Porphyrin and BODIPY Derived Donor-Acceptor Multi-Modular Systems: Synthesis, and Excited State Energy and Electron Transfer Studies

Benitz, Alejandro Daniel

05 1900

This dissertation demonstrates that it is possible to create a donor-acceptor system that can transform sunlight into electrons. By using site-directed synthesis, it was possible to create a novel trans-A2B2 porphyrin. In the pursuit of creating a supramolecular system, both the novel (TPA-BT)2ZnP and C60imidazole combined in solution such that the nitrogenous lone pair of C60 imidazole would coordinate axially to the zinc atom in the porphyrin. The conjugates' characterization utilized spectral, electrochemical, and computational techniques. Computational studies revealed in the optimized structure that the HOMO localized on the porphyrin and LUMO centered over the C60imidazole entity. Rehm-Weller calculations showed feasibility of singlet-electron transfer. Femtosecond transient absorption studies documented an efficient photoinduced charge separation in the conjugate. The subsequent work through steady-state and time-resolved transient absorption techniques that photoinduced electron transfer takes place between the synthesized phenylimidazole functionalized bisstyrylBODIPY (BDP(Im)2) and three selected zinc tetrapyrroles. This dyad consisted of BDP(Im)2 and either zinc tetratolylporphyrin (ZnP), zinc-tetra-t-butyl phthalocyanine (ZnPc), or zinc tetra-t-butyl naphthalocyanine (ZnNc) in a solution solvated by σ-dichlorobenzene (DCB). The three dyads (BDP(Im)2:ZnP, BDP(Im)2:ZnPc, and BDP(Im)2:ZnNc) were investigated by spectroscopic, computational, and electrochemical methods. The 1:1 complex of the dyads in optical absorption studies were approximately ~104 M-1 suggesting moderately stable binding. Spectral and electrochemical studies of the dyads used to generate energy level diagrams indicated that PET was thermodynamically unfavorable in BDP(Im)2:ZnP but favorable when the zinc tetrapyrrole is selectively excited dyads—as confirmed in femtosecond transient absorption studies. In the third work, two novel tetrads, consisting of charge stabilizing triphenylamine (TPA) to either bithiophene (BT) or terthiophene (TT) via a covalent linker that is attached to the meso-position of a BODIPY. This BODIPY was further extended by linking it to fulleropyrrolidine via a catechol linker to a modified BODIPY. Computational studies revealed the electronic structures of the tetrads, which rendered the HOMO to be on TPA-BT/TPA-TT moiety, while the HOMO-1 to be on the BODIPY entity and the LUMO to localized to the fulleropyrrolidine. Coupling the results with the electrochemistry, deduced that there is the formation of (TPA-TT).+-BODIPY-C60.- and (TPA-BT).+-BODIPY-C60.- as charge-separated states after the selective excitation of BODIPY in the tetrads. Femtosecond transient absorption studies were conducted in non-polar toluene and polar benzonitrile, and results affirmed photoinduced charge separation in the tetrads.

PORPHYRIN

BODIPY

SYNTHESIS

EXCITED STATE ENERGY STUDIES

ELECTRON TRANSFER STUDIES