46 results on '"Zhang, Lunxiang"'
Search Results
2. A novel low-temperature evaporation wastewater treatment apparatus based on hydrate adsorption.
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Sun, Huilian, Wang, Shuai, Sun, Lingjie, Ling, Zheng, and Zhang, Lunxiang
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WASTEWATER treatment ,METHANE hydrates ,HEAVY metal toxicology ,ADSORPTION (Chemistry) ,WATER consumption ,WATER vapor - Abstract
Heavy metal pollution is an urgent challenge worldwide due to the acceleration of industrialization. While adsorption desalination is regarded as an innovative method for wastewater treatment, the current technologies have been impeded by high costs and intensive energy consumption. In this work, a novel low-temperature evaporation wastewater treatment apparatus based on hydrate adsorption was proposed. The water vapor from wastewater evaporation reacted with CO
2 to form hydrate under the pressure of 3.3 MPa, constantly promoting wastewater evaporation due to the consumption of water vapor. The effect of feeding concentration on treatment effect was analyzed in terms of removal efficiency, water yield, and enrichment factor. Remarkably, a maximum removal efficiency of 97.4% can be achieved by treating an artificial solution with a Cu2+ concentration of 500 mg/L. Furthermore, compared with the control group that only depended on evaporation and condensation without forming hydrate, the maximum water yield of purified water in the experimental group increased to 310%. This innovative design concept for a low-temperature wastewater treatment apparatus based on hydrate adsorption presents a promising solution for the green and energy-efficient treatment of heavy metal wastewater. [ABSTRACT FROM AUTHOR]- Published
- 2023
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3. Formation, Exploration, and Development of Natural Gas Hydrates.
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Dong, Hongsheng, Zhang, Lunxiang, and Wang, Jiaqi
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GAS hydrates , *METHANE hydrates , *NATURAL gas prospecting - Published
- 2022
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4. An Analytical Model for the Permeability in Hydrate‐Bearing Sediments Considering the Dynamic Evolution of Hydrate Saturation and Pore Morphology.
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Wang, Qilin, Chen, Xiongyu, Zhang, Lunxiang, Wang, Ziming, Wang, Dayong, and Dai, Sheng
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METHANE hydrates ,COMPUTED tomography ,PERMEABILITY ,SEDIMENTS ,GAS flow - Abstract
Hydrate‐saturation‐dependent permeability in sediments is largely affected by the pore morphology of hydrate. Hydrate pore morphology evolves from a single pore habit, which depends on its formation conditions, toward a sophisticated hybrid habit with increased hydrate saturation. Resulted permeability reduction curves in hydrate‐bearing sediments are diverse and lack universal models. By using a two‐parameter logistic function to link microscale hydrate pore habit evolution with macroscale permeability variations, this study establishes a pore‐morphology‐weighted permeability model that well captures the permeability evolution in hydrate‐bearing sediments at various conditions. The universality of this model is validated and the values of the two parameters in the model are calibrated using published laboratory and pressure core data. This newly proposed model offers a mechanistic understanding of the permeability in hydrate‐bearing sediments and an elegant expression that can be implemented in reservoir simulators for field‐scale gas production estimation. Plain Language Summary: Permeability of hydrate‐bearing sediments governs the gas and water flow, and thus plays important roles in many energy, environment, and climate related processes including the formation and evolution of hydrate deposits, the recovery of hydrate resources, and the release of methane from hydrates into the ocean and the atmosphere. Existing models of permeability in hydrate‐bearing sediments assume single and simplified hydrate pore morphology, and thus, fail to capture the dynamic evolution of permeability in sediments with changing hydrate saturation. With recent advances of direct observations of hydrate crystallization in sediments using microfocus X‐ray computed tomography, much has been learned about the dynamic evolution of hydrate morphology in sediment pores, based on which we established a physical model to quantitatively correlate the dynamic evolution of hybrid hydrate pore morphology to the permeability variation in sediments in this study. The robustness and universality of this new model are validated using published data from both laboratory synthesized and naturally occurred hydrate‐bearing samples. The results of this study enhance the physical understandings of flow in hydrate‐bearing sediments and shed light to hydrate reservoir evolution. Key Points: The evolution of hydrate pore morphology depends on hydrate formation conditions, exerting diverse controls over permeabilityThe relation between permeability and the saturation and pore morphology of hydrate is quantitatively described and analyzedThe new permeability model is universal and can capture measurements under excess‐gas, excess‐water, and dissolved‐gas conditions [ABSTRACT FROM AUTHOR]
- Published
- 2021
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5. In-situ observation for natural gas hydrate in porous medium: Water performance and formation characteristic.
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Zhang, Lunxiang, Sun, Mingrui, Sun, Lingjie, Yu, Tao, Song, Yongchen, Zhao, Jiafei, Yang, Lei, and Dong, Hongsheng
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METHANE hydrates , *POROUS materials , *FUSED silica , *NATURAL gas , *GAS hydrates , *NATURAL resources - Abstract
Extensive efforts have been made regarding gas hydrate sample reconstruction in the laboratory for a better understanding and development of natural gas resources. Magnetic resonance imaging (MRI) is a useful method for directly observing the reconstruction of methane hydrate, yet relevant studies remain limited. In this study, a 9.4-T 400-MHz MRI instrument was employed to investigate CH 4 hydrate formation in porous media involving various initial water saturation levels and sand diameters. Pressure histories and MRI signal variations were monitored to discuss the process of CH 4 hydrate growth, and the three main formation stages of induction, rapid growth, and slow formation were determined. Furthermore, the liquid water performance in MRI micro-images was analyzed to predict the characteristics of CH 4 hydrate formation. The results indicated that CH 4 hydrate formed in a spatially and temporally random manner and that pore plugging occurred owing to the residual water encased in grown hydrate. Additionally, phase saturations, water conversion percentages, and formation rates were defined to evaluate the effect of sand diameter and initial water saturation on CH 4 hydrate formation. With the reduction in the diameter of quartz glass beads from 400 μm to 100 μm, the average hydrate formation rate increased from 0.0010 min−1 to 0.0034 min−1, respectively. When the initial water saturation decreased to the optimized value (0.22 in this study), the water conversion percentage and hydrate saturation increased. [ABSTRACT FROM AUTHOR]
- Published
- 2020
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6. Analyzing spatially and temporally visualized formation behavior of methane hydrate in unconsolidated porous media.
