<HashMap><database>biostudies-literature</database><scores/><additional><submitter>Gahlot K</submitter><funding>Dutch Research Council (NWO)</funding><pagination>5177-5187</pagination><full_dataset_link>https://www.ebi.ac.uk/biostudies/studies/S-EPMC10918525</full_dataset_link><repository>biostudies-literature</repository><omics_type>Unknown</omics_type><volume>16(10)</volume><pubmed_abstract>Metal halide perovskite nanostructures, characterized by their ionic nature, present a compelling avenue for the tunability of dimensions and band gaps through facile compositional transformations involving both cationic and anionic exchange reactions. While post-synthetic ion-exchange processes have been extensively explored in Pb-halide perovskite nanocrystals, the inherent instability of Sn&lt;sup>2+&lt;/sup> has limited the exploration of such processes in Sn-halide perovskite nanostructures. In this study, we present a straightforward cation exchange process wherein 2D [R-NH&lt;sub>3&lt;/sub>]&lt;sub>2&lt;/sub>SnX&lt;sub>4&lt;/sub> Ruddlesden-Popper (RP) nanostructures with &lt;i>n&lt;/i> = 1 transition to 3D ASnX&lt;sub>3&lt;/sub> nanocrystals at room temperature with the addition of A-cation oleate. In addition, anion exchange processes have been demonstrated for both 2D [R-NH&lt;sub>3&lt;/sub>]&lt;sub>2&lt;/sub>SnX&lt;sub>4&lt;/sub> RP nanostructures and 3D nanocrystals, showcasing transitions between iodide and bromide counterparts. Furthermore, we have fabricated a thin film of 2D [R-NH&lt;sub>3&lt;/sub>]&lt;sub>2&lt;/sub>SnX&lt;sub>4&lt;/sub> RP nanostructures for cation exchange, wherein A-cation diffusion through a liquid-solid interface facilitates the transformation into a 3D ASnX&lt;sub>3&lt;/sub> crystal. This investigation underscores the versatility of ion exchange processes in engineering the composition of Sn-halide perovskite nanostructures and, consequently, modulating their optical properties.</pubmed_abstract><journal>Nanoscale</journal><pubmed_title>Structural and optical control through anion and cation exchange processes for Sn-halide perovskite nanostructures.</pubmed_title><pmcid>PMC10918525</pmcid><funding_grant_id>VI.Veni.192.048</funding_grant_id><pubmed_authors>Meijer J</pubmed_authors><pubmed_authors>Gahlot K</pubmed_authors><pubmed_authors>Protesescu L</pubmed_authors></additional><is_claimable>false</is_claimable><name>Structural and optical control through anion and cation exchange processes for Sn-halide perovskite nanostructures.</name><description>Metal halide perovskite nanostructures, characterized by their ionic nature, present a compelling avenue for the tunability of dimensions and band gaps through facile compositional transformations involving both cationic and anionic exchange reactions. While post-synthetic ion-exchange processes have been extensively explored in Pb-halide perovskite nanocrystals, the inherent instability of Sn&lt;sup>2+&lt;/sup> has limited the exploration of such processes in Sn-halide perovskite nanostructures. In this study, we present a straightforward cation exchange process wherein 2D [R-NH&lt;sub>3&lt;/sub>]&lt;sub>2&lt;/sub>SnX&lt;sub>4&lt;/sub> Ruddlesden-Popper (RP) nanostructures with &lt;i>n&lt;/i> = 1 transition to 3D ASnX&lt;sub>3&lt;/sub> nanocrystals at room temperature with the addition of A-cation oleate. In addition, anion exchange processes have been demonstrated for both 2D [R-NH&lt;sub>3&lt;/sub>]&lt;sub>2&lt;/sub>SnX&lt;sub>4&lt;/sub> RP nanostructures and 3D nanocrystals, showcasing transitions between iodide and bromide counterparts. Furthermore, we have fabricated a thin film of 2D [R-NH&lt;sub>3&lt;/sub>]&lt;sub>2&lt;/sub>SnX&lt;sub>4&lt;/sub> RP nanostructures for cation exchange, wherein A-cation diffusion through a liquid-solid interface facilitates the transformation into a 3D ASnX&lt;sub>3&lt;/sub> crystal. This investigation underscores the versatility of ion exchange processes in engineering the composition of Sn-halide perovskite nanostructures and, consequently, modulating their optical properties.</description><dates><release>2024-01-01T00:00:00Z</release><publication>2024 Mar</publication><modification>2025-04-04T12:34:43.575Z</modification><creation>2025-04-04T12:34:43.575Z</creation></dates><accession>S-EPMC10918525</accession><cross_references><pubmed>38385551</pubmed><doi>10.1039/d3nr06075f</doi></cross_references></HashMap>