End of Linear Flow Time Picking in Long Transient Hydraulically Fractured Wells to Correctly Estimate the Permeability, Fracture Half-Length and Original Gas in Place in Liquid Rich Shales

Dahraj, Naeem Ul. Hussain; Ali, Muhammad; Khan, Muhammad Noman

doi:10.2118/185303-ms

Cited by 12 publications

(5 citation statements)

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“…It is pertinent to measure the conventional petrophysics and rock properties via reservoir characterization in order to quantify hydrocarbon potential. − This can be achieved by proper characterization of the porous media and its lithology. − Our results for petrophysical experiments depict bright difference in properties of tight sandstone rock samples before and after LN 2 treatment, Figure and Table . Liquid nitrogen treatment from 30 to 90 min has enhanced the porosity and permeability of tight sandstone rocks due to induced fractures.…”

Section: Results and Discussionmentioning

confidence: 88%

Effect of Cryogenic Liquid Nitrogen on the Morphological and Petrophysical Characteristics of Tight Gas Sandstone Rocks from Kirthar Fold Belt, Indus Basin, Pakistan

et al. 2020

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Tight gas sandstone production faces enormous challenges from marginal matrix porosity and permeability in rock formations. In this regard, the liquid nitrogen (LN 2 ) treatment remedy has been suggested as an appropriate stimulation approach to resolve this issue. An experimental study was carried out to investigate the cryogenic liquid nitrogen fracturing of tight rock sandstone to enhance gas recovery from such reservoirs. Three core samples from the Kirthar fold belt were subjected to LN 2 treatment for 30, 60, and 90 min. Petrophysical characterization was performed through scanning electron microscopy, atomic force microscopy, nanoindentation measurements, and quantitative X-ray diffraction technique. The results reveal wide conductive fractures with an optimum size of 30 μm in the 90 minutes treatment case. Moreover, petrophysical measurements show that porosity increases from 8 to 19% at an optimal liquid nitrogen (LN 2 ) treatment duration (90 minutes). Furthermore, the permeability of the samples increased from 31 to 53 md after treatment with liquid nitrogen. Results from nanoindentation studies after LN 2 treatment revealed a significant decrease in nanoindentation moduli because of the increase in cracked rock compressibility.

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Section: Results and Discussionmentioning

confidence: 88%

Effect of Cryogenic Liquid Nitrogen on the Morphological and Petrophysical Characteristics of Tight Gas Sandstone Rocks from Kirthar Fold Belt, Indus Basin, Pakistan

et al. 2020

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“…Energies 2020, 13, x FOR PEER REVIEW 3 of 30 nano-silica polymer grafted polymer [61], ZnO polymer nanocomposite [43], TiO2/polymer nanocomposite [62], TiO2/clay nanocomposite [63], and several others [64]. Nanomaterials are widely used for different purposes, including enhanced oil recovery [65][66][67][68], wettability alteration [69][70][71][72], IFT reduction [73][74][75], surface adsorption [76], and CO2 storage applications [77][78][79][80][81]. They have a potential to augment rheological properties and shale inhibition of unconventional HPHT wells, but this has not been reported in a review work to date.…”

Section: Development Of Unconventional Reservoirsmentioning

confidence: 99%

Nanomaterial-Based Drilling Fluids for Exploitation of Unconventional Reservoirs: A Review

et al. 2020

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The world’s energy demand is steadily increasing where it has now become difficult for conventional hydrocarbon reservoir to meet levels of demand. Therefore, oil and gas companies are seeking novel ways to exploit and unlock the potential of unconventional resources. These resources include tight gas reservoirs, tight sandstone oil, oil and gas shales reservoirs, and high pressure high temperature (HPHT) wells. Drilling of HPHT wells and shale reservoirs has become more widespread in the global petroleum and natural gas industry. There is a current need to extend robust techniques beyond costly drilling and completion jobs, with the potential for exponential expansion. Drilling fluids and their additives are being customized in order to cater for HPHT well drilling issues. Certain conventional additives, e.g., filtrate loss additives, viscosifier additives, shale inhibitor, and shale stabilizer additives are not suitable in the HPHT environment, where they are consequently inappropriate for shale drilling. A better understanding of the selection of drilling fluids and additives for hydrocarbon water-sensitive reservoirs within HPHT environments can be achieved by identifying the challenges in conventional drilling fluids technology and their replacement with eco-friendly, cheaper, and multi-functional valuable products. In this regard, several laboratory-scale literatures have reported that nanomaterial has improved the properties of drilling fluids in the HPHT environment. This review critically evaluates nanomaterial utilization for improvement of rheological properties, filtrate loss, viscosity, and clay- and shale-inhibition at increasing temperature and pressures during the exploitation of hydrocarbons. The performance and potential of nanomaterials, which influence the nature of drilling fluid and its multi-benefits, is rarely reviewed in technical literature of water-based drilling fluid systems. Moreover, this review presented case studies of two HPHT fields and one HPHT basin, and compared their drilling fluid program for optimum selection of drilling fluid in HPHT environment.

