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Five-Membered Heterocyclic Aromatic Compounds: Overview01:13

Five-Membered Heterocyclic Aromatic Compounds: Overview

5.8K
Heterocyclic aromatic compounds are cyclic compounds that are aromatic and have one or more heteroatoms—atoms other than carbon, in the ring. Depending upon the number of atoms present in the ring, they can be either five or six-membered. Examples of five-membered heterocyclic aromatic compounds include pyrrole, furan, thiophene, and imidazole. Pyrrole consists of one nitrogen atom having one lone pair of electrons. Furan and thiophene have one oxygen and one sulfur heteroatom,...
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Aromatic Hydrocarbon Cations: Structural Overview01:18

Aromatic Hydrocarbon Cations: Structural Overview

4.0K
Cycloheptatriene is a neutral monocyclic unsaturated hydrocarbon that consists of an odd number of carbon atoms and an intervening sp3 carbon in the ring. The three double bonds in the ring correspond to 6 π electrons, which is a Huckel number, and therefore satisfies the criteria of 4n + 2 π electrons. However, the intervening sp3 carbon disrupts the continuous overlap of p orbitals. As a result, cycloheptatriene is not aromatic.
Removing one hydrogen from the intervening CH2 group...
4.0K
Aromatic Hydrocarbon Anions: Structural Overview01:18

Aromatic Hydrocarbon Anions: Structural Overview

4.0K
Neutral hydrocarbons like cyclopentadiene with an odd number of carbon atoms and one intervening CH2 group in the ring are not aromatic. Cyclopentadiene with 4 π electrons does not satisfy the 4n + 2 π electron rule. Additionally, the intervening CH2 group is sp3 hybridized and lacks a vacant p orbital, thereby interrupting the overlap of p orbitals in a continuous manner and preventing the delocalization of π electrons throughout the ring.
Due to the absence of continuous...
4.0K
Frost Circles for Different Conjugated Systems01:18

Frost Circles for Different Conjugated Systems

3.9K
The inscribed polygon method is consistent with Hückel’s 4n + 2 rule and helps to learn whether the given cyclic compound is aromatic or not. The compound is stable and aromatic if every bonding molecular orbital (MO) is completely filled with a pair of electrons. However, if the non-bonding or antibonding orbitals are filled with electrons, the compound is unstable and not aromatic. Consider the Frost circle diagrams for cycloalkenes containing 4 to 8 carbons.
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Conformations of Cycloalkanes02:29

Conformations of Cycloalkanes

15.4K
Adolf von Baeyer attempted to explain the instabilities of small and large cycloalkane rings using the concept of angle strain — the strain caused by the deviation of bond angles from the ideal 109.5° tetrahedral value for sp3  hybridized carbons. However, while cyclopropane and cyclobutane are strained, as expected from their highly compressed bond angles, cyclopentane is more strained than predicted, and cyclohexane is virtually strain-free. Hence, Baeyer’s theory that...
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Conformations of Cyclohexane02:11

Conformations of Cyclohexane

16.3K
Cyclohexane does not exist in a planar form due to the high angle and torsional strain it would experience in the planar structure. Instead, it adopts non-planar chair and boat conformations.
The chair form is the most stable and derives its name from its resemblance to the “easy chair.” In the chair conformation, two carbon atoms are arranged out-of-plane — one above and one below, minimizing the torsional strain. In the chair form, the bond angle is very close to the ideal...
16.3K

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Related Experiment Video

Updated: Feb 24, 2026

Preparation of a Corannulene-functionalized Hexahelicene by CopperI-catalyzed Alkyne-azide Cycloaddition of Nonplanar Polyaromatic Units
09:35

Preparation of a Corannulene-functionalized Hexahelicene by CopperI-catalyzed Alkyne-azide Cycloaddition of Nonplanar Polyaromatic Units

Published on: September 18, 2016

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Spherical Congeners of Polyaromatic Compounds Approaching C20- and C60-Fullerene-Type Structures.

Herbert Höpfl1, Mario Sánchez2, Jonas Baltrusaitis3

  • 1Centro de Investigaciones Químicas, Instituto de Investigación en Ciencias Básicas y Aplicadas, Universidad Autónoma del Estado de Morelos, Av. Universidad 1001, Cuernavaca 62209, Morelos, México.

ACS Nanoscience Au
|February 23, 2026
PubMed
Summary

Computational modeling explored novel molecular organic cages, revealing tunable electronic properties. These cage structures show potential for various applications due to their unique electronic characteristics.

Keywords:
Cage assembly through covalent bondsDFT calculationsFullerene-type structuresOrganic cage compoundsPolyaromatic compoundsSpherical polyhedra

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Area of Science:

  • Materials Science
  • Computational Chemistry
  • Supramolecular Chemistry

Background:

  • Molecular organic cages are cage-like structures with potential applications in various fields.
  • Symmetric, hollow spherical, and shape-persistent molecular organic cages analogous to C20 and C60 are of interest.

Purpose of the Study:

  • To computationally examine three symmetric, hollow spherical, and shape-persistent molecular organic cages.
  • To analyze their structural elements, strain indicators, and physical properties for potential applications.

Main Methods:

  • Computational modeling was employed to study the molecular organic cages.
  • Natural Bond Orbital (NBO) and Molecular ESP (MESP) analyses were performed.
  • Structural elements, strain indicators, and physical properties were analyzed.

Main Results:

  • Three cage compounds were examined, with diameters ranging from 2.3 to 4.2 nm.
  • The cages feature electrophilic and nucleophilic sites within their molecular skeletons.
  • HOMO-LUMO gaps were found to be around 4.0 eV for phenylene-connected cages, reduced by ~0.4 eV for pyrene-connected cages.

Conclusions:

  • The studied molecular organic cages exhibit tunable electronic properties based on their structural components.
  • The presence of electrophilic and nucleophilic sites suggests potential for chemical interactions.
  • The variation in HOMO-LUMO gaps indicates potential for applications requiring specific electronic characteristics.