AI Article Synopsis
- The tris(alkoxo)-ligated Lindqvist-type polyoxovanadates show easy chemical post-functionalization of the R group and exhibit interesting conductive properties related to their V(3d) redox states.
- The study investigates how charge stability and distribution depend on the R functionalities and various countercations (K, Li, NH, H, Mg).
- Findings reveal that hexavanadate structures can accept multiple electrons based on the cation type, emphasizing the role of countercations for potential applications in molecular memories and batteries.
Article Abstract
One of the striking characteristics of the tris(alkoxo)-ligated Lindqvist-type polyoxovanadates [VV6O{(OCH)CR}] in highest oxidation state in solution is the ease of their chemical post-functionalization the R group. On surfaces it is their conductivity as a function of individual V(3d) redox states. In both cases, the structural stability of the fully-oxidized dianion is enabled by charge-balancing counterions. In this Article, we explore the charge stability and the charge distibution across the molecular Lindqvist-type hexavanadate structure regarding the R functionality (R = OCHN, CHN, and OCHN) and the different type of countercations (Cat = K, Li, NH, H, or Mg). We show that the hexavanadate core can accept in its vacant V(3d) orbitals at least four and, in some cases, up to nine additional electrons if the negative charge is offset by the corresponding cation(s), without electron leakage to the covalently attached R groups. Remarkably, the maximum number of accepted electrons strongly depends on the type of cation(s) and is independent on the type of the remote R group exploited herein. The (Cat)[VV6O{(OCH)CR}] complexes exibit the structural integrity in all studied charged states. Our study demonstrates the importance of the countercations of multistate polyoxovanadate nanoswitches for the development of multi-charge based molecular memories and/or batteries.
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Article Synopsis
- The tris(alkoxo)-ligated Lindqvist-type polyoxovanadates show easy chemical post-functionalization of the R group and exhibit interesting conductive properties related to their V(3d) redox states.
- The study investigates how charge stability and distribution depend on the R functionalities and various countercations (K, Li, NH, H, Mg).
- Findings reveal that hexavanadate structures can accept multiple electrons based on the cation type, emphasizing the role of countercations for potential applications in molecular memories and batteries.
A series of organic hybrid polyoxovanadate clusters incorporating tris(hydroxymethyl)methane derivatives.
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