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Zhang, Lunxiang, Sun, Lingjie, Sun, Mingrui, Lv, Xin, Dong, Hongsheng, Miao, Yang, Yang, Lei, Song, Yongchen, and Zhao, Jiafei
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METHANE hydrates , *POROUS materials , *GAS hydrates , *GAS distribution , *MAGNETIC resonance imaging , *DISCONTINUOUS precipitation - Abstract
An understanding of the nucleation and growth mechanism of methane hydrate in porous space is essential for exploitation and application of hydrates, but the mechanism is yet to be clarified. Magnetic resonance imaging (MRI) was employed to visually analyze the spatial and temporal formation behavior of methane hydrate in a porous media. Detailed information about the water distribution, initial nucleation sites, and hydrate growth was obtained, in addition to MRI images. The results demonstrated that the water molecules distributed in the vertical direction preferred the middle slice of a porous medium sample, and the decrease in the number of molecules in the middle slice and on both sides of the slice was similar during hydrate formation. The formation process are quite different in selected horizontal slices, which were contributed to the various distribution of water and gas in pore spaces and the randomness of methane hydrate formation. The extension of these predicted results could have important implications for optimizing the formation processes of gas hydrate in hydrate-based technologies. [ABSTRACT FROM AUTHOR]
- Published
- 2019
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7. Enhanced CH4 recovery and CO2 storage via thermal stimulation in the CH4/CO2 replacement of methane hydrate.
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Zhang, Lunxiang, Yang, Lei, Wang, Jiaqi, Zhao, Jiafei, Dong, Hongsheng, Yang, Mingjun, Liu, Yu, and Song, Yongchen
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CARBON dioxide adsorption , *METHANE hydrates , *DIFFUSION , *HYDRATES , *ENERGY storage , *ENERGY consumption - Abstract
The replacement of CH 4 by CO 2 in methane hydrates is a promising method for simultaneously achieving CO 2 storage and CH 4 recovery for global warming mitigation and energy production, respectively. However, gas replacement is restricted to the slow diffusion-limited transport of CO 2 caused by the formation of a mixed hydrate layer, and little attention has been paid to the storage of CO 2 . Therefore, this study proposed a combination of CH 4 /CO 2 replacement and thermal stimulation to enhance CH 4 recovery and CO 2 storage. The effects of the methane hydrate saturation level, replacement zone, and freezing point on the replacement were analyzed. The CH 4 replacement percentage and energy efficiency were obtained and compared using the replacement and combined methods. The results suggested that the combined method effectively improved CH 4 recovery, with the CH 4 replacement percentage exhibiting an upper limit of 64.63%. Moreover, In CH 4 /CO 2 replacement, the total number of moles of CO 2 stored is unequal to CH 4 recovered, because the replacement is sensitive to the free water in the pores of the hydrate sediments. In addition, the CO 2 storage efficiency was first discussed. The results proved that the CH 4 /CO 2 replacement has obvious advantages in CO 2 storage, and a maximum CO 2 storage efficiency of 96.73% was achieved by combined method. [ABSTRACT FROM AUTHOR]
- Published
- 2017
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8. Magnetic resonance imaging for in-situ observation of the effect of depressurizing range and rate on methane hydrate dissociation.
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Zhang, Lunxiang, Zhao, Jiafei, Dong, Hongsheng, Zhao, Yuechao, Liu, Yu, Zhang, Yi, and Song, Yongchen
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MAGNETIC resonance imaging , *METHANE hydrates , *CHEMICAL kinetics , *DISSOCIATION (Chemistry) , *HEAT transfer , *ADDITION reactions - Abstract
Depressurization is considered to be the most promising method for exploitation of natural gas hydrate. To analyze the characteristics of hydrate dissociation during depressurization, methane hydrate (MH) dissociation was performed at different depressurizing ranges and rates, and the hydrate dissociation process was directly observed using magnetic resonance imaging (MRI). The experimental results indicate that with increased depressurizing rate from 0.01 MPa/min to 0.1 MPa/min, the average dissociation rate increases for a given depressurizing range. Meanwhile, with an increase in depressurizing range from 0.3 MPa to 1.1 MPa, the average dissociation rate increases for a given depressurizing rate. Moreover, the hydrate dissociation process can be divided into two main stages: hydrate saturation remains constant with little fluctuation for several minutes after back-pressure decreases, and then the hydrate dissociates continuously until dissociation completes. In addition, excessively high depressurizing range and rate result in hydrate reformation and ice generation, which slow the rate of hydrate dissociation. Furthermore, it was also determined that MH reformation and ice generation always occur at the higher depressurizing range and rate due to insufficient heat transfer. [ABSTRACT FROM AUTHOR]
- Published
- 2016
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9. Effects of depressurization on gas production and water performance from excess-gas and excess-water methane hydrate accumulations.
