Molecular electronics investigation: a first principles study

The possible end of the road for Silicon has motivated academic researchers and research laboratories to search for new technologies to be applied in the electronic industry. The molecular electronics, which studies the possibility of using molecules as active elements in a new generation of electronic devices, is among these new technologies. In this Thesis, we performed first principles calculations within the density functional theory (DFT) framework to determine the structural, electronic and transport properties of systems with strong application on molecular electronics. We analised the benzene-1,4-dithiol (BDT). For this prototypical system we coupled its adsorption on an Au(111) surface with its transport properties. After this, we investigated its structural evolution between gold leads and the effects of adsorded gold atoms on the Au(111) surface in the trasmitance. The effect of the self-interaction correction (SIC) in the transport calculations of the molecular junction (Au/BDT/Au) was discussed as well. Moreover, we determined the electronic and the structural properties of the molecule y[(tpySH)2]x, where y stands for the transition metals Co, Fe and Ni and; x is associated with the charge states 0, +, 2+ e 3+. We verified that the transition metals are more stable at the low spin configuration. Depending on the charge state a Jahn-Teller distortion leads to a local symmetry reduction: D2d to C2v. Finally, with a spintronic application in mind, we analised the effect of a Cobalt impurity on the structural evolution and transmitance of a gold nanowire. (AU)