Experimental Study of the Wettability Characteristic of Thermally Treated Shale

Yang, Jiajin; Gu, Cuilin; Chen, Wei; Yang, Yuan; Wang, Tengxi; Sun, Jingli

doi:10.1021/acsomega.0c03258

Cited by 10 publications

(9 citation statements)

References 59 publications

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“…The water contact angles of the nonporous PHBV and PHBV/10% Bioglass composite cuboids were evaluated to determine the hydrophilicity of the two kinds of scaffold composites. The sessile drop technique was used to evaluate the water contact angles at 25°C using a contact angle measuring instrument (SZ10-JC2000A, Shanghai, China) ( Yang et al, 2020 ).…”

Section: Methodsmentioning

confidence: 99%

Integration of Bioglass Into PHBV-Constructed Tissue-Engineered Cartilages to Improve Chondrogenic Properties of Cartilage Progenitor Cells

Xue

Zhang

et al. 2022

Front. Bioeng. Biotechnol.

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Background: The Poly (3-hydroxybutyrate-co-3-hydroxyvalerate) (PHBV) scaffold has proven to be a promising three-dimensional (3D) biodegradable and bioactive scaffold for the growth and proliferation of cartilage progenitor cells (CPCs). The addition of Bioglass into PHBV was reported to increase the bioactivity and mechanical properties of the bioactive materials.Methods: In the current study, the influence of the addition of Bioglass into PHBV 3D porous scaffolds on the characteristics of CPC-based tissue-engineered cartilages in vivo were compared. CPCs were seeded into 3D macroporous PHBV scaffolds and PHBV/10% Bioglass scaffolds. The CPC–scaffold constructs underwent 6 weeks in vitro chondrogenic induction culture and were then transplanted in vivo for another 6 weeks to evaluate the difference between the CPC–PHBV construct and CPC–PHBV/10% Bioglass construct in vivo.Results: Compared with the pure PHBV scaffold, the PHBV/10% Bioglass scaffold has better hydrophilicity and a higher percentage of adhered cells. The CPC–PHBV/10%Bioglass construct produced much more cartilage-like tissues with higher cartilage-relative gene expression and cartilage matrix protein production and better biomechanical performance than the CPC–PHBV construct.Conclusion: The addition of Bioglass into 3D PHBV macroporous scaffolds improves the characteristics of CPC-based tissue-engineered cartilages in vivo.

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Section: Methodsmentioning

confidence: 99%

Integration of Bioglass Into PHBV-Constructed Tissue-Engineered Cartilages to Improve Chondrogenic Properties of Cartilage Progenitor Cells

Xue

Zhang

et al. 2022

Front. Bioeng. Biotechnol.

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“…Wettability performs a significant role in fluid displacement efficiency within porous systems during EOR. However, the change of wettability near the wellbore zone from water-wet to oil-wet can affect reservoir properties and the extraction of oil and gas and, consequently, induce formation damage. , This wettability alteration leads to a pressure drop and decline of oil permeability and restricts oil flow to the producing well.…”

Section: Application Of Nanotechnology For Formation Damage Controlmentioning

confidence: 99%

Review of Developments in Nanotechnology Application for Formation Damage Control