- Author
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Zhang, Lunxiang, Dong, Hongsheng, Dai, Sheng, Kuang, Yangmin, Yang, Lei, Wang, Jiaqi, Zhao, Jiafei, and Song, Yongchen
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METHANE hydrates , *WATER-gas , *SPECIFIC heat capacity , *MAGNETIC resonance imaging , *WATER supply , *TEMPERATURE control - Abstract
[Display omitted] • Various water saturations simulate Classes I and II hydrate deposits in nature. • Ambient temperature controls periphery dissociation in excess-gas hydrate deposits. • Sensible heat dominates spatially uniform dissociation in excess-water deposits. • Secondary hydrate formation are prevented by adjusted gas production pressure. • Optimized depressurization is crucial to improve water production and CH 4 recovery. Depressurization is considered as the most promising technique for hydrate exploitation, as it achieves the highest energy profit ratio and is the most technologically feasible. However, the exploitation of excess-water hydrate accumulations generates high water production, leading to increased cost, poor energy efficiency, and problems with sand during operation. Thus, water management is crucial to gas recovery by the depressurization of different classes of hydrate accumulations, yet relevant studies remain limited. In this study, synthetic hydrate samples were prepared to simulate two types of natural methane hydrate sediments: Class 1 accumulations (excess-gas hydrate) and Class 2 accumulations (excess-water hydrate). Hydrate dissociation was conducted using a variety of depressurization approaches, and MRI imaging was employed to characterize water performance and methane recovery. Methane hydrate preferentially dissociated along the peripheries of the excess-gas samples due to more efficient heat dissipation. Methane hydrate dissociated more uniformly in the excess-water samples because the high specific heat capacity of water enabled the supply of extra heat. Furthermore, pressure histories, mean intensity change in MRI images, and water variations were monitored to analyze the characteristics of hydrate dissociation, changes in porosity, intrinsic permeability and reservoir heat, water and gas production rates, and possible secondary hydrate formation. The results of this study suggest that an optimized depressurization approach, such as stepwise depressurization, could improve methane recovery from Class 1 and Class 2 methane hydrate accumulations. [ABSTRACT FROM AUTHOR]
- Published
- 2022
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10. Permeability analysis of hydrate-bearing sediments considering the effect of phase transition during the hydrate dissociation process.
- Author
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Li, Min, Zhou, Shanshan, Wu, Peng, Zhang, Lunxiang, Yang, Lei, Li, Yanghui, Liu, Yu, Zhao, Jiafei, and Song, Yongchen
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METHANE hydrates ,PHASE transitions ,COMPUTED tomography ,PERMEABILITY ,SEDIMENT analysis ,POROSITY - Abstract
Permeability is the most important factor affecting water and gas production in hydrate-bearing sediments (HBS). In this study, we combined in-situ microfocus X-ray computed tomography (CT) and pore network model simulation to obtain insights into the dynamic permeability of the hydrate dissociation process. Microfocus X-ray CT is used to visualize the three-dimensional pore structures of the specimen. Then an equivalent pore network can be extracted, which is used as input to pore network flow simulator to simulate the water and gas flow process. Results show that secondary hydrate formation causes effective permeability k eff decreases and effective connate water saturation increases as hydrate saturation S h increases from 0.40 to 0.48. The water relative permeability k rw decreases and gas relative permeability k rg increases due to larger patchy hydrates (S h = 0.33). The k rw and k rg are largely affected by the pore and throat sizes and pore space connectivity. Hydrate dissociation in HBS also influences its permeability anisotropy. Secondary hydrate formation causes k eff decreases in the x , y , and z directions when S h increase from 0.40 to 0.48. Large patchy hydrates influence preferential flow direction for water flow. Predicting the dynamic permeability of the hydrate dissociation process would improve pore-scale water and gas flow analyses in HBS. • Secondary hydrate formation causes effective permeability decreases in the x, y, and z directions. • Permeability anisotropy in hydrate dissociating sediments was simulated. • Large patchy hydrates influence preferential flow direction for water flow. [ABSTRACT FROM AUTHOR]
- Published
- 2022
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11. Methane recovery and carbon dioxide storage from gas hydrates in fine marine sediments by using CH4/CO2 replacement.
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Wang, Tian, Zhang, Lunxiang, Sun, Lingjie, Zhou, Ran, Dong, Bo, Yang, Lei, Li, Yanghui, Zhao, Jiafei, and Song, Yongchen
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MARINE sediments , *GAS hydrates , *CARBON dioxide , *METHANE hydrates , *GAS storage , *MARINE natural products - Abstract
[Display omitted] • CH 4 /CO 2 replacement behaviors in natural marine sediments are investigated. • CO 2 diffusion is weakened by clayey sediment during replacement process. • NGH reservoir with moderate water content has excellent potential for replacement. • Optimized P-T conditions are crucial to improve CH 4 recovery from hydrates. The use of CH 4 /CO 2 replacement from hydrate bearing sediments for CH 4 recovery and CO 2 storage is an alternative option to mitigate energy shortage and global warming. Fine marine sediments are highly attractive for abundant gas hydrate reserves and tremendous CO 2 sequestration potential. However, the CH 4 /CO 2 replacement regularity previously obtained from coarse sands may not be suitable for fine marine sediments because of their distinct differences in physical properties. In this study, fine natural marine sediments obtained from the South China Sea were used as porous media to investigate the CH 4 /CO 2 replacement characteristics. The results indicated that the pressure and the temperature were the main controlling factors affecting the replacement efficiency. The content of initial methane hydrate and water in reservoir had a more significant effect on CO 2 storage than CH 4 recovery. The gas exchange kinetics in hydrates presented in fine marine sediments were significantly different from those in coarse grained sediments. CH 4 /CO 2 replacement in fine marine sediment seemed to be inhibited by weak CO 2 diffusion as peculiarities of the sediment including fine grain size, clay swelling and high proportion of bound water. According to the observed experimental results, the pressure and temperature conditions should be comprehensively optimized to enhance the mass transfer effect and improve economic benefits. This work provided greater insights into future marine NGH exploitation and contributed to carbon sequestration with applying CH 4 /CO 2 replacement method. [ABSTRACT FROM AUTHOR]
- Published
- 2021
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12. A combined hydrate-based method for removing heavy metals from simulated wastewater with high concentrations.
