Linear Extension of Carbaporphyrin Chromophores: Synthesis, Protonation, and Metalation of Anthro[2,3-b]carbaporphyrins: Evidence for 30π-Electron Aromatic Circuits in a Palladium(II) Complex

Iso-dibenzo[g,p]chrysene-Fused Bis-dicarbaporphyrin: Pd Coordination-Induced Global Aromaticity and Stabilization of Double In-Plane Pd(IV) Cations

An iso-dibenzo[g,p]chrysene (DBC)-fused bis-dicarbaporphyrin (4) with two adj-CCNN cores was synthesized. This bis-dicarbaporphyrin can be regarded as an isomer of the previously reported DBC-fused bis-dicarbacorrole obtained by tuning the orientation of the DBC bridge. This subtle change has significant impacts on structure and properties. As prepared, 4 has a highly twisted figure-eight conformation, whereas DBC-fused bis-dicarbacorrole adopts roughly a planar conformation with slight distortion. The incorporation of two Pd(II) cations can induce a transformation in the molecular framework, resulting in a curved, arch-shaped π-system. Utilizing crystallographic data, along with the electron density of delocalized bonds (EDDB), electron localization function-π (ELF-π), harmonic oscillator model of aromaticity (HOMA), the anisotropy of the induced current density (ACID), and nucleus-independent chemical shift (NICS) calculations, a 34π-electron global aromatic pathway was elucidated for the bis-Pd(II) complex (5). The Pd coordination-induced global aromaticity is a distinctive feature that has not been observed in the previously reported bis-Pd complexes of DBC-fused bis-dicarbacorrole. Moreover, the treatment of 5 with CuCl2 leads to the formation of a rare in-plane bis-Pd(IV) complex 6 with two axial coordinated Cl anions. The bis-Pd(IV) complex retains the global aromatic feature and arch-shaped conformation. To our knowledge, this is the first well-defined in-plane bis-Pd(IV) organometallic complex using a porphyrinoid-type macrocyclic ligand.

Assessment of Conjugation Pathways in N-Methylporphyrins that Are Fused to Acenaphthylene, Phenanthrene, or Pyrene: Evidence for the Presence of Alternative Aromatic Circuits

Acenaphtho-, phenanthro-, and pyrenopyrrole esters, readily available from Barton-Zard reactions of ethyl isocyanoacetate with nitroarenes, were reacted with methyl iodide and KOH in DMSO to give N-methylpyrroles and subsequent cleavage of the ester moieties was accomplished with KOH in ethylene glycol at 200 °C. Condensation with two equiv of an acetoxymethylpyrrole in refluxing acetic acid-2-propanol afforded a series of annulated tripyrranes. Cleavage of the terminal tert-butyl ester groups with trifluoroacetic acid, followed by condensation with a diformylpyrrole and oxidation with FeCl3, gave N-methyl acenaphtho-, phenanthro-, and pyrenoporphyrins. The N-methyl substituent effectively freezes the tautomeric equilibria to maximize interactions between the porphyrin nucleus and the fused aromatic substructures. Analysis of the proton NMR spectra provides evidence of the presence of extended aromatic circuits within these structures. Anisotropy of induced ring current (AICD) plots clearly shows the presence of 30π electron pathways in phenanthro- and pyrenoporphyrins that run around the exterior of the benzenoid fragments. These results demonstrate that N-alkylation can be used to relocate aromatic pathways in porphyrinoid systems.

Effects of Electron-Withdrawing and Electron-Donating Groups on Aromaticity in Cyclic Conjugated Polyenes

Determining the aromaticity of various fluorinated benzenes is challenging as easily obtained experimental aromaticity [Δδ(Houter - Hinner)] necessitates the chemical shifts of inner and outer protons. This issue was addressed in porphyrinoids by replacing the electron-withdrawing (E.W.) groups at the meso-positions of porphyrins and allyliporphyrins. Electronic effects on aromaticity in porphyrinoids have not been thoroughly examined in the literature. In porphyrins, the effect of E.W. groups is minimal, making it difficult to establish a clear relationship between the aromaticity strength and E.W. groups. Conversely, in allyliporphyrins, stronger E.W. groups, such as indandione (IND) derivatives, significantly reduce the aromaticity of the parent structure. The IND derivatives disrupted the aromatic pathway of allyliporphyrin more effectively than those attached to porphyrins. This is attributed to the absence of β-carbons in allyliporphyrins. The effect of electron-donating (E.D.) groups on porphyrins and allyliporphyrins was further investigated. Contrary to the initial assumption that the E.D. groups might enhance aromaticity owing to their ability to increase electron density, as the strength of the E.D. groups increased, the aromaticity of the porphyrinoids decreased. Despite the modest reduction in aromaticity, any form of electron perturbation reduces aromaticity. The aromaticity of various fluorinated benzenes is expected to parallel our observations of porphyrinoids as representative aromatic polyenes.