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“…The conventional methods of exploitation and development of such resources have limited applicability in their extraction. ,,,, Additionally, the economical production from such reservoirs cannot be achieved by conventional means due to their complex pore system and lesser connectivity, complex pore geometry, extremely low porosity, and permeability. − Hence, this requires innovative technologies to enhance the productivity of shale gas reservoirs. , Such techniques include carbon dioxide (CO 2 ) injection, − acidizing, hydrofracking, − drilling optimization, − , and liquid nitrogen (LN 2 ) fracturing (a recently developed technique). ,,,,,, …”

Section: Introductionmentioning

confidence: 99%

Cryogenic Liquid Nitrogen Fracking Effects on Petro-Physical and Morphological Characteristics of the Sembar Shale Gas Formation in the Lower Indus Basin, Pakistan

et al. 2022

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Shale gas resources have emerged as critical resources in global energy. Pakistan has a substantial unconventional shale gas potential. However, shale gas in Pakistan, like in the United States and China, is still poorly developed compared to other unconventional resources. Shale reservoirs exhibit extremely poor permeability for production by conventional means. Numerous approaches have been applied to extract unconventional shale gas energy resources, including acid treatment and hydraulic fracturing. However, due to copious concerns, many countries have banned such practices. Hence, waterless fracturing techniques have the potential to alleviate such issues. In such situations, cryogenic fracturing by liquid nitrogen (LN2) is an imperative stimulation option for tight formations. Hence, we obtained samples from the Sembar shale formation of the lower Indus basin in Pakistan and experimentally investigated the effects of pre- and post-treatment using LN2 under various time cycles (30, 60, and 90 min). The study provides information about mineralogical, microstructural, and petro-physical properties. Sembar shale samples were exposed to LN2 for aging at various time cycles to generate fractures. The cryogenic LN2 pre- and post-treatment effects were quantitatively characterized using atomic force microscopy (for topography), scanning electron microscopy (for microstructural properties), energy dispersive spectroscopy (for elemental composition), petro-physical quantification (for porosity and permeability), and nanoindentation (for rock-mechanical properties). The results reveal that, before LN2 treatment, Sembar exhibited nominal pore-throat sizes. However, the post-treatments of cryogenic LN2 were very effective in creating microcracks of up to 17 μm. Similarly, the petro-physical properties exhibited a significant increase after LN2 treatment. The mean indentation moduli decreased from 24.34 to 12.25 GPa for 50 mN force and 20.15 to 10.42 GPa for 200 mN force. The topographic study found increased surface roughness from 356 to 778 nm due to the LN2 treatment of 90 min. Cryogenic LN2 treatment can improve the pore connectivity of shale samples and significantly enhance the flowing capacity, which may greatly increase the productivity of unconventional shale gas reservoirs.

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End of Linear Flow Time Picking in Long Transient Hydraulically Fractured Wells to Correctly Estimate the Permeability, Fracture Half-Length and Original Gas in Place in Liquid Rich Shales

Cited by 12 publications

References 1 publication

Effect of Cryogenic Liquid Nitrogen on the Morphological and Petrophysical Characteristics of Tight Gas Sandstone Rocks from Kirthar Fold Belt, Indus Basin, Pakistan

Effect of Cryogenic Liquid Nitrogen on the Morphological and Petrophysical Characteristics of Tight Gas Sandstone Rocks from Kirthar Fold Belt, Indus Basin, Pakistan

Nanomaterial-Based Drilling Fluids for Exploitation of Unconventional Reservoirs: A Review

Cryogenic Liquid Nitrogen Fracking Effects on Petro-Physical and Morphological Characteristics of the Sembar Shale Gas Formation in the Lower Indus Basin, Pakistan

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