Title :
Effect of dipolar arrays on the localization of charge carriers in molecular materials
Author_Institution :
Inst. of Phys. & Theor. Chem., Tech. Univ. Wroclaw, Poland
fDate :
8/1/2000 12:00:00 AM
Abstract :
The paper presents results of calculations of the depth and distribution of local states for charge carriers created by polar impurities in a model molecular material. Equations resulting from the electrostatic model due to Lyons have been employed in the calculations. The presence of polar species in a non-polar molecular material locally modifies the polarization energy, thus creating local states (traps) on neighboring molecules. Calculations performed for an isolated dipolar defect show that traps as deep as ~0.4 eV to ~0.5 eV can result in such a way, their depths and cross-sections depending on the dipole moment of the guest molecule. Results of similar calculations carried out for arrays of spatially connected dipoles indicate that local states of a considerable density may be created, modifying the density-of-states function, and hence influencing the effective mobility of charge carriers
Keywords :
carrier mobility; defect states; electron traps; electronic density of states; hole traps; impurity states; organic compounds; density-of-states function; dipolar arrays; dipole moment; effective mobility; electrostatic model; guest molecule; isolated dipolar defect; local states; localization of charge carriers; molecular materials; polar impurities; polarization energy; spatially connected dipoles; Charge carriers; Chemicals; Crystalline materials; Crystals; Electron traps; Electrostatics; Equations; Ionization; Polarization; Solids;
Journal_Title :
Dielectrics and Electrical Insulation, IEEE Transactions on
