Study of organic transistors by nonlinear vibrational spectroscopy and charge modulation microscopy

This Thesis deals with the study of Organic Field Effect Transistors (OFETs). Understanding the behavior of the accumulated charge along the OFET channel, which is responsible for the electrical conduction process in the device, is of great importance for improving its efficiency or proposing a theoretical model that describes the behavior of the transistor in all its operating regimes. Several studies in the literature investigate the electric field in the semiconductor layer of the transistor (along the channel) generated by the charge accumulation, but none investigates the field in the OFET dielectric layer, which is directly proportional to the charge accumulated in the channel. The electric field in the dielectric layer of the device was initially investigated by Sum-Frequency Generation (SFG) vibrational spectroscopy. SFG spectra obtained in the polarized devices exhibited a band at ~ 1720 cm-1, due to the carbonyl group of the organic dielectric layer (PMMA - poly (methyl methacrylate)), whose amplitude was proportional to the applied gate voltage, indicating that these polar groups were oriented by the intense electric field in the device. This field-induced SFG signal may be due to two contributions, a second order non-linear term (due to molecular reorientation) and a third order term (interaction between the optical fields and the static field in the material volume). We observed an almost complete reduction of the SFG signal at high temperatures (close to the Tg of the dielectric polymer), indicating that the molecular reorientation mechanism is responsible for the generated SFG signal. Preliminary SFG microscopy measurements were performed to map this SFG signal along the channel of OFET fabricated with N2200 (semiconductor) and PMMA (dielectric) polymers. The results demonstrate the variation of the accumulated charge density along the channel when the device is polarized and close to saturation. Using Charge Modulation Microscopy (CMM), which is another noninvasive method to investigate the accumulation of charges in an operating device, we mapped the charge distribution in the channel of these OFETs with high spatial resolution (sub-micrometer). In addition, a simulation of the expected charge density and CMM profiles was performed using an ambipolar model for OFETs. Based on these simulations, we proposed a square-wave modulation of the OFET, which allows a more direct comparison of the CMM profiles with the charge density profile. Using the proposed scheme, these profiles along the transistor channel were measured and compared with those expected from the ambipolar model. In general, the obtained charge density profiles agree well with the model, using only a single global adjustable parameter, except very close to the drain electrode and in the deep saturation regime, when the experiments have an artifact due to the electro-absorption and do not allow a precise comparison with the model. Therefore, it is expected that this Thesis has contributed to the advancement of techniques to characterize the charge distribution in OFETs, and thus improve the understanding of its operating mechanisms. Keywords: Field-effect transistors. Organic electronics. Nonlinear optics. Sum-frequency generation. Polarization of dielectrics. Charge modulation microscopy. Metal-insulator-semiconductor capacitor. (AU)