Geometrical and energetic characteristics of Se⋯Se interactions in crystal structures of organoselenium molecules

Veljković, Ivana S.; Kretić, Danijela S.; Veljković, Dušan

doi:10.1039/d1ce00129a

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2021

Authors

Veljković, Ivana S.

Kretić, Danijela S.

Veljković, Dušan

Article (Published version)

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Abstract

Non-covalent selenium-selenium interactions between selenium-containing organic molecules were studied in crystal structures from the Cambridge Structural Database and by high-level quantum chemical calculations. Se⋯Se contacts in the crystal structures were analyzed, and the most frequent patterns were identified and used to design the model systems for quantum chemical calculations. The strongest calculated Se⋯Se interaction (ΔECCSD(T)/CBS = -2.31 kcal mol-1) was identified in the model system with a mutual parallel orientation of interacting molecules. In the crystal structures, this orientation of molecules is predominant. In the geometry with the σ-hole bonding, the interaction is somewhat weaker (ΔECCSD(T)/CBS = -2.13 kcal mol-1). NCI analysis showed that Se⋯Se interaction in the most stable geometries is further enhanced by hydrogen bonding of Se-H⋯Se or C-H⋯Se type. The results of energy decomposition analysis (SAPT) calculations revealed that the nature of the Se⋯Se interactio...

Keywords:

crystal structures / organoselenium molecules

Source:
CrystEngComm, 2021, 23, 18, 3383-3390

Publisher:

Royal Society of Chemistry

Funding / projects:

DOI: 10.1039/d1ce00129a

ISSN: 1466-8033

WoS: 000641721300001

TY - JOUR
AU - Veljković, Ivana S.
AU - Kretić, Danijela S.
AU - Veljković, Dušan
PY - 2021
UR - https://cer.ihtm.bg.ac.rs/handle/123456789/4825
AB - Non-covalent selenium-selenium interactions between selenium-containing organic molecules were studied in crystal structures from the Cambridge Structural Database and by high-level quantum chemical calculations. Se⋯Se contacts in the crystal structures were analyzed, and the most frequent patterns were identified and used to design the model systems for quantum chemical calculations. The strongest calculated Se⋯Se interaction (ΔECCSD(T)/CBS = -2.31 kcal mol-1) was identified in the model system with a mutual parallel orientation of interacting molecules. In the crystal structures, this orientation of molecules is predominant. In the geometry with the σ-hole bonding, the interaction is somewhat weaker (ΔECCSD(T)/CBS = -2.13 kcal mol-1). NCI analysis showed that Se⋯Se interaction in the most stable geometries is further enhanced by hydrogen bonding of Se-H⋯Se or C-H⋯Se type. The results of energy decomposition analysis (SAPT) calculations revealed that the nature of the Se⋯Se interaction is predominantly dispersive with a strong electrostatic contribution. The results of the energy decomposition analysis also suggest that the electrostatic component has a crucial role in defining the geometry of selenium-selenium interactions due to their directional nature.
PB - Royal Society of Chemistry
T2 - CrystEngComm
T1 - Geometrical and energetic characteristics of Se⋯Se interactions in crystal structures of organoselenium molecules
VL - 23
IS - 18
SP - 3383
EP - 3390
DO - 10.1039/d1ce00129a
ER -

@article{
author = "Veljković, Ivana S. and Kretić, Danijela S. and Veljković, Dušan",
year = "2021",
abstract = "Non-covalent selenium-selenium interactions between selenium-containing organic molecules were studied in crystal structures from the Cambridge Structural Database and by high-level quantum chemical calculations. Se⋯Se contacts in the crystal structures were analyzed, and the most frequent patterns were identified and used to design the model systems for quantum chemical calculations. The strongest calculated Se⋯Se interaction (ΔECCSD(T)/CBS = -2.31 kcal mol-1) was identified in the model system with a mutual parallel orientation of interacting molecules. In the crystal structures, this orientation of molecules is predominant. In the geometry with the σ-hole bonding, the interaction is somewhat weaker (ΔECCSD(T)/CBS = -2.13 kcal mol-1). NCI analysis showed that Se⋯Se interaction in the most stable geometries is further enhanced by hydrogen bonding of Se-H⋯Se or C-H⋯Se type. The results of energy decomposition analysis (SAPT) calculations revealed that the nature of the Se⋯Se interaction is predominantly dispersive with a strong electrostatic contribution. The results of the energy decomposition analysis also suggest that the electrostatic component has a crucial role in defining the geometry of selenium-selenium interactions due to their directional nature.",
publisher = "Royal Society of Chemistry",
journal = "CrystEngComm",
title = "Geometrical and energetic characteristics of Se⋯Se interactions in crystal structures of organoselenium molecules",
volume = "23",
number = "18",
pages = "3383-3390",
doi = "10.1039/d1ce00129a"
}

Veljković, I. S., Kretić, D. S.,& Veljković, D.. (2021). Geometrical and energetic characteristics of Se⋯Se interactions in crystal structures of organoselenium molecules. in CrystEngComm
Royal Society  of Chemistry., 23(18), 3383-3390.
https://doi.org/10.1039/d1ce00129a

Veljković IS, Kretić DS, Veljković D. Geometrical and energetic characteristics of Se⋯Se interactions in crystal structures of organoselenium molecules. in CrystEngComm. 2021;23(18):3383-3390.
doi:10.1039/d1ce00129a .

Veljković, Ivana S., Kretić, Danijela S., Veljković, Dušan, "Geometrical and energetic characteristics of Se⋯Se interactions in crystal structures of organoselenium molecules" in CrystEngComm, 23, no. 18 (2021):3383-3390,
https://doi.org/10.1039/d1ce00129a . .