Your search keyword '"Aljawad, Murtada Saleh"' showing total 4 results

1. Sustaining Wormholes Mechanical Stability in Weak Acidized Carbonates Using Consolidants.

Author

Mustafa, Ayyaz, Desouky, Mahmoud, Aljawad, Murtada Saleh, Solling, Theis, and Dvorkin, Jack

Subjects

LIMESTONE, HARD rock minerals, POISSON'S ratio, CARBONATE rocks, DIAMMONIUM phosphate, YOUNG'S modulus, PHOSPHATES

Abstract

Matrix acidizing is vital to enhance the production of tight carbonate formations. In weak carbonate rocks or acid over-dissolution, the rock is prone to failure upon developing wormholes. Strengthening agents can play a significant role in mitigating failure and supporting more extended productivity. In this study, we tested 0.1 M and 0.2 M zinc sulfate (ZnSO4) and 0.5 M diammonium phosphate ((NH4)2HPO4) as strengthening agents, which change the dominant host mineral into harder ones. Both agents were tested on two different types of acidized (i.e., wormholed) carbonate rocks, specifically Austin chalk and Indiana limestone. The impulse hammer and acoustics measurements evaluated the carbonate rocks' mechanical properties before and after the treatment. In addition, scanning electron microscopy energy-dispersive X-ray spectroscopy (SEM–EDS) and scanning electron microscopy (SEM) were used to affirm the change of rock mineralogy into harder minerals after the treatment. The chemical treatment caused no noticeable change in the wormhole size and shape, as revealed by the scanned micro-computed tomography (micro-CT) images. The chemical treatment of the samples was conducted by core flooding the plugs at high pressure and temperature with 4–5 pore volumes of the chemicals and leaving them in the treatment solution for 72 h. As a result of the formation of harder minerals, the mechanical properties after the treatment showed improvement. Zinc sulfate raised the surface rock hardness of limestone by 16%, while diammonium phosphate showed a 30% increase when evaluated with the same technique. The most noticeable improvement happened to chalk after treatment with diammonium phosphate. Chalk impulse hammer hardness almost quadrupled with the diammonium phosphate. The acoustics measurements showed a similar result to the impulse hammer through an increase in the dynamic Young's modulus and a decrease in Poisson's ratio. [ABSTRACT FROM AUTHOR]

Published

2023

2. Quantifying acid diversion efficiency through NMR tortuosity measurements.

Author

Elsayed, Mahmoud, BinGhanim, Ahmed, Aljawad, Murtada Saleh, El-Husseiny, Ammar, Al-Abdrabalnabi, Ridha, and Mahmoud, Mohamed

Subjects

NUCLEAR magnetic resonance spectroscopy, COMPUTED tomography, TORTUOSITY, DIFFUSION measurements, NUCLEAR magnetic resonance, CARBONATE rocks

Abstract

The diversion efficiency measures the acid capacity to change its flow direction to the lower permeability reservoir sections. A good acid diverter creates a tortuous (zigzagged) wormhole within the acidized core sample in a laboratory setup. Here, we studied two different acid diverters compared to the conventional hydrochloric acid (HCl) to investigate their efficiency in changing the wormhole direction inside the rock core. Nuclear magnetic resonance (NMR) can be used to measure the 3D tortuosity of a rock sample; hence, we propose it as a tool to measure acid diversion efficiency because it can be applied in the field and in the laboratory. Two acid systems were utilized: straight 15 wt.% HCl acid and gelled acid consisting of 15 wt.% HCl acid and polyacrylamide polymer (PAM). Four coreflooding experiments were conducted on 1.5 inch-diameter × 3 inch-length Indiana limestone samples, two with straight HCl acid and two with gelled HCl acid at different PAM concentrations. NMR was utilized to measure the T2 distribution of the rock samples and diffusion tortuosity in two orthogonal directions. Also, X-ray computed tomography (CT) of the acidized samples was taken to visualize the wormholes. Results showed that the polymer-based acid-created zigzagged paths, and more acid volume was consumed to create the wormholes using CT. NMR diffusion tortuosity measurements showed that the tortuosity was reduced along the wormhole direction in all experiments. Nevertheless, the gelled acid treatments showed a significant reduction of the tortuosity orthogonal to the main wormhole path. The diversion efficiency of the 50 lbm/ 1000 gal PAM-gelled acid was 35% higher compared to the straight HCl acid. On the contrary, the 30 lbm/ 1000 gal PAM-gelled acid gave only 10% improvement in the diversion. The index could screen quantitatively which diverting acid is more efficient. We introduced a new diversion index based on the NMR diffusion measurements in this study to quantify the diversion capacity of an acid system in carbonate rock. [ABSTRACT FROM AUTHOR]

