Department of Petroleum & Gas

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Biodegradation of polyester polyurethane during commercial composting and analysis of associated fungal communities
(Elsevier, 2014-03-04) Petrus Nzerem
In this study the biodegradation of polyurethane (PU) during the maturation stage of a commercial composting process was investigated. PU coupons were buried in the centre and at the surface of a 10 m high compost pile. Fungal communities colonising polyester PU coupons were compared with the native compost communities using culture based and molecular techniques. Putative polyester PU degrading fungi were ubiquitous in compost and rapidly colonised the surface of polyester PU coupons with significant deterioration. As the temperature decreased, fungal diversity in the compost and on the surface of the polyester PU coupons increased and selection of fungal community on the polyester PU coupons occurs that is different from the surrounding compost.
Adsorption of Cd(II) and Pb(II) ions from aqueous solutions using mesoporous activated carbon adsorbent: Equilibrium, kinetics and characterisation studies
(Lancaster E-Prints, 2017-02-23) Asuquo, Edidiong D.; Martin, Alastair Douglas; Petrus Nzerem; Siperstein, Flor; Fan, Xiaolei
In this study, cadmium and lead ions removal from aqueous solutions using a commercial activated carbon adsorbent (CGAC) were investigated under batch conditions. The adsorbent was observed to have a coarse surface with crevices, high resistance to attrition, high surface area and pore volume with bimodal pore size distribution which indicates that the material was mesoporous. Sorption kinetics for Cd(II) and Pb(II) ions proceeded through a two-stage kinetic profile-initial quick uptake occurring within 30 min followed by a gradual removal of the two metal ions until 180 min with optimum uptake (qe,exp) of 17.23 mg g1 and 16.84 mg g1 for Cd(II) and Pb(II) ions respectively. Modelling of sorption kinetics indicates that the pseudo first order (PFO) model described the sorption of Pb(II) ion better than Cd(II), while the reverse was observed with respect to the pseudo second order (PSO) model. Intraparticle diffusion modelling showed that intraparticle diffusion may not be the only mechanism that influenced the rate of ions uptake. Isotherm modelling was carried out and the results indicated that the Langmuir and Freundlich models described the uptake of Pb(II) ion better than Cd(II) ion. A comparison of the two models indicated that the Langmuir isotherm is the better isotherm for the description of Cd(II) and Pb(II) ions sorption by the adsorbent. The maximum loading capacity (qmax) obtained from the Langmuir isotherm was 27.3 mg g1 and 20.3 mg g1 for Cd(II) and Pb(II) ions respectively.
Evaluation of Cd(II) Ion Removal from Aqueous Solution by a Low-Cost Adsorbent Prepared from White Yam (Dioscorea rotundata) Waste Using Batch Sorption
(ChemEngineering, 2018-08-03) Edidiong Asuquo; Alastair D. Martin; Petrus Nzerem
An agricultural residue, white yam (Dioscorea rotundata) tuber peel (YTBS), was used for the removal of Cd(II) ion from an aqueous solution using a batch method. The adsorbent was characterized using FTIR, TGA, SEM, EDX, N2 BET, XRD, and XRF. The optimization of sorption variables such as pH, contact time, adsorbent dose, and initial metal ion concentration at 25 °C were also carried out. The results indicated the dependence of sorption on the adsorbate pH and adsorbent dose, while the adsorption system reached equilibrium in 180 min. The sorption kinetics was fitted to three models (pseudo first order, pseudo second order, and Elovich) to validate the kinetics, and the pseudo first order was the best model for the description of Cd(II) uptake. Equilibrium isotherm modelling was also carried out using the Langmuir, Freundlich, and Temkin models, with the Langmuir isotherm giving the best fitting to the experimental results. The maximum loading capacity (qmax) of the adsorbent for Cd(II) obtained from the Langmuir isotherm model was 22.4 mg∙g−1 with an isotherm constant (KL) of 3.46 × 10−3 L·mg−1 and r2 value of 0.99. This result indicates that the YTBS residue was a good adsorbent for the removal of Cd(II) ion from aqueous system.