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Sun, Huilian, Sun, Lingjie, Zhao, Yang, Yang, Shiying, Zhang, Lunxiang, Dong, Hongsheng, Yuan, Hui, Ling, Zheng, Zhao, Jiafei, and Song, Yongchen
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HEAVY metals ,METHANE hydrates ,SEWAGE ,HEAVY metal toxicology ,WASTEWATER treatment ,COMPLEX ions - Abstract
With the acceleration of industrialization, heavy metal pollution has significantly threatened environmental and human health. An innovative hydrate-based method was proposed in this study to treat wastewater containing heavy metal ions with high concentrations. The feasibility of this technology was confirmed by measuring ion concentration in purified water through hydrate dissociation. By forming R141b hydrate in simulated heavy metal solution under atmospheric pressure at 2 °C, the treatment effect on the wastewater was examined in terms of removal efficiency, water yield, and enrichment factor. Experiments explored how these treatment characters were influenced by changing the volume of hydrate former, post-treatment method, concentration, and species of ions. Considering the treatment effect and economy of the technology, we selected the optimal volume ratio was 4. We combined the solid-liquid separation as the post-treatment method of hydrate-based wastewater treatment and selected vacuum filtration combined with centrifugation as the optimal method, which increased the removal efficiency significantly. The treatment effect was determined by ion concentration, independent of the species of ions. The highest removal efficiency of copper ion reached 91.85%, up to 81.05% yield of water, with an enrichment factor of 2.686. The removal efficiency of different ions in complex wastewater was about 89%. Under the experimental conditions of this research, the limit value of copper ion concentration in the wastewater treated with the hydrate method reached 70 g/L. The wastewater treatment technology proposed in this study using hydrate may promote the development of treating wastewater containing high concentrations of heavy metals. [Display omitted] • A hydrate method is proposed to treat heavy metal sewage with high concentrations. • The limit value of ion concentration determines the removal efficiency. • The influence of concentration on treatment characteristics is addressed. • The suitable post-treatment combined with hydrates improve the removal efficiency. [ABSTRACT FROM AUTHOR]
- Published
- 2021
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13. Desalination and enrichment of phosphorus-containing wastewater via cyclopentane hydrate.
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Yang, Yamei, Du, Rui, Shi, Changrui, Zhao, Jiafei, Song, Yongchen, Zhang, Lunxiang, and Ling, Zheng
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CYCLOPENTANE ,METHANE hydrates ,SALINE water conversion ,LOW temperatures ,HIGH temperatures ,SEWAGE ,WASTE recycling - Abstract
With the rapid development of agriculture, controlling phosphorus emissions is a pressing challenge for preventing water eutrophication. A graphite-promoted cyclopentane (CP) hydrate-based desalination was proposed to remove K 3 PO 4 from effluents. It was found via the in situ optical microscopy that the reaction temperature and the concentration of feeding K 3 PO 4 solution significantly affect the morphologies and amount of the as-produced CP hydrate crystals. The lower reaction temperature produces more crystals with irregular shapes, while fewer crystals formed in K 3 PO 4 solution with higher concentration. The reaction temperature, time and feeding concentration-dependent desalination and salt enrichment performances were studied. It was found that desalination efficiency linearly increases with the elevated reaction temperature ranging from − 2 °C to 3 °C; however, water recovery declines with temperature. The temperature-dependent water recovery is due to the strong driving force for hydrate formation at low temperatures. The time-dependent water recovery shows a three-stage feature, including exponential growth, linear increase, and stable stages, owing to the interaction between the driving force of supercooling and the increasing K 3 PO 4 concentration during the reaction processes. The desalination efficiency shows an inverted volcanic shape with the increased concentration of feeding K 3 PO 4 solution. The pre-melting effect plays a critical role in improving desalination efficiency at high K 3 PO 4 concentrations. A maximum desalination efficiency of 85.0% was reached for treating an artificial solution with salinity as high as 42452 mg/L. Both desalted water and concentrated phosphorus-containing solution can be recovered by this method, which is attractive for producing freshwater with potential for recovery of resources. [Display omitted] • A method using cyclopentane hydrate formation was proposed to extract freshwater and enrich K 3 PO 4. • An impressive water recovery over 50% can be obtained in 2 h. • This method can treat an artificial solution with salinity as high as 42452 mg/L. [ABSTRACT FROM AUTHOR]
- Published
- 2021
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14. Capillary pressure in the anisotropy of sediments with hydrate formation.
- Author
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Wang, Jiaqi, Zhang, Lunxiang, Ge, Kun, and Dong, Hongsheng
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METHANE hydrates , *COMPUTED tomography , *CAPILLARIES , *ANISOTROPY , *HYDRATES , *DISCONTINUOUS precipitation - Abstract
• Capillary pressures in different directions are presented in this study. • Hydrate formation makes the skewness of capillary pressure finer slanting degrees. • The heterogeneity in hydrate formation determines capillarity in anisotropy. • The stronger capillary heterogeneity occurs in the vertical direction. The random nucleation and growth of hydrates in the pore space contribute to the heterogeneity of hydrate sediments, which results in anisotropic fluid flow. An exact forecast for capillary pressure in different directions, which governs the gas/water distribution and the volume of residual water saturation in porous sediments, is of significant importance for hydrate exploitation. In this study, the index properties of the artificial hydrate sediment were characterized through X-ray computed tomography (CT) visualization scanning. The spatial structure feature of hydrate sediment was captured via a topological pore network, which was established from CT imaging. Then, the evolution of capillary pressure in anisotropy with the formation of hydrates was simulated and discussed. The results indicated that with hydrate formation, the capillary pressure curves became steeper, representing skewness with finer slanting degrees and poor sorting. Moreover, the differences in capillary pressure with the same hydrate saturation between different directions was enlarged. Stronger capillary heterogeneity in the vertical direction represents greater heterogeneity, according to the Leverett J-Function. [ABSTRACT FROM AUTHOR]
- Published
- 2021
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15. Molecular dynamics simulation and in-situ MRI observation of organic exclusion during CO2 hydrate growth.
