Exploring the electron donor-acceptor duality of B3N3 in noncovalent interactions

Rahul Shukla; Anik Sen

doi:10.1039/d3cp02656f

Exploring the electron donor-acceptor duality of B₃N₃ in noncovalent interactions

Rahul Shukla
, Anik Sen

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

3 Scopus citations

Abstract

Boron nitrides are very important and are used as lubricants, insulating agents, etc. Interactions of such systems with small molecules are important. This study examined the potential of B₃N₃ (triboron trinitride) to act as both an electron acceptor and an electron donor in the formation of noncovalent interactions. The anisotropic electronic distribution observed in the electrostatic potential map supported the B₃N₃'s ability to exhibit the predicted electron donor-acceptor duality. Further computational investigations on optimized gas-phase complexes of B₃N₃:(NH₃)_n=1-3, B₃N₃:(NCH)_n=1-6, B₃N₃:(N₂H₂)_n=1-3 and (B₃N₃)₂ confirmed that the B₃N₃ molecule can participate in B⋯N triel bonding interactions and H···N hydrogen bonding interactions. These energetically stable complexes are primarily governed by electrostatic and polarization interactions.

Original language	English
Pages (from-to)	32040-32050
Number of pages	11
Journal	Physical Chemistry Chemical Physics
Volume	25
Issue number	46
DOIs	https://doi.org/10.1039/d3cp02656f
State	Published - 9 Nov 2023
Externally published	Yes

ASJC Scopus subject areas

General Physics and Astronomy
Physical and Theoretical Chemistry

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10.1039/d3cp02656f

Cite this

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title = "Exploring the electron donor-acceptor duality of B3N3 in noncovalent interactions",

abstract = "Boron nitrides are very important and are used as lubricants, insulating agents, etc. Interactions of such systems with small molecules are important. This study examined the potential of B3N3 (triboron trinitride) to act as both an electron acceptor and an electron donor in the formation of noncovalent interactions. The anisotropic electronic distribution observed in the electrostatic potential map supported the B3N3's ability to exhibit the predicted electron donor-acceptor duality. Further computational investigations on optimized gas-phase complexes of B3N3:(NH3)n=1-3, B3N3:(NCH)n=1-6, B3N3:(N2H2)n=1-3 and (B3N3)2 confirmed that the B3N3 molecule can participate in B⋯N triel bonding interactions and H···N hydrogen bonding interactions. These energetically stable complexes are primarily governed by electrostatic and polarization interactions.",

author = "Rahul Shukla and Anik Sen",

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T1 - Exploring the electron donor-acceptor duality of B3N3 in noncovalent interactions

AU - Shukla, Rahul

AU - Sen, Anik

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N2 - Boron nitrides are very important and are used as lubricants, insulating agents, etc. Interactions of such systems with small molecules are important. This study examined the potential of B3N3 (triboron trinitride) to act as both an electron acceptor and an electron donor in the formation of noncovalent interactions. The anisotropic electronic distribution observed in the electrostatic potential map supported the B3N3's ability to exhibit the predicted electron donor-acceptor duality. Further computational investigations on optimized gas-phase complexes of B3N3:(NH3)n=1-3, B3N3:(NCH)n=1-6, B3N3:(N2H2)n=1-3 and (B3N3)2 confirmed that the B3N3 molecule can participate in B⋯N triel bonding interactions and H···N hydrogen bonding interactions. These energetically stable complexes are primarily governed by electrostatic and polarization interactions.

AB - Boron nitrides are very important and are used as lubricants, insulating agents, etc. Interactions of such systems with small molecules are important. This study examined the potential of B3N3 (triboron trinitride) to act as both an electron acceptor and an electron donor in the formation of noncovalent interactions. The anisotropic electronic distribution observed in the electrostatic potential map supported the B3N3's ability to exhibit the predicted electron donor-acceptor duality. Further computational investigations on optimized gas-phase complexes of B3N3:(NH3)n=1-3, B3N3:(NCH)n=1-6, B3N3:(N2H2)n=1-3 and (B3N3)2 confirmed that the B3N3 molecule can participate in B⋯N triel bonding interactions and H···N hydrogen bonding interactions. These energetically stable complexes are primarily governed by electrostatic and polarization interactions.

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JO - Physical Chemistry Chemical Physics

JF - Physical Chemistry Chemical Physics

IS - 46

ER -

Exploring the electron donor-acceptor duality of B₃N₃ in noncovalent interactions

Abstract

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