A Comparative Analysis of the Well Performance of Vertical, Horizontal and Multilateral Well
(Petroleum and Coal, 2019) Ameena A. Gaji; Petrus Nzerem; Oghenerume Ogolo; Ikechukwu Okafor ; Ternenge Joseph Chior
The demand for energy in the world has been ever increasing. Conventional technologies are being replaced gradually by different new technologies. Horizontal wells and multilateral wells have proved to be highly beneficial by improving production rates significantly. This study focuses on investigating the well performance of vertical well (Well V), horizontal well (Well H), and multilateral well (Well M) in the Hurricane field using PROSPER software. PVT matching, well modelling and well performance analysis was carried out. Sensitivity analysis was performed on key parameters such as tubing diameter, water cut, wellhead pressure and tubing roughness to determine their effects on well productivity. It was observed that increasing the water cut decreased the production rates of Well V, Well H and Well M by 41%, 36.1% and 33.5% respectively. An increase in the tubing diameter improved the production rates, wellhead pressure had high impacts on the well performance while tubing roughness had a minimal effect on oil production. The optimum production rates of 21,622.5 STB/day, 28,653.6 STB/day and 29,800.9 STB/day for Well V, Well H and Well M respectively were achieved at reservoir pressure of 3500 psig, wellhead pressure of 400 psig, water cut of 5% and a 5.5 inches tubing diameter.
Defining the Optimal Development Strategy to Maximize Recovery and Production Rate from an Integrated Offshore Water-Flood Project
(Society of Petroleum Engineers, 2019-07-31) Hajara Kabeer Abdulfatah; Ikechukwu Okafor; Petrus Nzerem; Khaleel Jakada
A reservoir development plan provides the necessary guidance and information for establishing whether or not a project is economically viable considering possible development project options, risks and uncertainties in order to define the most optimal development concept that will increase oil production and reduce production costs. The aim of this project was to determine the optimum way to develop and produce an offshore oil field in a manner that considers risks and uncertainties and values stakeholders’ interest. A stochastic multi-tank reservoir model was created using MBAL and it consist of various producers and water injection wells. Sensitivity analysis was carried out on Seven development scenarios with a view to examine effect of maintaining reservoir pressure, sustaining well productivity and injectivity, optimize well counts and improving well delivery- timing, cost and well performance. The economic viability of each of the development scenarios was carried out to determine the net present value, incremental project cash flow, unit technical cost, unit development cost and breakeven price BEP of each of the scenarios. The optimal development strategy was then selected based on the production performance and key economic indicators. The project provided an opportunity to develop an additional 396MMbbls of recoverable oil from 32 new wells both producers and injector wells (P+WI).
Well Placement Optimization Using Simulated Annealing and Genetic Algorithm
(Society of Petroleum Engineers SPE, 2019-07-31) Aisha Diggi Tukur; Alonge Oluwaseun; Oghenerume Ogolo; Petrus Nzerem; Nhoyidi Nsan; Ikechukwu Okafor ; Abdullahi Gimba; Okafor Andrew
The general success ratio of wells drilled lies at 1:4, which highlights the difficulty in properly ascertaining sweetspots. well placement location selection is one of the most important processes to ensure optimal recovery of hydrocarbons. Conventionally, a subjective decision is based on the visualization of the HUPHISO (a product of net-to-gross, porosity and oil saturation) map. While this approach identifies regions of high HUPHISO regarded as sweetspots in the reservoir; it lacks consideration for neighbouring regions of the sweetspot. This sometimes lead to placement of wells in a sweetspot but near an adjoining aquifer; giving rise to early water breakthrough - low hydrocarbon recovery. Recently, heuristic optimization techniques. Genetic algorithm (GA) and simulated annealing (SA) has received attention as methods of selection of well-placement locations. This project developed and implemented GA and SA well-placement algorithms and compared the reservoir performance outputs to that of conventional method. Firstly, a reservoir performance model was built using a reservoir flow simulator. In the base case, the wells were placed based on a subjective selection of gridblocks upon the visualization of the HUPHISO map. Thereafter, JAVA routines of GA and SA well-placement algorithms were developed. The numeric data (ASCII format) underlying the map were then exported to the routines. Finally, the performance model was updated with new well locations as selected based on the GA and SA-based approach and the results were compared to the base case. The Comparison of the results showed that both GA and SA-based approach resulted to an increased recovery and time before water breakthrough.
