Nuclear
Quadrupolar Resonance Structural Characterization
of Halide Perovskites and Perovskitoids: A Roadmap from Electronic
Structure Calculations for Lead–Iodide-Based Compounds
posted on 2024-12-24, 18:34authored byClaudio Quarti, Régis Gautier, Marios Zacharias, Axel Gansmuller, Claudine Katan
Metal
halide perovskites, including some of their related perovskitoid
structures, form a semiconductor class of their own, which is arousing
ever-growing interest from the scientific community. With halides
being involved in the various structural arrangements, namely, pure
corner-sharing MX6 (M is metal and X is halide) octahedra,
for perovskite networks, or alternatively a combination of corner-,
edge-, and/or face-sharing for related perovskitoids, they represent
the ideal probe for characterizing the way octahedra are linked together.
Well known for their inherently large quadrupolar constants, which
is detrimental to the resolution of nuclear magnetic resonance spectroscopy,
most abundant halide isotopes (35/37Cl, 79/81Br, 127I) are in turn attractive for magnetic field-free
nuclear quadrupolar resonance (NQR) spectroscopy. Here, we investigate
the possibility of exploiting NQR spectroscopy of halides to distinctively
characterize the various metal halide structural arrangements, using
density functional theory simulations. Our calculations nicely match
the available experimental results. Furthermore, they demonstrate
that compounds with different connectivities of their MX6 building blocks, including lower dimensionalities such as 2D networks,
show distinct NQR signals in a broad spectral window. They finally
provide a roadmap of the characteristic NQR frequency ranges for each
octahedral connectivity, which may be a useful guide to experimentalists,
considering the long acquisition procedures typical of NQR. We hope
this work will encourage the incorporation of NQR spectroscopy to
further our knowledge of the structural diversity of metal halides.