et al. 2021

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Formation damage has the potential to impair and weaken reservoir productivity and injectivity, causing substantial economic losses. Oil and gas wells can be damaged by various mechanisms, such as solid invasion, rock–fluid incompatibilities, fluid–fluid incompatibilities, and phase trapping/blocking, which can reduce natural permeability of oil and gas near the wellbore zone. These can happen during most field operations, including drilling operations, completion, production, stimulation, and enhanced oil recovery (EOR). Numerous studies have been undertaken in recent years on the application of nanotechnology to aid the control of formation damage. This review has found that nanotechnology is more successful than traditional materials in controlling formation damages in different phases of oil and gas development. This is facilitated by their small size and high surface area/volume ratio, which increase reactivity and interactivity to the adjacent materials/surfaces. Furthermore, adding hydrophilic nanoparticles (0.05 wt %) to surfactants during EOR alters their wettability from 15 to 33%. Wettability alteration capabilities of nanoparticles are also exemplified by carbonate rock from oil-wet to water-wet after the concentration of 4 g/L silica nanoparticles is added. In addition, mixing nanoparticles to the drilling fluid reduced 70% of fluid loss. However, the mechanisms of impairment of conductivity in shale/tight formations are not consistent and can differ from one formation to another as a result of a high level of subsurface heterogeneity. Thus, the reactivity and interaction of nanoparticles in these shale/tight formations have not been clearly explained, and a recommendation is made for further investigations. We also recommend more nanotechnology field trials for future research because deductions from current studies are insufficient. This review provides more insights on the applications of nanoparticles in different stages of oil and gas development, increasing our understanding on the measures to control formation damage.

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“…However, geological bodies are generally composed of multiple components, and different components exhibit different hydrophilic and hydrophobic properties. 11 Quartz, feldspar, and mica in rock reservoirs generally exhibit hydrophilic properties, while talc and metal sulfides exhibit hydrophobic properties. 12 The wettability of the coal reservoir matrix is related to the degree of metamorphism, 13 and its inclusions of clay exhibit strong hydrophilic properties, while hydrocarbon organic matter is hydrophobic.…”

Section: Introductionmentioning

confidence: 99%

“…Wettability can characterize the solid–gas–liquid interaction and determine the gas–water flow. However, geological bodies are generally composed of multiple components, and different components exhibit different hydrophilic and hydrophobic properties . Quartz, feldspar, and mica in rock reservoirs generally exhibit hydrophilic properties, while talc and metal sulfides exhibit hydrophobic properties .…”

Section: Introductionmentioning

confidence: 99%

Seepage Characteristics of Mixed-Wettability Porous Media on the Phase-Field Model

et al. 2022

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Clarifying the microscale gas–water flow behaviors in a mixed wettability reservoir is of great importance for underground engineering. A numerical model of mixed wettability based on circular particles was constructed using the MATLAB stochastic distribution program, and the gas–water flow was simulated based on the phase-field method. The Navier–Stokes equations were solved by the finite element method. The work analyzed the effects of the content of heterogeneous wetting particles, wettability, and inversed wettability of the matrix on the flow path and pressure distribution of the mixed wettability model. Besides, the two-phase flow behaviors were evaluated in microscale mixed-wettability porous media. The simulation results revealed that (i) the residual saturation of the gas phase showed a positive correlation with the hydrophobic particle content, and closed gases only existed in isolated pore channels with small content. Isolated closed gases gradually connected as the content increased. (ii) The residual gas content in the corner and tail end increased as the hydrophobicity of particles increased in hydrophilic matrices. Hydrophobic matrices showed a negative correlation, with the greatest pressure drop due to capillary resistance and step changes in the neutral-hydrophobic transition zone. (iii) Water-phase breakthrough time and gas-phase residual saturation showed a negative correlation change. The more space occupied by the gas phase, the faster the water-phase breakthrough. Moreover, the saturation no longer changes after the breakthrough. The work provides a guideline for determining the dominant flow path of phase displacements and the distribution of residual phases.

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Experimental Study of the Wettability Characteristic of Thermally Treated Shale

Cited by 10 publications

References 59 publications

Integration of Bioglass Into PHBV-Constructed Tissue-Engineered Cartilages to Improve Chondrogenic Properties of Cartilage Progenitor Cells

Integration of Bioglass Into PHBV-Constructed Tissue-Engineered Cartilages to Improve Chondrogenic Properties of Cartilage Progenitor Cells

Review of Developments in Nanotechnology Application for Formation Damage Control

Seepage Characteristics of Mixed-Wettability Porous Media on the Phase-Field Model

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