11 research outputs found
Intramolecular Hypervalent Interaction in the Conjugate Five-Membered Rings
The intramolecular hypervalent interaction between the electron abundant atomic centers X and Y belonging to the IVāVI groups and second and fourth periods has been computationally studied on a model quasi-cyclic conjugate five-membered ring system <b>9</b> using the CCSD/6-311+G** and DFT B3LYP/6-311+G** methods. Electronic and structural factors affecting the strength and geometrical characteristics of the hypervalent XāY interaction were analyzed based on the quantum theory of atoms in molecules (QTAIM) and natural bond orbital (NBO) analyses. The donorāacceptor <i>n</i><sub>Y</sub>āĻ*<sub>XR</sub> interaction has been shown to be the central factor correlating all important properties of the studied hypervalently bonded compounds <b>9</b>
Group 14 element cationic pentagonalāpyramidal complexes E<sup>a</sup>[<i>Ī·</i><sup>5</sup>-E<sup>b</sup><sub>5</sub>(SiMe<sub>3</sub>)<sub>5</sub>]<sup>+</sup> (E<sup>a</sup> = SiāPb, E<sup>b</sup> = Si, Ge): A quantum-chemical study
<p>Heavy 14 group element cationic half-sandwich complexes E<sup>a</sup>[Ī·<sup>5</sup>-E<sup>b</sup><sub>5</sub>(SiMe<sub>3</sub>)<sub>5</sub>]<sup>+</sup> (E<sup>a</sup> = SiāPb, E<sup>b</sup> = Si, Ge) have been studied at the B3LYP/Def2TZVP level of theory. Structures of the neutral complexes {Si[Si<sub>5</sub>(SiMe<sub>3</sub>)<sub>5</sub>]}<sup>+</sup>Cl<sup>ā</sup> and {Si[Si<sub>5</sub>(SiMe<sub>3</sub>)<sub>5</sub>]}<sup>+</sup>[AlCl<sub>4</sub>]<sup>ā</sup> are also discussed.</p
Supertetrahedral Aluminum ā A New Allotropic Ultralight Crystalline Form of Aluminum
A new metastable
ultralight crystalline form of aluminum has been computationally designed
using density functional calculations with imposing periodic boundary
conditions. The geometric and electronic structures of the predicted
new allotrope were calculated on the basis of a diamond lattice in
which all carbon atoms are replaced by aluminum Al<sub>4</sub> tetrahedra.
The new form of crystalline aluminum has an extremely low density
of 0.61 g/cm<sup>3</sup> and would float in water. The new aluminum
form is a semimetal and shows high plasticity
From Borapyramidane to Borole Dianion
Nonclassical
pyramidanes with their inverted tetrahedral configuration
of the apical atom are among the most challenging synthetic targets
in cluster chemistry. In this Communication, we report on the synthesis
and structure of the first representative of pyramidal compounds with
the group 13 element at the apex, namely, chloroborapyramidane <b>2</b>. Reduction of <b>2</b> with excess of lithium metal
unexpectedly produced the cage-opening product, borole dianion derivative <b>{3</b><sup><b>2ā</b></sup><b>Ā·[LiĀ(thf)</b><sup><b>+</b></sup><b>]</b><sub><b>2</b></sub><b>}</b>, a 6Ļ-electron aromatic system
From Borapyramidane to Borole Dianion
Nonclassical
pyramidanes with their inverted tetrahedral configuration
of the apical atom are among the most challenging synthetic targets
in cluster chemistry. In this Communication, we report on the synthesis
and structure of the first representative of pyramidal compounds with
the group 13 element at the apex, namely, chloroborapyramidane <b>2</b>. Reduction of <b>2</b> with excess of lithium metal
unexpectedly produced the cage-opening product, borole dianion derivative <b>{3</b><sup><b>2ā</b></sup><b>Ā·[LiĀ(thf)</b><sup><b>+</b></sup><b>]</b><sub><b>2</b></sub><b>}</b>, a 6Ļ-electron aromatic system
Pyramidanes
Pyramidane
is an elusive but highly desirable target for synthetic
chemists that has attracted a great deal of attention because of its
nonclassical structure and unusual bonding features. Although well
studied on theoretical grounds, neither the parent all-carbon pyramidane
nor its derivatives containing heavier group 14 elements have ever
been isolated and characterized. In this Communication, we report
on the synthesis and structural elucidation of the first stable representatives
of this class of highly strained polyhedral compounds: germa- and
stannapyramidanes Ge[C<sub>4</sub>(SiMe<sub>3</sub>)<sub>4</sub>] and SnĀ[C<sub>4</sub>(SiMe<sub>3</sub>)<sub>4</sub>]. The peculiar structural and bonding features of these
compounds are verified by combined experimental and computational
analyses, showing these derivatives to be nonclassical neutral compounds
with a very large contribution of ionic character
From Borapyramidane to Borole Dianion
Nonclassical
pyramidanes with their inverted tetrahedral configuration
of the apical atom are among the most challenging synthetic targets
in cluster chemistry. In this Communication, we report on the synthesis
and structure of the first representative of pyramidal compounds with
the group 13 element at the apex, namely, chloroborapyramidane <b>2</b>. Reduction of <b>2</b> with excess of lithium metal
unexpectedly produced the cage-opening product, borole dianion derivative <b>{3</b><sup><b>2ā</b></sup><b>Ā·[LiĀ(thf)</b><sup><b>+</b></sup><b>]</b><sub><b>2</b></sub><b>}</b>, a 6Ļ-electron aromatic system
From Borapyramidane to Borole Dianion
Nonclassical
pyramidanes with their inverted tetrahedral configuration
of the apical atom are among the most challenging synthetic targets
in cluster chemistry. In this Communication, we report on the synthesis
and structure of the first representative of pyramidal compounds with
the group 13 element at the apex, namely, chloroborapyramidane <b>2</b>. Reduction of <b>2</b> with excess of lithium metal
unexpectedly produced the cage-opening product, borole dianion derivative <b>{3</b><sup><b>2ā</b></sup><b>Ā·[LiĀ(thf)</b><sup><b>+</b></sup><b>]</b><sub><b>2</b></sub><b>}</b>, a 6Ļ-electron aromatic system
Pyramidanes
Pyramidane
is an elusive but highly desirable target for synthetic
chemists that has attracted a great deal of attention because of its
nonclassical structure and unusual bonding features. Although well
studied on theoretical grounds, neither the parent all-carbon pyramidane
nor its derivatives containing heavier group 14 elements have ever
been isolated and characterized. In this Communication, we report
on the synthesis and structural elucidation of the first stable representatives
of this class of highly strained polyhedral compounds: germa- and
stannapyramidanes Ge[C<sub>4</sub>(SiMe<sub>3</sub>)<sub>4</sub>] and SnĀ[C<sub>4</sub>(SiMe<sub>3</sub>)<sub>4</sub>]. The peculiar structural and bonding features of these
compounds are verified by combined experimental and computational
analyses, showing these derivatives to be nonclassical neutral compounds
with a very large contribution of ionic character
Bis(stibahousene)
Strained
hydrocarbons constitute one of the most prominent classes
of organic compounds. Among them, bicyclo[2.1.0]Āpentene (āhouseneā)
derivatives represent a highly challenging and very attractive class.
Although organic housenes have been known for more than five decades,
there are still very few of them containing heavier main group elements.
In this paper, we report on the two housene-type structures, novel
monomeric stibahousene and dimeric bisĀ(stibahousene). The bonding
natures of both compounds were approached from both experimental and
computational directions to reveal their peculiar structural features