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Temperature-Dependent <sup>207</sup>Pb Nuclear Magnetic Resonance Spectroscopy: A Spectroscopic Probe for the Local Electronic Structure of Lead Halide Perovskites

Sebastian Sabisch, Marcel Aebli, Andrii Kanak, Viktoriia Morad, Simon C. Boehme, Michael Wörle, Leon G. Feld, Christophe Copéret, Maksym V. Kovalenko

2025Chemistry of Materials7 citationsDOIOpen Access PDF

Abstract

High Resolution Image Download MS PowerPoint Slide Lead halide perovskites (LHPs) have garnered considerable interest, owing to their advantageous optoelectronic properties and ease of synthesis. However, understanding their intricate structure–property relationships remains challenging, for both bulk and nanoscale forms, such as colloidal quantum dots (QDs). In this study, in addition to conventional characterization by X-ray diffraction and optical absorption, we show that variable temperature solid-state nuclear magnetic resonance spectroscopy, complemented by computational modeling, provides unique insight into the local coordination geometry and electronic structure of LHPs in relation to the moderate change in composition or materials morphology. For CsPbBr 3 and FAPbBr 3 in the form of QDs and bulk, we uncover nuanced disparities between their orthorhombic and on-average cubic structures, respectively, reflected in their temperature-dependent 207 Pb chemical shifts and optical band gaps. Specifically, the mode of thermal expansion, be it the increase of the Pb–Br–Pb angles in the orthorhombic structure or the elongation of the Pb–Br bonds in a cubic lattice, gives rise to an increase of the chemical shift by 0.63 or 1.53 ppm/K and optical band gap by 0.18 or 0.66 meV/K, respectively. Identifying the chemical shift as a spectroscopic descriptor, in particular as a lattice ruler, is highly instrumental also for LHP QDs, capturing the difference between CsPbBr 3 and FAPbBr 3 . In a broader perspective, establishing relations across spectroscopic and structural descriptors for diverse LHP compositions and morphologies paves the way for informed design strategies in next-generation optoelectronic devices.

Topics & Concepts

HalideSpectroscopyNuclear magnetic resonance spectroscopyResonance (particle physics)Materials scienceElectronic structureNuclear magnetic resonanceAtomic physicsChemistryAnalytical Chemistry (journal)PhysicsInorganic chemistryCondensed matter physicsChromatographyQuantum mechanicsPerovskite Materials and ApplicationsSolid-state spectroscopy and crystallographyMagnetic and transport properties of perovskites and related materials
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