absorption feature exhibited by the chromophore.

Topics & Concepts

TrimerMonomerMesoscopic physicsChirality (physics)ExcitonCrystallographyEnantiomerMaterials scienceCovalent bondHydrogen bondChemistryStereochemistryPolymerMoleculeOrganic chemistryChiral symmetryDimerCondensed matter physicsPhysicsComposite materialQuantum mechanicsNambu–Jona-Lasinio modelQuarkmelanin and skin pigmentationBiochemical Analysis and Sensing TechniquesAcne and Rosacea Treatments and Effects