Structural chemistry of layered lead halide perovskites containing single octahedral layers

• Published in: IUCrJ Vol. 8; no. 4; pp. 485 - 513
• Main Authors: McNulty, Jason A., Lightfoot, Philip
• Format: Journal Article
• Language: English
• Published: Chester International Union of Crystallography 01.07.2021
• Subjects: Crystal structure; Crystallography; Crystals; Halides; hybrid materials; Interlayers; layered perovskites; Lead; Lead compounds; Metal halides; Perovskites; Stoichiometry; Symmetry; symmetry mode analysis; Unit cell
• ISSN: 2052-2525; 2052-2525
• DOI: 10.1107/S2052252521005418

We present a comprehensive review of the structural chemistry of hybrid lead halides of stoichiometry A Pb X 4 , A 2 PbX 4 or A A ′Pb X 4 , where A and A ′ are organic ammonium cations and X = Cl, Br or I. These compounds may be considered as layered perovskites, containing isolated, infinite layers of corner-sharing Pb X 4 octahedra separated by the organic species. First, over 250 crystal structures were extracted from the CCDC and classified in terms of unit-cell metrics and crystal symmetry. Symmetry mode analysis was then used to identify the nature of key structural distortions of the [Pb X 4 ] ∞ layers. Two generic types of distortion are prevalent in this family: tilting of the octahedral units and shifts of the inorganic layers relative to each other. Although the octahedral tilting modes are well known in the crystallography of purely inorganic perovskites, the additional layer-shift modes are shown to enormously enrich the structural options available in layered hybrid perovskites. Some examples and trends are discussed in more detail in order to show how the nature of the interlayer organic species can influence the overall structural architecture; although the main aim of the paper is to encourage workers in the field to make use of the systematic crystallographic methods used here to further understand and rationalize their own compounds, and perhaps to be able to design-in particular structural features in future work.