Human Detection For Crowd Count Estimation Using CSI of WiFi Signals
(International Conference on Electronics Computer and Computation (ICECCO), 2019-12-01) Omotayo Oshiga; Hussein U. Suleiman; Sadiq Thomas; Petrus Nzerem; Labaran Farouk; Steve Adeshina
We address the problem of crowd estimation in situations such as indoor events using anonymous and non-participatory CSI of WiFi Signals. Observing the great resemblance of Channel State Information (CSI, a finegrained information captured from the received Wi-Fi signal) to texture, we propose a brand-new framework based on statistical mechanics, and relying only on sets of machine learning techniques.In this paper, a framework for crowd count estimation is presented which utilizes Chebyshev filter and SVD to remove background noise in the CSI data, PCA to reduce the dimensionality of the CSI data and spectral descriptors for feature extraction. From the extracted feature, a set of classiffying algorithms are then utilised for training and testing the accuracy of our crowd estimation framework The aim of this framework to effectively and efficiently extract the channel information in WiFi signals across OFDM carriers reflected by the presence of human bodies. From the experiments conducted, we demonstrate the feasibility and efficacy of the proposed framework. Our result depict that our estimation becomes more–rather than less–accurate when the crowd count increases.
Evaluation of the Potential of Calcium Hydroxide Synthesized from Eggshells as a Drilling Fluid Additive
(Petroleum and Coal, 2020-01-09) Abdullahi Gimba; Shalom Onome Amakhabi; Oghenerume Ogolo; Oluwaseun Alonge; Nzerem Petrus; Ikechukwu Okafor; David Afolayan
This research work studied the suitability of Ca(OH)2 synthesized from eggshell as a drilling fluid additive. Ca(OH)2 was synthesized from calcined eggshells (CES) and uncalcined eggshells (UCES) and characterized using FTIR and EDX. Samples of one laboratory barrel of water-based mud were prepared using bentonite clay from Afuze, Edo State, Nigeria, and the synthesized Ca(OH)2 produced from CES and UCES and commercial Ca(OH)2 were added to different mud samples prepared, and its effect on the mud properties were tested for. The results obtained from the experiment conducted showed that the synthesized Ca(OH)2 gave comparable pH values as the commercial Ca(OH)2. Hence it served primarily as a pH enhancer. However, the addition of Ca(OH)2 from both sources increased the filtrate volume and mud cake thickness far beyond API standard which might create wellbore problems due to the high filtrate loss and mud cake thickness that were observed.
Study of the Potential of Sodium Carbonate Extracted from Trona as a Drilling Fluid Additive
(International Journal of Engineering Research in Africa, 2020-06-30) Petrus Nzerem; Enyo June Adejoh; Oghenerume Ogolo; Ikechukwu Okafor; Abdullahi Gimba; Ternenge Joseph Chior; Precious Ogbeiwi
Drilling additives play a unique role during drilling operations, from aiding in the control of various drilling challenges to successfully enhancing downhole drilling efficiency. pH enhancers are amongst the plethora of additives imported into Nigeria at exorbitant prices to aid in drilling operations. These additives includes NaOH, Na2CO3, Ca(OH)2 etc. These additives are used to improve the mud pH and mitigates drill string corrosion. The high cost of importation of these additives, has warranted the need for product substitution which should take advantage of the locally available resources. This paper evaluated the suitability of locally-sourced Trona, as a mud additive in drilling mud. Trona is known chemically as Sodium Sesquicarbonate or Sodium Hydrogen Carbonate. A distinguishing factor in this research work was the purification of Trona by extracting the compound of interest (Na2CO3) from it using the monohydrate process. The purification method involved crushing and screening of Trona as well as calcination, filtration and evaporation processes. The analysis of the Trona and the extracted product was performed using quantitative analysis and characterization tools such as FTIR and EDX. Further experimentation was carried out to evaluate the effects of the extracted sodium carbonate on the mud pH, rheology, and density of the water based mud. The results were also compared to the results gotten from the addition of conventional Na2CO to similar mud samples. The extracted Na2CO was observed to increase the pH of the mud samples from 8.73 to 9.52 and the commercial Na2CO increased it from 8.73 to 10 and this value is still in the range of API standard. The pH enhancers from both sources also had effect on the mud rheological properties. This indeed showed that the extracted Na2CO from Trona acted as drilling fluid pH enhancer and hence possess the potential for usage in the industry.
