Repozytorium
Wyszukaj
Kolekcje
Inne
How substitution combines with non-covalent interactions to modulate 1,4-naphthoquinone and its derivatives molecular features : multifactor studies.
Autorzy
Rok wydania
2021
Czasopismo
International Journal of Molecular Sciences
Numer woluminu
22
Strony
10357/1-10357/19
DOI
10.3390/ijms221910357
Kolekcja
Język
Angielski
Typ publikacji
Artykuł
Substitution is well-known to modulate the physico-chemical properties of molecules. In this study, a combined, multifactor approach was employed to determine a plethora of substitution patterns using –Br and –O-H in 1,4-naphthoquinone and its derivatives. On the basis of classical Density Functional Theory (DFT), 25 models divided into three groups were developed. The first group contains 1,4-naphthoquinone and its derivatives substituted only by –Br. The second group consists of compounds substituted by –Br and one –O-H group. As a result of the substitution, an intramolecular hydrogen bond was formed. The third group also contains –Br as a substituent, but two –O-H groups were introduced and two intramolecular hydrogen bonds were established. The simulations were performed at the ωB97XD/6-311++G(2d,2p) level of theory. The presence of substituents influenced the electronic structure of the parent compound and its derivatives by inductive effects, but it also affected the geometry of the 2 and 3 groups, due to the intramolecular hydrogen bonding and the formation of a quasi-ring/rings. The static DFT models were applied to investigate the aromaticity changes in the fused rings based on the Harmonic Oscillator Model of Aromaticity (HOMA). The OH stretching was detected for the compounds from groups 2 and 3 and further used to find correlations with energetic parameters. The evolution of the electronic structure was analyzed using Hirshfeld atomic charges and the Substituent Active Region (cSAR) parameter. The proton reaction path was investigated to provide information on the modulation of hydrogen bridge properties by diverse substitution positions on the donor and acceptor sides. Subsequently, Car–Parrinello Molecular Dynamics (CPMD) was carried out in the double-bridged systems (group 3) to assess the cooperative effects in double –O-H-substituted systems. It was determined that the –O-H influence on the core of the molecule is more significant than that of –Br, but the latter has a major impact on the bridge dynamics. The competitive or synergic effect of two –Br substituents was found to depend on the coupling between the intramolecular hydrogen bridges. Thus, the novel mechanism of a secondary (cooperative) substituent effect was established in the double-bridged systems via DFT and CPMD results comparison, consisting of a mediation of the bromine substitutions’ influence by the cooperative proton transfer events in the hydrogen bridges.
Słowa kluczowe
1,4-naphthoquinone derivatives, substituent effect, DFT, HOMA, Hirshfeld atomic charges, cSAR, CPMD
Licencja otwartego dostępu
Licencja na prawach której można swobodnie kopiować, rozprowadzać, zmieniać i remiksować objęty prawem autorskim utwór (Utwór-przedmiot prawa autorskiego) pod warunkiem podania imienia i nazwiska autora utworu pierwotnego oraz źródła pochodzenia utworu.
Pełny tekst licencji: https://creativecommons.org/licenses/by/3.0/pl/legalcode
Adres publiczny
http://doi.org/10.3390/ijms221910357
Strona internetowa wydawcy
Podobne publikacje
Structure-property relationship in selected naphtho- and anthra-quinone derivatives on the basis of density functional theory and Car–Parrinello molecular dynamics.
Kizior Beata, Panek Jarosław J., Szyja Bartłomiej M., Jezierska Aneta
Proton Changes the Rules of the Game: Insight into the Nature of "Proton Sponges"
Kizior Beata, Szatyłowicz Halina, Krygowski Tadeusz M., Panek Jarosław J., Zierkiewicz Wiktor, Jezierska Aneta
Association and solubility of chlorophenols in CCl4: MIR/NIR spectroscopic and DFT study
Singh Swapnil, Ozaki Yukihiro, Czarnecki Mirosław Antoni
