NiO, Fe2O3, and MoO3 Supported over SiO2 Nanocatalysts for Asphaltene Adsorption and Catalytic Decomposition: Optimization through a Simplex–Centroid Mixture Design of Experiments

Daniela Arias-Madrid,Farid B Cortés,Jaime Gallego,Oscar E Medina,Sócrates Acevedo,Alexander A Correa-Espinal,Camilo A Franco

doi:10.3390/catal10050569

Abstract

The main objective of this study was to evaluate the effect of functionalized silica nanoparticles with Fe2O3, NiO, and MoO3 metal oxides on the decomposition of asphaltenes, through an experimental simplex–centroid mixture design for surface area, asphaltene adsorption, and activation energy. The experimental nanoparticle surface area was measured by adsorption of N2. Adsorption isotherms, and the subsequent oxidation process of asphaltenes, were performed through batch adsorption experiments and thermogravimetric analysis, respectively. Among the monometallic systems, the presence of iron increased the affinity between the nanoparticle and the asphaltenes, and a higher metal oxide load increased the adsorptive capacity of the system. For the pairings evaluated, there was better synergy between iron and nickel, with the participation of the former being slightly superior. In the mixture design that included three transition elements, the participation of molybdenum was not significant, and the adsorption of asphaltenes was dominated by the active sites formed by the other two transition element oxides. The mixture design created to minimize the activation energy showed that the interaction of the three transition elements is important and can be evidenced in the interaction coefficients.

Highlights

The oil industry has a significant challenge in the extraction and production of heavy (HO)and extra heavy crude oil (EHO), due to the presence of heavy components [1]
The setting for the prediction of surface area as a response variable for nanoparticles functionalized with designs including two and three transition elements was achieved with less than 6% error, providing reliable surface area values of each nanoparticle, using specific parameters, thereby reducing operational costs
Being able to predict the values of the surface area with a potential error of only 6%

Summary

Introduction

The oil industry has a significant challenge in the extraction and production of heavy (HO)and extra heavy crude oil (EHO), due to the presence of heavy components [1]. Catalysts 2020, 10, 569 and growth of asphaltenes, and the subsequent formation of colloidal nanoaggregates, increasing crude oil viscosity [5]. The presence of asphaltenes in crude oils causes many problems in transportation, production, and oil-recovery operations, increasing the economic costs and environmental impacts [3,6]. Reducing the asphaltene content helps to improve the quality of HO and EHO and contributes to environmental stewardship [7]. Nanotechnology has taken a significant role as an alternative for the management of asphaltenes and heavy crude oil recovery [8,9]. Nanoparticles can be used as adsorbents and catalysts in the process of removal and transformation of asphaltenes and oil recovery [10]

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Conclusion