Assessing the Impact of Deep Offshore and Inland Basin Production Sharing Contract Ammendments on the Economics of Deep Offshore E&P Assets in Nigeria
(Society of Petroleum Engineers, 2020-08-04) Oghenerume Ogolo; Omowumi Iledare; Petrus Nzerem; Ikechukwu Okafor ; Emeka Iloegbunam; Isaac P. Ekeoma
Nigeria recently amended the Deep Offshore and Inland Basins Act. The Act seeks to generate aditional annual revenue of over $1 billion for the government. The 2019 Law seems attractive to the government in the short run in terms of early rent extraction; on one hand, the seeminglly attractiveness of the fiscal terms in the Ammended Act, which is to expand output from investment in Nigeria deep offshore in the country is conjectural. The purpose of this paper is to evaluate the impact of the amendments to the PSC Act on value creation and addition to stake holders using systems and economic metrics that include investment earning power and discounted government take. A designed petroleum economic modeling framework applied to the fiscal terms in the new Act show a significant decrease in value addition to contractor portfolio of assets by about 25% but increases government discounted take statistics from 63.70% to 72.64% in comparison to the fiscal and contract terms in PSC 1993. The IRR and FLI obtained using the terms in the new Act were 23.66% and 0.043, respectively.
Absorption, Diffraction and Free Space Path Losses Modeling for the Terahertz Band
(MECS, 2020-08-18) Petrus Nzerem; Oyeleke D. Oluseun; Idris Muhammad; Sadiq Thomas; Olabode Idowu-Bismark
With the explosive increase in the data traffic of wireless communication systems and the scarcity of spectrum, terahertz (THz) frequency band is predicted as a hopeful contender to shore up ultra- broadband for the forthcoming beyond fifth generation (5G) communication system. THz frequency band is a bridge between millimeter wave (mmWave) and optical frequency bands. The contribution of this paper is to carry out an in-depth study of the THz channel impairments using mathematical models to evaluate the requirements for designing indoor THz communication systems at 300GHz. Atmospheric absorption loss, diffraction loss and free space path loss were investigated and modeled. Finally, we discuss several potential application scenarios of THz and the essential technical challenges that will be encountered in the future THz communications. Finally, the article finds that propagating in the THz spectrum is strongly dependent on antenna gain.
Economic Modelling of the Delay in Passing the Petroleum Industry Bill in Nigeria and Its Impact on Deep Offshore Investments and Government Take Statistics
(Research Square, 2020-11-21) Oghenerume Ogolo; Petrus Nzerem
The petroleum industry bill (PIB) in Nigeria aims to reform the petroleum sector of the country and increase government revenue from petroleum investments. Despite the benefits the bill offers to the country, its passage has suffered several setbacks. This research therefore studied the impact of the delay in passing the bill on deep offshore investments. Economic models were built using the fiscal terms in PIB 2009 and 1993 production sharing contract (PSC) arrangement to evaluate the impact of the bill. The model with the 1993 PSC fiscal terms was adjusted to capture the delay in passing the bill. The bill was assumed to be passed on a yearly basis for 10 years (2010 to 2019). The impact of the delay in passing the bill based on the reserve portfolio of firms in the deep offshore region of the country was also evaluated. The delay in passing the PIB reduced the government take. It was seen that for the non-passage of the bill, the government lost about $1227.2 MM. When the bill was passed in 2019, the government had been losing about $11.843 MM on a yearly basis due to the delay in passing the bill.