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Zhang, Lunxiang, Sun, Lingjie, Lu, Yi, Kuang, Yangmin, Ling, Zheng, Yang, Lei, Dong, Hongsheng, Yang, Shengxiong, Zhao, Jiafei, and Song, Yongchen
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MOLECULAR dynamics , *METHANE hydrates , *CONCENTRATION gradient , *HYDRATES , *CARBON dioxide , *WASTEWATER treatment - Abstract
• Organic exclusions with hydrate growth were firstly simulated and in-situ observed. • Progressive organic exclusion caused substance migration and concentration gradient. • Higher driving formation force generated the precipitation of excluded organics. Inorganic substances and most organic compounds are typically excluded from crystalline hydrate structures. In this study, the phenomenon and mechanism of organic exclusions during hydrate formation were investigated using MD simulations and in-situ observations with an MRI experimental apparatus. The results showed that the organic macromolecules could not be trapped in the hydrate structure and formed a concentration gradient of dissolved organic substances from the growth front of the CO 2 hydrate into the aqueous solution. This study demonstrates the hydrate-based technology would be a promising method for organic wastewater treatment. [ABSTRACT FROM AUTHOR]
- Published
- 2021
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16. Characterizing anisotropy changes in the permeability of hydrate sediment.
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Wang, Jiaqi, Zhang, Lunxiang, Ge, Kun, Zhao, Jiafei, and Song, Yongcheng
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METHANE hydrates , *COMPUTED tomography , *HORIZONTAL wells , *GAS hydrates , *HYDRATES , *SOIL permeability , *PERMEABILITY - Abstract
Natural gas hydrate is recognized as an ideal substitute for traditional energy resources. Gas production from hydrate reservoirs is accompanied by the phase transition of solid hydrate, which inevitably results in changes to the microstructure of hydrate sediments. Therefore, the interaction mechanism between the microstructure and permeation characteristics of hydrate sediments must be investigated, especially permeability anisotropy. In this study, we assess the variations in permeability anisotropy during krypton hydrate formation using a pore network model and X-ray computed tomography. The results showed that absolute permeability in the vertical (k v) and horizontal (k h) directions both decreased throughout the formation process, but that the decline in k v was steeper, thus resulting in a sharp increase in the degree of permeability anisotropy (k h /k v). The relative permeability to gas was always higher in the horizontal direction than of that in the vertical direction, whereas the relative permeability to water was the opposite. Moreover, the difference in the relative permeability to water and gas between the two directions increased with the increasing hydrate saturation (S h). When extrapolating to the field-scale for hydrate field trials, we consider that horizontal wells provide a better option for gas production, especially for hydrate reservoirs with a higher hydrate saturation. • Prediction of permeability anisotropy during hydrate formation is presented. • Hydrate formation increases the degree of permeability anisotropy (k h /k v). • Difference in gas/water flow between two directions increases with high S h. • Horizontal wells are found to be a better option for gas hydrate production. [ABSTRACT FROM AUTHOR]
- Published
- 2020
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17. Kinetic enhancement of capturing and storing greenhouse gas and volatile organic compound: Micro-mechanism and micro-structure of hydrate growth.
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Zhang, Lunxiang, Kuang, Yangmin, Dai, Sheng, Wang, Jiaqi, Zhao, Jiafei, and Song, Yongchen
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VOLATILE organic compounds , *METHANE hydrates , *SODIUM dodecyl sulfate , *BICARBONATE ions , *GREENHOUSE gases , *GAS hydrates , *HYDRATES , *GAS storage - Abstract
Kinetic enhancement for capturing and storing harmful gases into hydrates simultaneously to achieve low energy penalties and environmental mitigations. • Kinetic surfactants accelerate gas captures in pore spaces. • Oscillated pressure controls are first proposed to enhance CO 2 gas captures. • Enhanced gas capture processes change microstructural features. • The hydrate technology is a safely long-term storages of harmful gases. The use of hydrate-based technology for gas capture and storage is highly attractive for environmental mitigation, as it entails low energy penalties and provides gas storage density maximization and long-term storage stability. Although this method has been investigated in extensive researches, its development is restricted by the obscure underlying gas capture micro-mechanisms, elusive micro-structures of stored forms, and insufficient hydrate film growth rates. In this study, the Magnetic Resonance Imaging technique was employed to analyze the hydrate growth micro-processes for greenhouse gas (imitated by CO 2 , CH 4 , and various fractions of CO 2 -CH 4 mixed gases) and volatile organic compound (simulated by C 2 H 4 and C 2 H 2 gases) capture and storage. The hydrate film growth was enhanced with the addition of 288 ppm sodium dodecyl sulfate (SDS), which significantly improved the hydrate growth in the cases of hydrocarbon gases, but not CO 2 gas due to the competing adsorption of bicarbonate and dodecyl sulfate ions. With SDS, hydrocarbon gas hydrates grew via the patchy model at 65–105 mm/s, and 65–95% liquid water was converted into hydrates for gas capture and storage. However, only about 1.4% water was converted into CO 2 hydrates with SDS, at 10.4 mm/s. Thus, a multi-pressure control mechanism for secondary hydrate growth was developed to promote CO 2 capture and storage, based on a large amount of dissolved CO 2 gas compared to the other investigated gases. The enhanced CO 2 capture has important implications for the optimized harmful gas sequestration, due to preferentially patchy hydrate morphologies and associated impacts on permeability. [ABSTRACT FROM AUTHOR]
- Published
- 2020
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18. Kinetic process of upward gas hydrate growth and water migration on the solid surface.
