Abstract
Pyrene (C16H10) is an organic semiconductor which has wide applications in the field of organic electronics suitable for the development of organic light emitting diodes (OLED) and organic photovoltaic cells (OPV). In this work, Density Functional Theory (DFT) using Becke’s three and Lee Yang Parr (B3LYP) functional with basis set 6-311++G(d, p) implemented in Gaussian 03 package was used to compute total energy, bond parameters, HOMO-LUMO energy gap, electron affinity, ionization potential, chemical reactivity descriptors, dipole moment, isotropic polarizability (α), anisotropy of polarizability ( Δ∝) total first order hyper-polarizability () and second order hyperpolarizability (). The molecules used are pyrene, 1-chloropyrene and 4-chloropyrene in gas phase and in five different solvents: benzene, chloroform, acetone, DMSO and water. The results obtained show that solvents and chlorination actually influenced the properties of the molecules. The isolated pyrene in acetone has the largest value of HOMO-LUMO energy gap of and is a bit closer to a previously reported experimental value of and hence is the most stable. Thus, the pyrene molecule has more kinetic stability and can be described as low reactive molecule. The calculated dipole moments are in the order of 4-chloropyrene (1.7645 D) < 1-chloropyrene (1.9663 D) in gas phase. The anisotropy of polarizability ( for pyrene and its derivatives were found to increase with increasing polarity of the solvents. In a nutshell, the molecules will be promising for organic optoelectronic devices based on their computed properties as reported by this work.
Highlights
The study of organic electronics has for a long time been viewed as an essential determinant in the field of display technology, renewable energy and flexible electronics (Shaw, 2001)
The values are in the range of isolated pyrene 4-chloropyrene 1-chloropyrene in each of the corresponding gaseous state and solvent
The higher frontier orbital gap indicates that the pyrene molecule has more kinetic stability and can be described as low reactive molecule
Summary
The study of organic electronics has for a long time been viewed as an essential determinant in the field of display technology, renewable energy and flexible electronics (Shaw, 2001). Pyrene (C16H10) is one of the simplest π-conjugated molecules which has shown electrical conductivity undergoing electrochemical doping (Facchetti, 2011). This feature, together with pyrene’s unique radiometric properties and its concentration-dependent excimer (Somerharju, 2002) gives rise to the multiple applications including luminescence-switching chemical sensing and membrane biophysics (Li, 2019). As a result of their outstanding optical and electronic properties, pyrene and mono-chlorinated pyrene derivatives have represented an important building block in optoelectronic devices, such as organic light-emitting diodes (OLEDs) (Kuroda et al, 1963), organic field effect transistors (OFETs) (Abdulaziz et al., 2019), and organic photovoltaics (OPVs). The substituent attached to the molecular framework can enhance or diminish the reactivity (Saleh, 2009)
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