Applications of Artificial Intelligence Based Techniques on the Analysis of Chemical Data: a Review
(International Conference on Multidisciplinary Engineering and Applied Science (ICMEAS), 2021-07-15) Chinomso Odimba; Steve Adeshina; Petrus Nzerem
Artificial Intelligence based techniques such as Deep Learning, Machine Learning, Chemometrics have recently begun to replace chemical heuristics. They are promising tools that can be used to gain insight on the characteristics, processes and interactions of a chemical sampleand to a clearer and better understanding of chemical data. The focus of this review paper is on the recent developments on the applications of Artificial Intelligence based techniques for different chemical scenarios of computational chemistry, quantum chemistry, synthetic route design, drug delivery, analysis of spectral data and analytical chemistry.
Production of Biodiesel from Waste Cooking Oil by Transesterification Process using Heterogeneous Catalyst
(NIJEST, 2021-12-07) Ayuba Salihu; Mahmood A. A.; Gimba S. B.; Petrus Nzerem; Ikechukwu Okafor
Non-renewable diesel from fossil has been considered as potentially carcinogenic with serious harmful effect to human health and to the environment. This study aimed to produce a renewable diesel –biodiesel- via transesterification of waste cooking oil (WCO), investigated and determined the most suitable amongst various types of heterogenous catalysts (viz a viz KOH/CaCO3, KOH/CaO and KOH/K2CO3). The chemical and physical characterisation of the biodiesel was been carried out. Among the catalysts investigated, KOH/CaCO3 catalyst showed the best catalytic performance in terms of % yield and better fuel quality in density, acid value, viscosity and free fatty acid. The reason for this performance may be due to its most basic characteristic than the others. As a result, this catalyst was selected for the optimisation study. At the optimum reaction conditions of 10 wt% catalyst loading and 1:10 oil to methanol feed mole ratio, triglycerides conversion was highest, 98.12%. The characterisation results shows that the parameters tested (i.e. density, viscosity, acid value and free fatty acid) meet the strict requirements of the biodiesel standard and therefore, the produced fuel can be used in place of the petrol diesel.
Evaluation and Treatment of Cement Contamination in Water Based Mud
(NJEAS, 2023-01-01) Tahir Aliyu; Ikechukwu Okafor; Ayuba Salihu; Khaleel Jakada; Oghenerume Ogolo; Petrus Nzerem; Abdullahi Gimba; Oluogun Olawale
Drilling mud is susceptible to contamination, particularly from cement, yet monitoring its characteristics and implementing control and remediation strategies is critical for its performance in safe and cost-effective drilling operations. This study presents an experimental investigation into the evaluation and treatment of cement contamination in Water Based Mud (WBM). Four mud samples were prepared and three were contaminated with 4g, 8g and 12g of cement. A chemical treatment using 6g of sodium bicarbonate was applied as a remedy for contamination. The Rheological properties, mud pH and mud densities of the contaminated and treated Water Based Mud at temperatures of 35°C, 55°C, 75°C and 95°C were determined. Furthermore, the elemental composition of samples of contaminated and treated Water Based Mud was determined using an X-Ray Fluorescence Spectrometer. From the results obtained the mud density increased with a rise in cement concentration for both contamination and treatment with the exception of 8g cement concentration at 75°C and 95°C and 12g cement concentration at 55°C and 75°C where a decrease was observed in the treatment process. The yield point and 10second gel increased for both contamination and treatment process. In contrast, the 10minute gel decreased for both contamination and treatment process. With some exceptions, increasing cement concentration resulted in a decrease in plastic viscosity, whereas treatment with sodium bicarbonate resulted in an increase with some exceptions. The mud pH for the contamination process increased as cement concentration increased, while treatment only marginally increased it with exception of 12g at 75°C and 95°C where a decrease was observed. Sodium bicarbonate treatment improves stability by decreasing excessive calcium and lime contamination from cement, reducing pollutants and enhancing the pH stability of the drilling mud. Additionally, results from the mud characterization indicates a higher percentage of 17.962% lime (CaO) for cement contamination and lower percentage of 15.710% lime (CaO) for treatment with sodium bicarbonate which agrees with literature for the treatment process.
