THEORETICAL AND EXPERIMENTAL STUDY OF ELECTRICAL AND ELECTROCHEMICAL PROPERTIES OF (E)-3-(4, 5-DIHYDROXY-2-(PHENYLSULPHONYL) PHENYL) ACRYLIC ACID AS A NEW CAFFEIC ACID DERIVATIVE
Abstract
The electrode potentials of (E)-3-(4,5-dihydroxy-2-(phenylsulphonyl) phenyl) acrylic acid (DPA), as a new caffeic acid derivative, in aqueous solution have been calculated. DPA has two geometric structures, cis and trans. Since the cis structure of caffeic is unstable, it cannot be found in nature, but in this research, its electrode potential have been calculated theoretically. The calculations have been performed using ab initio molecular orbital calculations (HF), and density functional theory (DFT) with the inclusion of entropic and thermochemical corrections to yield free energies of redox reactions. The electrode potential was also obtained experimentally by means of an electrochemical technique (cyclic voltammetry) and it was 335 mV for trans structure. The theoretical and experimental values for the electrode potential of the studied molecule are in excellent agreement. Geometric parameters and vibrational frequencies values of DPA and (2E)-3-(3,4-dioxo-6-(phenylsulfonyl) cyclohexa-1,5-dienyl)acrylic acid (DPDA is the oxidized form of DPA), were computed using same methods. The calculated IR spectrum of DPA used for the assignment of IR frequencies was observed in the experimental FT-IR spectrum. Correlations between theoretical and experimental vibrational frequencies of DPA molecule were 0.996. The agreement mutually verifies the accuracy of the experimental method and the validity of the applied mathematical model.
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