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Liang, Huiyong, Guan, Dawei, Liu, Yuda, Zhang, Lunxiang, Zhao, Jiafei, Yang, Lei, and Song, Yongchen
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METHANE hydrates , *GAS hydrates , *CARBON sequestration , *COMPUTED tomography , *THIN films , *SEPARATION of gases - Abstract
[Display omitted] Gas hydrates have gained great interest in the energy and environmental field as a medium for gas storage and transport, gas separation, and carbon dioxide sequestration. The presence of small doses of surfactants in the aqueous phase has been reported to enhance hydrate formation; however, the underlying mechanisms remain poorly understood. Thus, in situ high-resolution X-ray computed tomography measurements were performed to monitor the upward water migration and the resulting hydrate nucleation and growth. It was found that the presence of hydrate crystals at the gas–liquid–solid contact line triggered the enhanced growth of hydrates on the reactor wall. A time delay was observed between the disappearance of the bulk water reservoir and its transformation into hydrate. The lower interfacial tension between the hydrate surface and the solution facilitated its adsorption onto the reactor wall once a thin film of hydrate nucleated on the solid wall surface. These hydrate layers present on the reactor wall were found to be porous, wherein the porosity decreased with increased subcooling. These fundamental results will be of value in understanding the mechanism of hydrate growth in the presence of surfactants and its potential application in hydrate-based technologies. [ABSTRACT FROM AUTHOR]
- Published
- 2022
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19. Upward migration of the shallow gas enhances the production behavior from the vertical heterogeneous hydrate-bearing marine sediments.
- Author
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Yang, Lei, Wang, Zifei, Shi, Kangji, Ge, Yang, Li, Qingping, Leng, Shudong, Zhou, Yi, Zhang, Lunxiang, Zhao, Jiafei, and Song, Yongchen
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GAS hydrates , *MELTWATER , *GAS migration , *MARINE sediments , *NATURAL gas production , *METHANE hydrates - Abstract
Low gas production rates and insufficient gas yield hinder the large-scale production from natural gas hydrates; a joint production of gas hydrate and its underlying shallow gas is expected to address this limitation. This study focuses on the interaction between heterogeneous hydrate reservoirs and the upward migration of the shallow gas. The results indicated a 38.4 % increase in production efficiency with the assistance of the shallow gas. Specially, the melt water generated from extensive hydrate decomposition could potentially induce a lateral migration of the shallow gas at the interfacial zones of the heterogeneous reservoirs. Further investigation revealed that a lower production pressure would help the release of the shallow gas as well as the hydrate decomposition, thereby contributing to a 64.55 % shorter t 90. A faster depressurization rate could facilitate the temperature recovery by intensifying the lateral movement of the shallow gas in the junction layer. Consequently, a proper control of the upward channeling of the shallow gas was suggested in the field test for a successive and secure gas production. Our results could be of help in elucidating the interlayer interference mechanisms and the selection of the depressurization strategy for a better recovery efficiency from the multi-gas source reservoirs. [Display omitted] • An upward channeling of the shallow gas occurred during the gas production. • The production efficiency increased by 38.4 % with the assistance of shallow gas. • An enhanced release of the shallow gas contributed to a 64.55 % shorter t 90. [ABSTRACT FROM AUTHOR]
- Published
- 2024
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20. Enhancing gas hydrate decomposition assisted by the shallow gas: Effects of interlayer permeability and depressurization strategies.
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Shi, Kangji, Feng, Yu, Gao, Peng, Fan, Qi, Li, Qingping, Leng, Shudong, Zhou, Yi, Zhang, Lunxiang, Zhao, Jiafei, Liu, Yu, Yang, Lei, and Song, Yongchen
- Subjects
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RENEWABLE energy transition (Government policy) , *GAS hydrates , *ENERGY consumption , *MARINE sediments , *GAS flow , *METHANE hydrates , *NATURAL gas - Abstract
• Efficiency of shallow gas-assisted production was 10.71 % higher than single one. • Decrease in interlayer permeability increased possibility of interlayer blockage. • High-speed gas flow under 2 MPa provided possibility of unblocking interlayer. • Shallow gas showed a significant temperature bounce in constant-pressure stage. Natural gas is crucial for the global energy transition to low-carbon and clean energy utilization. Natural gas hydrate, rich in high energy–density natural gas, has excellent production potential. At present, even with the most commercially viable depressurization method, the production efficiency is still limited by the weakening of the hydrate decomposition driving force. That is expected to be enhanced by optimizing the upward migration of the shallow gas. However, the effect of production elements of the depressurization method on the shallow-gas upward migration remains unclear. In this study, several production elements were systematically analyzed. Results showed that the efficiency of shallow gas-assisted hydrate production was 10.71 % higher than that of a single one, with a 79.16 % increase in the hydrate stage decomposition rate. Reducing the production pressure from 3 MPa to 2 MPa boosted the production efficiency by 366.85 %. The resulting high-speed shallow gas provided the possibility of unblocking the interlayer. In addition, the shallow gas layer exhibited a more significant temperature rise effect during the constant-pressure stage when employing a stepwise depressurization. The injection of hotter gas was able to further promote the hydrate decomposition. Finally, the crucial role of the shallow-gas sweep behaviors in optimizing production performance was verified. The results could guide the efficient use of the shallow gas to strengthen the hydrate decomposition in the field joint production of multi-gas source reservoirs. [ABSTRACT FROM AUTHOR]
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- 2024
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21. Strengthening the energy efficiency ratio of warm deep gas-assisted hydrate production through optimizing water circulation.