STUDY OF THE POTENTIAL OF CALCIUM HYDROXIDE SYNTHESIZED FROM PERIWINKLE SHELL AS A pH ENHANCER IN WATER BASED DRILLING MUD
(NJEAS, 2023-01-01) Zainab Lamin; Ikechukwu Okafor; Khaleel Jakada; Petrus Nzerem; Abdullahi Gimba; Oghenerume Ogolo; Ayuba Salihu; Khadijah Ibrahim
Reservoirs that contain acidic gases can lead to the corrosion of the drilling string and casing which could result in incessant down time and also increase the cost of drilling operation. This research work aimed at investigating the potential of using locally sourced materials such as Periwinkle Shell Ash (PSA) that can serve as substitutes to imported chemicals used in the industry, to help raise the mud pH to the API standard (9.5-12.5) whilst reducing the cost of drilling operation. Calcium hydroxide (Ca (OH2)) was extracted from Periwinkle Shell using two different process routes (via the calcination of the PSA and without it). Characterization tools were used to assess the functional groups present and the elemental composition of the periwinkle shell. Various laboratory equipment was used to observe the impact the additives would have on the mud properties (pH, mud weight, filtration characteristics and rheological properties) of the new drilling ﬂuid. Results showed that as the mass of the synthesized Ca (OH2) from the calcined PSA, the uncalcined PSA and the commercial Ca (OH2) was increased, the pH of the mud samples was observed to have increased the pH of the base mud by 20.9%, 15.1% and 10%. Therefore, this research showed that the extracted Ca (OH2) acted primarily as a pH enhancer. However, the addition of Ca (OH2) from all sources exhibited poor filtration characteristics as there was high filtrate loss as the filtration time and the additive concentration increased which could affect the formulation and the performance of the drilling mud.
MODIFICATION, CHARACTERIZATION AND APPLICATION OF LOCALLY SOURCED ORGANOCLAY FOR OIL SPILL REMEDIATION
(NJEAS, 2023-01-01) Ikechukwu Okafor; Roselyn Odimba; Ayuba Salihu; Oghenerume Ogolo; Petrus Nzerem; Abdullahi Gimba; Khaleel Jakada
The Bentonite clay, obtained from Ubakala, Umuahia, in Abia State was investigated as a sorbent for the potential treatment of oil spill in aquatic medium after its modificaion with Dioctadecyl dimethyl ammonium bromide (DODAB). The purified clay sample was subjected to hydrothermal ion exchange reaction to synthesize organoclays under mild reaction conditions. Changes in the microstructural, morphological and physicochemical properties of the modified clay samples were investigated and studied with the use of Fourier Transform Infrared (FTIR), Scanning Electron Microscopy (SEM) and Energy Dispersive X-Ray Spectroscopy (EDX). The observations showed the presence of new organic compound groups which indicated that the surfactant was intercalated successfully. The organoclays were further tested in a simulated oil spill situation to assess their potential as oil sorbents and sorbed about 4.5% of the oil that was simulated in the laboratory in water. The results further showed that the synthesized organoclay can be used for the remediation of oil spillage. The organoclays present a cost effective and a suitably environmentally friendly alternative for the remediation of oil spill polluted lands in the Niger Delta region of Nigeria.
