Das, Prasenjit ; Chattaraj, Pratim Kumar (2022) Structure and Bonding in Planar Hypercoordinate Carbon Compounds Chemistry, 4 (4). pp. 1723-1756. ISSN 2624-8549
Full text not available from this repository.
Official URL: http://doi.org/10.3390/chemistry4040113
Related URL: http://dx.doi.org/10.3390/chemistry4040113
Abstract
The term hypercoordination refers to the extent of the coordination of an element by its normal value. In the hypercoordination sphere, the element can achieve planar and/or non-planar molecular shape. Hence, planar hypercoordinate carbon species violate two structural rules: (i) The highest coordination number of carbon is four and (ii) the tetrahedral orientation by the connected elements and/or groups. The unusual planar orientations are mostly stabilized by the electronic interactions of the central atom with the surrounding ligands. In this review article, we will talk about the current progress in the theoretical prediction of viable planar hypercoordinate carbon compounds. Primary knowledge of the planar hypercoordinate chemistry will lead to its forthcoming expansion. Experimental and theoretical interests in planar tetracoordinate carbon (ptC), planar pentacoordinate carbon (ppC), and planar hexacoordinate carbon (phC) are continued. The proposed electronic and mechanical strategies are helpful for the designing of the ptC compounds. Moreover, the 18-valence electron rule can guide the design of new ptC clusters computationally as well as experimentally. However, the counting of 18-valence electrons is not a requisite condition to contain a ptC in a cluster. Furthermore, this ptC idea is expanded to the probability of a greater coordination number of carbon in planar orientations. Unfortunately, until now, there are no such logical approaches to designing ppC, phC, or higher-coordinate carbon molecules/ions. There exist a few global minimum structures of phC clusters identified computationally, but none have been detected experimentally. All planar hypercoordinate carbon species in the global minima may be feasible in the gas phase.
Item Type: | Article |
---|---|
Source: | Copyright of this article belongs to MDPI (Basel, Switzerland) |
Keywords: | anti-van’t Hoff Le Bel; planar tetracoordinate carbon; planar pentacoordinate carbon; planar hexacoordinate carbon; σ/π-dual aromaticity |
ID Code: | 133253 |
Deposited On: | 27 Dec 2022 09:40 |
Last Modified: | 27 Dec 2022 09:40 |
Repository Staff Only: item control page