Published

2023

3. Thermochemical acid fracturing of tight and unconventional rocks: Experimental and modeling investigations.

Author

Tariq, Zeeshan, Aljawad, Murtada Saleh, Mahmoud, Mohamed, Abdulraheem, Abdulazeez, and Al-Nakhli, Ayman R.

Subjects

LIMESTONE, HYDRAULIC fracturing, TEMPERATURE control, ROCKS, TREATMENT of fractures, PRESSURE control, ROCK deformation

Abstract

The exploitation of unconventional formations requires propped hydraulic fracturing treatments. Propped fracturing is an expensive process that usually suffers from operational challenges. In this study, a new technology is proposed which targets implementing thermochemical fluids to stimulate unconventional formations. These fluids release large pressure pulses upon a reaction that creates networks of cracks along the fracture. Triggering thermochemical fluids with acid creates differential etching along the fracture surfaces due to the acid/rock dissolution. The new technology was tested experimentally through coreflooding on Indiana limestone and Kentucky sandstone samples and through breakdown pressure experiments on Eagle Ford shale samples. The breakdown pressure of the Eagle Ford shale samples was reduced from 2400 to 900 pisa using thermochemical fluids triggered with acid. It was also observed that the acid triggered thermochemical fluids could maintain the permeability of the fractures at high closure stresses due to the acid/rock dissolution. A laboratory and field-scale models were also developed in this study to understand thermochemical reactions. The laboratory-scale model could capture the pressure pulses generated experimentally and the system temperature. The field-scale model was then used to understand the thermochemical reactive transport in a hydraulic fracture. The model showed that thermochemical concentration is the most significant parameter in controlling the temperature and pressure magnitudes in the field. • Thermochemical fluids triggered with acid generate high conductivity and network of cracks. • Thermochemical fluids triggered with acid reduce the breakdown pressure. • A model is created to match the pressure pulses and temperature magnitudes obtained experimentally. • Sensitivity analysis was conducted at field-scale to investigate the importance of different design parameters. • Thermochemical fluids concentration was found to be the most important design parameter. [ABSTRACT FROM AUTHOR]

Published

2020

4. A green and efficient acid system for carbonate reservoir stimulation.

Author

Mustafa, Ayyaz, Aly, Moustafa, Aljawad, Murtada Saleh, Dvorkin, Jack, Solling, Theis, and Sultan, Abdullah

Subjects

*LIMESTONE, *CARBONATE reservoirs, *DOLOMITE, *COMPUTED tomography, *CHELATING agents, *NUCLEAR magnetic resonance, *CARBONATE rocks

Abstract

Matrix acidizing is a well stimulation method that is applied to enhance productivity. The success of a stimulation job depends mainly on the efficiency of the acid systems that are employed. This study investigated a new and efficient acid system that is biodegradable, not corrosive, and safe to handle. The system efficiency was compared to that of HCl and chelating agents. Acid coreflooding has been applied to chalk, dolomite, and limestone carbonate rock samples to measure the efficiency in terms of injected pore volume to breakthrough (PVBT). The rock samples were characterized in terms of porosity, permeability, composition using X-ray diffraction (XRD), and pore distribution using nuclear magnetic resonance (NMR). The effluent was collected at different times and analyzed using induced coupled plasma (ICP). Medical computed tomography (MCT) was used to visualize the interior of the rock samples after acidizing. The new acid system was more efficient in terms of acid spending than straight HCl acid and chelating agents in Indiana limestone. At the optimum injection rate, chelating agents had an optimum PVBT value of about 15 compared to 0.85 for plain HCl acid. Using the new acid system resulted in an optimum PVBT value of only 0.41, which is less than half of HCl acid. A numerical wormhole simulator was implemented to match the experimental PVBT and assess the reactivity of the acid system. • A novel acid system has been identified to be better than aqueous HCl. • A modelling approach reproduces the wormholing. • Different lithologies react (systematically) different. [ABSTRACT FROM AUTHOR]

Published

2021