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Shi, Kangji, Zhao, Yang, Wei, Kunbo, Fan, Qi, Li, Qingping, Leng, Shudong, Zhou, Yi, Zhang, Lunxiang, Liu, Yu, Zhao, Jiafei, Yang, Lei, and Song, Yongchen
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GAS hydrates , *HEAT radiation & absorption , *ENERGY consumption , *NATURAL gas production , *WATER consumption , *GEOTHERMAL resources , *METHANE hydrates - Abstract
• Hydrate decomposition was enhanced by circulating warm water from the deep gas layer. • Increasing the flow rate of the circulating water improved the production efficiency. • A cycling regulation of the hybrid water flow rate could enhance the EER by 16.23 %. Utilizing the geothermal energy from the deep gas layer to enhance the hydrate decomposition is a potential clean production approach, avoiding the vast costs and severe pollution in the traditional heat injection scheme. In this work, a novel method was proposed to promote hydrate decomposition by employing circulating water to transport heat from the deep gas layer. Results showed that increasing the water flow rate from 9.82 mL/min to 39.28 mL/min could significantly improve the production efficiency by 27.27 %. Yet, the energy efficiency ratio (EER) slightly decreased by 3.31 % due to the increased power consumption of the water pump. A hybrid water flow rate was thus used with a lower rate in the later production stage when the heat absorption of hydrate decomposition was declining accordingly. This was found to successively improve the EER by 2.68 % while maintaining comparable production efficiency; a further cycling regulation (intermittent circulating) of the hybrid water flow rate could significantly enhance the EER by 16.23 %. The results could guide the efficient utilization of natural geothermal energy to facilitate the large-scale gas production from the natural gas hydrates when heat supply from the surrounding sediments was limited. [ABSTRACT FROM AUTHOR]
- Published
- 2024
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22. The promoting effect and mechanisms of oxygen-containing groups on the enhanced formation of methane hydrate for gas storage.
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Shi, Changrui, Liu, Huiquan, Zhang, Lunxiang, Yang, Mingjun, Song, Yongchen, Zhao, Jiafei, and Ling, Zheng
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METHANE hydrates , *GAS hydrates , *GAS storage , *GROUP formation , *NATURAL gas storage , *NATURAL gas transportation - Abstract
• CBCMs significantly improved the hydrate formation kinetics and storage capacity. • Carbonyl groups was identified as the active sites enhancing CH 4 hydrate formation. • Functional groups tuned hydrogen-bonding network results in the enhanced kinetics. The sluggish formation kinetics is a formidable challenge for the practical application of gas hydrate-based technologies for natural gas storage and transportation. Methane hydrates in both nature and labs exclusively form with the assistant of foreign additives via a heterogeneous process. Although the process is common and widely used, it remains unclear what makes a material a good methane hydrate promoter. Additionally, the molecular mechanisms underlying the promoted hydrate formation remain largely unknown. Herein, carbon monoliths (labeled as CBCM) with finely controlled surface functional groups were produced using cellulose as precursors. The oxygen-containing groups have been identified as the active sites enhancing the nucleating ability of methane hydrates. Carbonyl oxygen is pinned down as the most effective functional group in reducing the induction time and enhancing the formation kinetics of methane hydrate. The turned hydrogen bonds between water molecules, which are close to the surface of CBCM, contribute to the enhanced formation kinetics as confirmed by the Raman spectroscopy. The CBCM with optimized carbonyl oxygen significantly improve the methane hydrate formation kinetics and storage capacity with outstanding cycle stability, which are superior than most of the previously reported promoters, particularly in shorter induction time. The finding in this work paves the way for effectively designing promoters and unraveling the underlying mechanism for enhancing gas hydrate formation. [ABSTRACT FROM AUTHOR]
- Published
- 2022
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23. Effects of protein macromolecules and metabolic small molecules on kinetics of methane hydrate formation in marine clay.
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Liu, Yanzhen, Feng, Yu, Zhang, Lunxiang, Song, Yongchen, Yang, Lei, and Zhao, Jiafei
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METHANE hydrates , *SMALL molecules , *MACROMOLECULES , *GAS hydrates , *ORGANIC compounds , *NUCLEAR magnetic resonance - Abstract
• Metabolic molecules significantly promote hydrate formation. • Protein macromolecules could act as kinetic inhibitor of hydrate nucleation. • Water in the macropores is preferentially consumed during hydrate formation. Numerous efforts have been made to mimic the natural marine environments to understand the behavior of hydrate formation and accumulation in the sediments under seafloor. Yet it is found that the role of organic matters in the kinetics of hydrate formation is largely veiled, which should be much enriched as a result of the activities of the marine ecosystem. Therefore in this study, the kinetic effects of protein macromolecules and metabolic small molecules on CH 4 hydrate formation were examined; the organic compounds were extracted from the samples gathered from the hydrate reservoir located in the South China Sea. A total of 2058 species classified into 10 types of protein macromolecules and metabolic molecules were identified. Low-field nuclear magnetic resonance technique was used to in-situ monitor the hydrate formation process. The results showed that the metabolic molecules could remarkably promote hydrate formation, with more water converted into hydrate within a shorter time. Proteins have been widely studied to inhibit hydrate formation; here it is for the first time confirmed that the proteins extracted from the natural samples drilled in the hydrate reservoir could act as kinetic inhibitor, lowering the possibility of hydrate nucleation. It was further indicated that hydrate formation majorly consumed the water in the macro pores; this was followed by a diffusion-limitation process with the hydrate shell acting as mass transfer barrier slowing down the water conversion. The water in the micropores was yet found to be very difficult to participate in the reaction, potentially resulting from the unavailable gas-water contact. The findings could provide insights into the kinetics of hydrate formation in the presence of organic matters abundant in natural sediments and expand the current understandings on the occurrence of natural gas hydrate under marine environments. [ABSTRACT FROM AUTHOR]
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- 2021
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24. Visual study of methane hydrate kinetics in a microfluidic chip: Effect of the resins extracted from the crude oil.
