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Remote chirality transfer in low-dimensional hybrid metal halide semiconductors
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Remote chirality transfer in low-dimensional hybrid metal halide semiconductors
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Journal Article
Remote chirality transfer in low-dimensional hybrid metal halide semiconductors
2025
Overview
In hybrid metal halide perovskites, chiroptical properties typically arise from structural symmetry breaking by incorporating a chiral A-site organic cation within the structure, which may limit the compositional space. Here we demonstrate highly efficient remote chirality transfer where chirality is imposed on an otherwise achiral hybrid metal halide semiconductor by a proximal chiral molecule that is not interspersed as part of the structure yet leads to large circular dichroism dissymmetry factors (
g
CD
) of up to 10
−2
. Density functional theory calculations reveal that the transfer of stereochemical information from the chiral proximal molecule to the inorganic framework is mediated by selective interaction with divalent metal cations. Anchoring of the chiral molecule induces a centro-asymmetric distortion, which is discernible up to four inorganic layers into the metal halide lattice. This concept is broadly applicable to low-dimensional hybrid metal halides with various dimensionalities (1D and 2D) allowing independent control of the composition and degree of chirality.
Hybrid metal halide semiconductors typically rely on chiral A-site ammonium cations for chiral induction in the lattice. Now it has been shown that chirality in low-dimensional achiral metal halide semiconductors can be induced by non-ammonium, non-A-site chiral molecules through remote stereocontrol of the inorganic framework.
Publisher
Nature Publishing Group UK,Nature Publishing Group
