Aromaticity in heterocyclic analogues of benzene: Dissected NICS and current density analysis

R. Báez-Grez; Walter A. Rabanal-León; Luis Alvarez-Thon; Lina Ruiz; W. Tiznado; R. Pino-Rios

doi:10.1002/poc.3823

Aromaticity in heterocyclic analogues of benzene: Dissected NICS and current density analysis

R. Báez-Grez
, Walter A. Rabanal-León
, Luis Alvarez-Thon
, Lina Ruiz
, W. Tiznado
, R. Pino-Rios

Research output: Contribution to journal › Article › peer-review

35 Scopus citations

Abstract

The magnetic aromaticity of 6-membered monoheterocycles containing Group 13 to 16 elements (C₅H₅X, where X = SiH, GeH, N, P, As, O⁺, S⁺, Se⁺) was assessed by using 2 magnetic descriptors: the π-electron contribution to the out-of-plane component of the nucleus-independent chemical shifts (NICSzz,_π) and ring current strength. The results show that both descriptors lead to the same conclusion regarding magnetic aromaticity. However, they do not agree with the predictions obtained by isotropic NICS, which is a most commonly used method. Ring current strength and NICS_π predict that benzene is the most aromatic molecule of the series, with an only slightly less aromatic pyridine. Additionally, aromaticity decreases when going down in the same group of the periodic system. The only exception is the pyrylium cation, which is predicted as the least aromatic species of this series.

Original language	English
Article number	e3823
Journal	Journal of Physical Organic Chemistry
Volume	32
Issue number	1
DOIs	https://doi.org/10.1002/poc.3823
State	Published - Jan 2019

Keywords

benzene analogues
current density
magnetic aromaticity
NICS

Access to Document

10.1002/poc.3823

Cite this

@article{7a4b0c1d196048fea321ba143efcd2d2,

title = "Aromaticity in heterocyclic analogues of benzene: Dissected NICS and current density analysis",

abstract = "The magnetic aromaticity of 6-membered monoheterocycles containing Group 13 to 16 elements (C5H5X, where X = SiH, GeH, N, P, As, O+, S+, Se+) was assessed by using 2 magnetic descriptors: the π-electron contribution to the out-of-plane component of the nucleus-independent chemical shifts (NICSzz,π) and ring current strength. The results show that both descriptors lead to the same conclusion regarding magnetic aromaticity. However, they do not agree with the predictions obtained by isotropic NICS, which is a most commonly used method. Ring current strength and NICSπ predict that benzene is the most aromatic molecule of the series, with an only slightly less aromatic pyridine. Additionally, aromaticity decreases when going down in the same group of the periodic system. The only exception is the pyrylium cation, which is predicted as the least aromatic species of this series.",

keywords = "benzene analogues, current density, magnetic aromaticity, NICS",

author = "R. B{\'a}ez-Grez and Rabanal-Le{\'o}n, \{Walter A.\} and Luis Alvarez-Thon and Lina Ruiz and W. Tiznado and R. Pino-Rios",

note = "Publisher Copyright: Copyright {\textcopyright} 2018 John Wiley \& Sons, Ltd.",

year = "2019",

month = jan,

doi = "10.1002/poc.3823",

language = "English",

volume = "32",

journal = "Journal of Physical Organic Chemistry",

issn = "0894-3230",

number = "1",

}

TY - JOUR

T1 - Aromaticity in heterocyclic analogues of benzene

T2 - Dissected NICS and current density analysis

AU - Báez-Grez, R.

AU - Rabanal-León, Walter A.

AU - Alvarez-Thon, Luis

AU - Ruiz, Lina

AU - Tiznado, W.

AU - Pino-Rios, R.

PY - 2019/1

Y1 - 2019/1

N2 - The magnetic aromaticity of 6-membered monoheterocycles containing Group 13 to 16 elements (C5H5X, where X = SiH, GeH, N, P, As, O+, S+, Se+) was assessed by using 2 magnetic descriptors: the π-electron contribution to the out-of-plane component of the nucleus-independent chemical shifts (NICSzz,π) and ring current strength. The results show that both descriptors lead to the same conclusion regarding magnetic aromaticity. However, they do not agree with the predictions obtained by isotropic NICS, which is a most commonly used method. Ring current strength and NICSπ predict that benzene is the most aromatic molecule of the series, with an only slightly less aromatic pyridine. Additionally, aromaticity decreases when going down in the same group of the periodic system. The only exception is the pyrylium cation, which is predicted as the least aromatic species of this series.

AB - The magnetic aromaticity of 6-membered monoheterocycles containing Group 13 to 16 elements (C5H5X, where X = SiH, GeH, N, P, As, O+, S+, Se+) was assessed by using 2 magnetic descriptors: the π-electron contribution to the out-of-plane component of the nucleus-independent chemical shifts (NICSzz,π) and ring current strength. The results show that both descriptors lead to the same conclusion regarding magnetic aromaticity. However, they do not agree with the predictions obtained by isotropic NICS, which is a most commonly used method. Ring current strength and NICSπ predict that benzene is the most aromatic molecule of the series, with an only slightly less aromatic pyridine. Additionally, aromaticity decreases when going down in the same group of the periodic system. The only exception is the pyrylium cation, which is predicted as the least aromatic species of this series.

KW - benzene analogues

KW - current density

KW - magnetic aromaticity

KW - NICS

UR - https://www.scopus.com/pages/publications/85043386759

U2 - 10.1002/poc.3823

DO - 10.1002/poc.3823

M3 - Article

AN - SCOPUS:85043386759

SN - 0894-3230

VL - 32

JO - Journal of Physical Organic Chemistry

JF - Journal of Physical Organic Chemistry

IS - 1

M1 - e3823

ER -

Aromaticity in heterocyclic analogues of benzene: Dissected NICS and current density analysis

Abstract

Keywords

Access to Document

Other files and links

Fingerprint

Cite this