Your search keyword '"Samuel Eshorame Sanni"' showing total 2 results

1. Technological advancements in the use of ionic liquid- membrane systems for CO2 capture from biogas/flue gas - A review

Author

Samuel Eshorame Sanni, Denen Ashiekaa Vershima, Emeka Emmanuel Okoro, and Babalola Aisosa Oni

Subjects

Adsorption, Biogas, Biomass, Carbon capture, Membrane-ionic liquid system, Post-combustion, Science (General), Q1-390, Social sciences (General), H1-99

Abstract

Carbon capture has become a very important method for curbing the problems associated with the release of carbon dioxide into the atmosphere, which in turn has detrimental effects on the planet and its inhabitants. Ionic liquids and membrane separation have been explored in this review paper as effective means of capturing carbon dioxide. An innovative approach to CO2 capture is the use of Ionic liquids (ILs) since they exhibit certain significant traits such as good stability (thermal, mechanical and chemical), inflammability and high absorptive capacities. Ionic liquids (ILs) are widely regarded as nontoxic substances. Viscosity and thermal degradation of ILs at temperatures slightly above 100 °C are the major disadvantages of ILs. Membrane separation is a technique used for the effective separation of substances by materials bearing holes in a continuous structure. Membrane technology has gained significant improvements, over the years. Several ILs and membrane systems were considered in this work. Their weaknesses, strengths, permeability, selectivity, operating conditions and carbon capture efficiencies, were all highlighted in order to gain a good perspective on ways by which the individual systems can be improved upon. The study considered several polymer-Ionic liquid hybrid materials as viable options for CO2 capture from a post-combustion process. Different ILs were scrutinized for possible integration in membranes by taking full advantage of their individual properties and harnessing their tune-able characteristics in order to improve the overall carbon capture performance of the system. Several options for improving the mechanical, chemical, and thermal stabilities of the hybrid systems were considered including the use of cellulose acetate membrane, nanoparticles (graphene oxide powder) alongside potential ionic liquids. Doping membranes with ILs and nanoparticulates such as graphene oxide serves as a potential method for enhancing the CO2 capture of membranes and this review provides several evidences that serve as proofs for this concept.

Published

2022

2. Development of an automated drilling fluid selection tool using integral geometric parameters for effective drilling operations

Author

Samuel Eshorame Sanni, Adewale Dosunmu, Adedotun O. Alaba, Emeka Emmanuel Okoro, and Evelyn Bose Ekeinde

Subjects

0301 basic medicine, Multidisciplinary, Energy, Petroleum engineering, Drilling, Highly selective, Process automation system, Article, Wellbore, 03 medical and health sciences, 030104 developmental biology, 0302 clinical medicine, Range (aeronautics), Drilling fluid, lcsh:H1-99, lcsh:Social sciences (General), Reduction (mathematics), lcsh:Science (General), 030217 neurology & neurosurgery, Selection (genetic algorithm), Geology, lcsh:Q1-390

Abstract

Modern-day climate and environmental factors are largely responsible for the different geometric characteristics exhibited by formation zones/petroleum reservoirs which makes them highly selective with respect to their adaptation to drilling fluids. However, recent advances in drilling technology, such as, the development of an appropriate drilling fluid automation system carried out in this study, have shown prospects for tremendous improvements in well performance with a subsequent reduction in well dormancy/shutdown. Based on the mud density calculations from the simulation and field measurements, it is evident that the novel drilling fluid selector system has a characteristic algorithm that is suitable for predicting the performance of drilling fluids within limits of accuracy as high as 95–99% for wellbore sizes/diameters and depth, in the range of 8–16" and 0–15,760 ft which is a good step towards attaining a fully automated drilling operation.

Published

2019