Density functional theory (DFT) calculations on the structures and stabilities of [C_nO_2n+1]^2– and [C_nO_2n+1]X₂ polycarbonates containing chainlike (CO₂)_n units (n = 2–6; X = H or Li)

Author： Bruna Pablo J. Grein Friedrich Passmore Jack

Publisher： NRC Research Press

ISSN： 1480-3291

Source： Canadian Journal of Chemistry, Vol.89, Iss.6, 2011-06, pp. : 671-687

Disclaimer: Any content in publications that violate the sovereignty, the constitution or regulations of the PRC is not accepted or approved by CNPIEC.

Previous Menu Next

Abstract

The structures and stabilities of chainlike (CO₂)_n (n = 2–6) polycarbonates, where adjacent C atoms are linked by C–O–C bonds, were investigated at the density functional theory (DFT) level (B3PW91/6–311G(2d,p)), including dicarboxylic dianions, [C_nO_2n+1]^2–, and the corresponding acids, [C_nO_2n+1]H₂, and Li salts, [C_nO_2n+1]Li₂. At equilibrium, the most stable systems have C_s, C₂, or C_2v symmetries. In the gas phase, these dianions are generally metastable with respect to spontaneous ejection of one electron, yet in the presence of counterions they become stabilized, for example, as [C_nO_2n+1]^2–(Li⁺)₂ ion pairs. [C_nO_2n+1]^2– linkages are also stabilized as dicarboxylic acids, [C_nO_2n+1]H₂; we find the latter to have equilibrium conformations of higher symmetry than previously reported in the literature. To the best of our knowledge, none of the [C_nO_2n+1]X₂ (X = Li or H) compounds with n ≥ 2 have been reported in the experimental literature (albeit, the alkyl esters C₂O₅R₂ and C₃O₇R₂ are commercially available). All CO bonds in C₂O₅X₂ to C₆O₁₃X₂ have single- to double-bond character (≍140–118 pm), indicating that the [C_nO_2n+1] moieties are held together by strong chemical forces (in contrast to the weakly bound complexes (CO₂)_n and (CO₂)_n^–, n > 1). Vibrational frequencies were calculated to ensure all conformations were true minima. The IR and Raman intensities show that the high intensity C=O stretching modes (1750 ± 100 cm^–1) will help in the spectral characterization of these compounds. Solvation calculations using the polarizable continuum model (PCM) find that C₂O₅^2– can be formed via CO₃^2– + CO₂ as well as CO₃^– + CO₂^–, each reaction having ∆G²⁹⁸ < 0 in practically all solvents. This result confirms the experimentally observed large solubility of CO₂(g) in molten carbonates, CO₃M₂ (M = Li, Na, or K). In contrast, starting with n = 2, the reactions [C_nO_2n+1]^2– + CO₂ do not proceed spontaneously in any solvent (∆G²⁹⁸ > 0).