Systematically varying the optical gap that is associated with charge-transfer excitations is an important step in the design of light-harvesting molecules. So far the guidance that time-dependent density functional theory could give in this process was limited by the traditional functionals’ inability to describe charge-transfer excitations. We show that a nonempirical range-separated hybrid approach allows to reliably predict charge-transfer excitations for molecules of practically relevant complexity. Calculated absorption energies agree with measured ones. We predict from theory that by varying the number of thiophenes in donor-acceptor-donor molecules, the energy of the lowest optical absorption can be tuned to the lower end of the visible spectrum. Saturation sets in at about five thiophene rings.
The drive to develop new organic materials for use in optoelectronic devices has created the need to understand the fundamental role functionalization plays concerning the electronic properties of conjugated molecules. Here density functional theory (DFT) is used to investigate how the HOMO-LUMO gaps of halogenobenzenes are affected as a function of substituent size, position, electronegativity, ionization potential, and polarizability. A detailed molecular orbital analysis is also provided. It is shown that the molecular static polarizability and ionization potential of the bound halogens are the primary physical descriptors governing the HOMO-LUMO gap within halogenobenzenes. Two secondary descriptors controlling the HOMO-LUMO gap in these materials are the aromaticity of the halogen substituted benzene rings (as monitored via the harmonic oscillator method of aromaticity index [HOMA]) and the reduced population of the halogen atomic orbitals in the frontier MOs (%X or %X). The molecular polarizability and aromaticity, as well as %X and %X, are shown to be a function of halogen electronegativity and size, as well as number and position on the ring. It is ultimately demonstrated that halogenobenzenes which are most polarizable and are either least aromatic and/or exhibit the smallest %X (or largest %X) values, have the smallest HOMO-LUMO gaps.
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