DFT and canonical ensemble investigations on the thermodynamic properties of Syngas and natural gas/Syngas mixtures

Density Functional Theory and canonical ensemble were used to investigate thermodynamic properties of Syngas and its mixture with natural gas. The following thermodynamic potentials were obtained: internal energy, enthalpy, entropy and Gibbs free energy for temperatures ranging from 0.5 K to 1500 K....

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Bibliographic Details
Published in:Renewable energy 2019-01, Vol.130, p.495-509
Main Authors: Neto, Abel F.G., Marques, Francisco C., Amador, Adriana T., Ferreira, Amanda D.S., Neto, Antonio M.J.C.
Format: Article
Language:English
Subjects:
DFT
Natural gas
Natural gas combustion
Syngas
Temperature effect
Thermodynamics
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Summary:Density Functional Theory and canonical ensemble were used to investigate thermodynamic properties of Syngas and its mixture with natural gas. The following thermodynamic potentials were obtained: internal energy, enthalpy, entropy and Gibbs free energy for temperatures ranging from 0.5 K to 1500 K. It was observed that CO and H2 were the most stable Syngas components, possessing the ability to render Syngas less favorable to the temperature increase. Also, we verified that Syngas presents properties similar to an antiknock agent for natural gas, raising its resistance to temperature increases. Were determined the Poisson coefficients and Bulk modulus for Natural gas/Syngas mixtures and Shomate equation coefficients for some Syngas types, providing a more complete thermodynamic description for these gases. Additionally, thermodynamic potentials of combustion for Natural gas/Syngas mixtures were predicted, showing that this biofuel can reduce the calorific power of natural gas and makes its combustion less favorable due its antiknock behavior. However, a mixture with 30% of Syngas may be useful for natural gas combustion, since it present a calorific power between 73.41% and 79.49% of that of natural gas, which is a substantial fraction of energy released during combustion, showing good future prospects to the Natural gas/Syngas mixture to the renewable energy generation. [Display omitted] •A Natural gas/Syngas mixture shows good prospects for renewable energy generation.•Syngas can act as antiknock agent of Natural gas, rising its thermal stability.•A good proportion for the Natural gas/Syngas mixture is presented.•Thermodynamic potentials for several Natural gas/Syngas mixtures were determined.•The CO and H2 fractions are proportional to the thermal stability of Syngas.
ISSN:0960-1481
1879-0682
DOI:10.1016/j.renene.2018.06.091