Litcius/Paper detail

Unraveling the Role of Structural Topology on Chirality Transfer and Chiroptical Properties in Chiral Germanium Iodides

Clarissa Coccia, Marco Moroni, Antonella Treglia, Massimo Boiocchi, Yali Yang, Chiara Milanese, Marta Morana, Doretta Capsoni, Alessio Porta, Annamaria Petrozza, Alessandro Stroppa, Lorenzo Malavasi

2024Journal of the American Chemical Society26 citationsDOI

Abstract

Chiral hybrid organic–inorganic metal halides are highly promising chiroptoelectronic materials with potential applications in several fields, such as circularly polarized photodetectors, second-order nonlinear optics, and spin-selective devices. However, the ability of manipulating the chiroptical response and the chirality transfer from the organic ligands require one to shed light on structure–property correlations. Herein, we devised and prepared two novel Ge-based chiral hybrid organic–inorganic metal halides showing a different structural topology, namely, a 1D and a 2D arrangement, but composed of the same chemical building blocks: ( R / S -ClMBA) 3 GeI 5 and ( R / S -ClMBA) 2 GeI 4 . Through a combined experimental and computational investigation on these samples, we discuss the impact of structural dimensionality on chiroptical properties, chirality transfer, and spin-splitting effects; also, we highlight the impact of structural distortions. The approach presented here paves the way for a solid understanding of the factors affecting the properties of chiral metal halides, thus allowing a future wise materials engineering.

Topics & Concepts

Chirality (physics)ChemistryTopology (electrical circuits)HalideMetalGermaniumCircular polarizationMetal halidesChemical physicsNanotechnologyOpticsOrganic chemistryPhysicsMaterials scienceQuantum mechanicsChiral anomalyNambu–Jona-Lasinio modelCombinatoricsSiliconFermionMicrostripMathematicsPerovskite Materials and ApplicationsCrystal Structures and PropertiesSolid-state spectroscopy and crystallography