Gas detecting and sensing is a largely studied field of knowledge, but total understanding is not yet achieved and the ideal device is still far in the future. Many experimental efforts have been devoted to find the minimum optimal temperature and operational conditions for SnO2 to sense hydrocarbons; different methods to build gas-detecting devices keep being developed all around the world, from paste-based bulk devices to nanostructured thick and thin films, but little effort has been aim to characterize the reactions by calculating their related enthalpies. Computational methods have been widely used to characterize, understand and model many physicochemical interactions. In this regard, three main courses can be followed: Ab initio (first principles of quantum mechanics), DFT (Density Functional Theory) and MD (Molecular Dynamics) simulation. In this research, DFT modelling tool is employed to understand and characterize the gas-sensing reactions of Tin Oxide when exposed to an atmosphere with Methane. In CASTEP, a robust DFT module of the Materials Studio suite, one SnO2 (110) crystal plane is exposed to CH4 and the structure is optimized many times for each possible step of the reaction, recording the energies related with each optimization stage, in sum giving us the Transition State (TS) of the reaction. Based on the data, a promising reaction-path is proposed and analyzed for the (110) surface.
The sustainable production of energy is a field of interest to which a new requirement is now imposed: the need to be respectful of the environment. New materials and techniques are being developed, but environmental concerns impose the necessity of keeping research active towards the development of green energy. For this reason, we present the study of short polythiophene (PTh) chains (three and five monomers) and their interaction with nickel oxide, looking for properties related to solar photon harvesting in order to produce electricity. The models of the molecules were developed, and the calculations were performed with an M11-L meta-GGA functional, specially developed for electronic structure calculations. The theoretical explorations demonstrated that the geometry of the PTh molecules suffer little distortion when interacting with the NiO molecule. The calculated value of Eg lies between 2.500 and 0.412 eV for a three-ring PTh chain and between 1.944 and 0.556 eV for a five-ring PTh chain. The chemical parameters indicated that, depending on the geometry of the system, the chemical potential varies from 81.27 to 102.38 kcal/mol and the highest amount of electronic charge varies from −2.94 to 21.56 a.u. for three-monomer systems. For five-monomer systems, the values lie within similar ranges as those of the three-monomer systems. The Partial Density of States (PDOS) showed that the valence and conduction electronic bands were composed of states in the NiO and PTh rings, except for a system where there was a non-bonding interaction.
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