INVESTIGATING THE IMPACT OF ACHI (BRACHYSTEGIA EURYCOMA) ON THE THICKENING TIME OF CEMENT
(NJEAS, 2023-01-01) Ayuba Salihu; Yakubu Nuhu; Khadijah Ibrahim; Abdullahi Gimba; Petrus Nzerem; Ikechukwu Okafor; Oghenerume Ogolo
In recent times, more wells are being drilled and producing in the petroleum industry. To prevent early workover resulting from casing collapse caused by corrosion, shattering of cement sheath during perforation and fracturing, and to protect the integrity of the well, it is important to use properly designed cement slurry with appropriate additives to protect the well from the formation. The development of adequate thickening time cement is a critical task in cementing operations today. Achieving suitable thickening time of oil well cement ensures both prevention of lost circulation and a long wait on cement time. With this in mind, this research work shows a comparative study of the thickening time of oil well cement with achi and without achi contamination under different temperature of 130 ℉, 150 ℉, 200 ℉, and 250℉ and pressure conditions of 1000 psi, 1500 psi, 2000 psi and 3000psi respectively for all the experiment conducted. The thickening time of cement slurry without achi content at 70 Bc were 205, 215, 202 and 200 minutes respectively. The experiment was also conducted under different achi content ranging from 2 g, 4 g, 8 g, 10 g to 12g. The results and analysis were compared. The result with 2g achi content were 164, 147, 146, and 141 minutes. The results with 4g achi content were 127, 131, 130, and 124 minutes. The results with 8g achi content were 71, 69, 75, and 65 minutes, while the results at 10g achi content were 67, 62, 63, and 60 minutes. The results with 12g achi content were 63, 62, 60, and 56 minutes under the temperature and pressure respectively. The data obtained from the experiment signifies that introducing achi and altering the temperature and pressure to the cement slurry has a significant effect on the properties of the cement by accelerating the thickening time.
A COMPREHENSIVE REVIEW OF HYDRAULIC FRACTURING TECHNIQUES IN SHALE GAS PRODUCTION
(NJEAS, 2023-01-01) Umar Adekola; Abdullahi Gimba; Ayuba Salihu; Khaleel Jakada; Ikechukwu Okafor ; Petrus Nzerem; Joseph Chior; Oghenerume Ogolo; Khadijah Ibrahim
Shale gas has emerged as a significant source of natural gas due to advancements in hydraulic fracturing and horizontal drilling technologies. This extraction method has facilitated drilling and production activities in regions previously untouched by oil and gas development. Hydraulic fracturing, a well-stimulation technique suitable for low and moderate-permeability reservoirs, relies on the successful drilling of horizontal wells and the creation of multiple hydraulic fractures to ensure economic viability. While shale gas presents significant energy production opportunities, concerns have been raised regarding its environmental impact. To mitigate these risks and determine the most effective approach for shale gas extraction, alternative fracturing technologies are being investigated. Notably, a considerable number of perforation clusters in shale gas horizontal wells do not contribute to production, highlighting the potential for refracturing. Therefore, a comprehensive analysis is required to evaluate the performance of hydraulic fracturing and alternative fracturing technologies in shale gas wells, considering factors such as cost-effectiveness, environmental impact, and gas extraction efficiency. This article aims to evaluate the hydraulic fracturing technology's capability to enhance gas recovery in shale gas formations as well as its environmental implications. The focus of this research is primarily on the hydraulic fracturing technique employed in shale gas development, its production capability, and associated environmental concerns. Through a systematic evaluation, this study provided valuable insights into the potential of hydraulic fracturing in maximizing gas recovery while addressing environmental challenges in shale gas formations.
CHARACTERIZATION OF WHEAT HUSK ASH AND CALCINED EGGSHELL AS POTENTIAL GLASS FORMER
(International Conference on Multidisciplinary Engineering and Applied Sciences, 2023-02-02) Serifat Olamide Adeleye; Adekunle Akanni Adeleke; Petrus Nzerem; Peter Pelumi Ikubanni; Ayuba Salihu; Adebayo Isaac Olosho
Numerous agricultural byproducts, such as rice husk and straw, bagasse from sugar cane, palm kernel shell, wheat husk and straw, corn cobs, etc, are highly desired for the production of renewable energy and are seen as potential raw materials for high-value products. Because they can be used to extract quality silica and Calcium oxide for borosilicate glass production, this research has demonstrated that these wastes have a significant end value. X-ray diffraction (XRD) spectroscopy, Fourier transform infrared spectroscopy (FT-IR), and X-ray fluorescence spectroscopy (XRF) were used to characterize the calcined waste eggshell and wheat husk ash for crystal type, compound identification, and chemical composition. The findings demonstrated that the amount of silica and calcium oxide obtained from agricultural waste could be a suitable alternative source for making glass, with calcined eggshells having a calcium oxide content of 91.7% and wheat husk ash having a silica content of 71.3%. The potential for utilizing the CaO and amorphous silica in the formation of glass is thus intriguing.