2014
DOI: 10.4067/s0717-97072014000100019
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Impact of Global and Local Reactivity Descriptors on the Hetero-Diels-Alder Reaction of Enaminothione With Various Electrophiles

Abstract: The mechanism of the Diels-Alder reaction of 1-(2-furyl)-3-(dimethylamino)-2-propene-1-thione with various dienophiles resulting in the formation of 2H-thiopyran derivatives were discussed by evaluating global and local electrophilicity and nucleophilicity descriptors for whole series of diene and dienophiles at B3LYP/6-31G* level of theory. The results preluded that the polarity and charge transfer flow between diene and dienophiles was consistent with the global reactivity descriptors and substitutional patt… Show more

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Cited by 10 publications
(6 citation statements)
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“…The chemical potential (μ), chemical hardness (η), and global softness (S) of a molecule are calculated using Koopman's theorem (Eq. (5), (6), (7)) (Table 7): [49] μ=-12(EHOMO+EnormalLnormalUnormalMnormalO) $\vcenter{\openup.5em\halign{$\displaystyle{#}$\cr \mu =-{{1}\over{2}}\ ({{\rm E}}_{HOMO}+{{\rm E}}_{{\rm L}{\rm U}{\rm M}{\rm O}})\ \hfill\cr}}$ η=12(ELUMO-EnormalHnormalOnormalMnormalO) $\vcenter{\openup.5em\halign{$\displaystyle{#}$\cr \eta ={{1}\over{2}}\ ({{\rm E}}_{LUMO}-{{\rm E}}_{{\rm H}{\rm O}{\rm M}{\rm O}})\ \hfill\cr}}$ S=1η $\vcenter{\openup.5em\halign{$\displaystyle{#}$\cr S={{1}\over{{\rm \eta }}}\ \hfill\cr}}$ …”
Section: Resultsmentioning
confidence: 99%
See 1 more Smart Citation
“…The chemical potential (μ), chemical hardness (η), and global softness (S) of a molecule are calculated using Koopman's theorem (Eq. (5), (6), (7)) (Table 7): [49] μ=-12(EHOMO+EnormalLnormalUnormalMnormalO) $\vcenter{\openup.5em\halign{$\displaystyle{#}$\cr \mu =-{{1}\over{2}}\ ({{\rm E}}_{HOMO}+{{\rm E}}_{{\rm L}{\rm U}{\rm M}{\rm O}})\ \hfill\cr}}$ η=12(ELUMO-EnormalHnormalOnormalMnormalO) $\vcenter{\openup.5em\halign{$\displaystyle{#}$\cr \eta ={{1}\over{2}}\ ({{\rm E}}_{LUMO}-{{\rm E}}_{{\rm H}{\rm O}{\rm M}{\rm O}})\ \hfill\cr}}$ S=1η $\vcenter{\openup.5em\halign{$\displaystyle{#}$\cr S={{1}\over{{\rm \eta }}}\ \hfill\cr}}$ …”
Section: Resultsmentioning
confidence: 99%
“…where, μ = chemical potential; η = chemical hardness The chemical potential (μ), chemical hardness (η), and global softness (S) of a molecule are calculated using Koopman's theorem (Eq. ( 5), ( 6), ( 7)) (Table 7): [49]…”
Section: Computational Studiesmentioning
confidence: 99%
“…The highest value appeared with the VO-CTZ complex (5.03 eV), followed by VO-SCZ and VO-CBZ, which reveal their biological potency. The ∆N max is an expression of the maximum charge an electrophile may accept from the environment [44]. We could arrange the metal complexes depending on this value in descending order, VO-CTZ > VO-LOR > VO-SCZ > VO-CBZ, which represents the capacity of VO-CTZ to be an anticancer agent.…”
Section: Global Reactivity Descriptorsmentioning
confidence: 99%
“…, 37 Finally, the global electrophilicity index (ω) gives a measure of the stabilization energy involved in a process during which a molecule acquires an additional electronic charge from its environment. 38 It is interesting to note that a correlation has been established between the electrophilic index and the toxicity 39 and that the organic compounds with the highest electrophilicity indices would be the most toxic. Moreover, it has been stated that the global electrophilicity index provides information about the electrophilic or nucleophilic nature of a medicinal compound.…”
Section: Effect Of Substituents On the Global Reactivity Parametersmentioning
confidence: 99%