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Feng, Yu, Han, Yuze, Jia, Yuxin, Lv, Xin, Li, Qingping, Liu, Yanzhen, Zhang, Lunxiang, Zhao, Jiafei, Yang, Lei, and Song, Yongchen
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PETROLEUM , *METHANE hydrates , *GAS flow , *PIPELINE maintenance & repair - Abstract
Natural resins extracted from crude oil in the South China Sea have a significant inhibition effect on hydrate nucleation and growth due to the polar functional group of resins. [Display omitted] • Resins were extracted from the crude oil from the SCS. • The resins contained many polar heteroatomic functional groups. • Hydrate grew along gas flow in the microfluidic channels. • The resins could retard the hydrate formation kinetics. • The more polar resins showed a stronger inhibitory effect. Hydrate plugging in oil and gas transport pipelines is a crucial challenge to the safety of flow and maintenance of pipelines. Specifically, the resins, the strongest polar component in crude oil would significantly affect hydrate kinetics but the mechanism of the interaction remains unclear. Here, a microfluidic chip was used to monitor the hydrate formation under gas flow in-situ , with and without resins extracted from the crude oil. FTIR–ATR and NMR results indicate the presence of a large number of polar components in the resins. High-resolution mass spectrometry showed that two resins contain a variety of heteroatom compounds and sulfur-containing heteroatom. The results indicated that these resins played a surprisingly inhibitory role in the hydrate formation kinetics; this was ascribed to the presence of the polar functional groups. The results also showed that the hydrate grew along the direction of gas flow. Notably, the presence of resins could prolong the induction time and lower the growth rate; this effect could be enhanced with the addition of resins containing more heteroatoms. This study filled the gap in the effect of natural resins on the hydrate formation kinetics and provided guidance on preventing hydrate plugging in oil and gas transport pipelines. [ABSTRACT FROM AUTHOR]
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- 2024
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25. Sustained production of gas hydrate through hybrid depressurization scheme with enhanced energy efficiency and mitigated ice blockage.
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Wei, Rupeng, Xia, Yongqiang, Qu, Aoxing, Fan, Qi, Li, Qingping, Lv, Xin, Leng, Shudong, Li, Xingbo, Zhang, Lunxiang, Zhang, Yi, Zhao, Jiafei, Yang, Lei, Sun, Xiang, and Song, Yongchen
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METHANE hydrates , *ENERGY consumption , *GAS reservoirs , *GAS hydrates , *POWER resources , *SUSTAINABILITY , *NATURAL gas - Abstract
Several trial productions have been conducted on marine natural gas hydrate reservoirs, demonstrating its enormous potential as an alternative energy source. Nonetheless, sustained and efficient production still remains challenging, with crucial issues on low gas production efficiency and blockages. The large amount of hydrate decomposition and resulting heat absorption can lead to prolonged subzero conditions close to the well; this can readily induce ice formation and blockage. This study aims to investigate the issue of ice blockages caused by insufficient energy supply during the recovery process. A systematic analysis of the energy consumption and ice blockage quantification at each stage of the traditional multi-stage direct depressurization and constant speed depressurization methods is conducted. A hybrid optimized scheme is proposed, which enhances energy utilization efficiency by appropriately utilizing reservoir sensible heat during the initial stage of production. Additionally, a multi-stage constant speed depressurization method is introduced in the later stages to mitigate production fluctuations and reduce blockage duration. Results showed a 69.5 % increase in energy efficiency and an average 67.1 % decline in gas blockage duration with comparable gas productivity. The proposed method could be a viable solution to mitigate challenges of icing blockages and fluctuating production during trial tests of marine hydrate reservoirs, achieving improved energy efficiency and sustainable production. • Ice blockage in hydrate reservoirs reduced production efficiency during direct and constant-speed depressurization methods. • Proposed a hybrid method to address gas production fluctuations caused by ice blockage through energy consumption analysis. • Multi-stage analysis revealed 70% energy efficiency improvement and 67% reduced ice blockage duration with the hybrid method. [ABSTRACT FROM AUTHOR]
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- 2024
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26. Modified balsa wood with natural, flexible porous structure for gas storage.
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Zhao, Yang, Qu, Aoxing, Yang, Mingzhao, Dong, Hongsheng, Ge, Yang, Li, Qingping, Liu, Yanzhen, Zhang, Lunxiang, Liu, Yu, Yang, Lei, Song, Yongchen, and Zhao, Jiafei
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WOOD , *METHANE hydrates , *GAS storage , *FLEXIBLE structures , *POROSITY , *X-ray microscopy - Abstract
The utilization and transportation of clean energy require efficient energy storage solutions. Gas hydrate represents a promising way for high-density storage under mild conditions. In particular, hydrate induced by confined space has the advantage of being environmentally friendly with rapid nucleation and high mass transfer efficiency. However, the cost of artificial pore-construction methods has hindered its widespread application. In this study, we report a novel approach of hydrate storage in the -SO 3 − modified flexible balsa wood as a naturally porous material. The surface sulfonate groups were successfully grafted by coupling agents which was verified by various techniques. The material's natural porous hierarchical structure allows for efficient fluid flow in porous media, enabling a reduction in induction time by ∼88% and a storage capacity of up to 150.6 v/v by adjusting the load water amount. The 100 wt% water-loaded wood materials exhibited the highest water conversion efficiency. Moreover, the recoverable mechanical properties make it reusable without performance degradation. The inner pore structure and hydrate morphologies were further investigated by X-ray microscopy to clarify the hydrate growth mechanism. The interconnected pores and channels make the hydrate grow in layers inside. In addition, the performance could be adjusted by simply changing the hydrophobicity to regulate the gas flow which may contribute to the large storage systems. The use of natural biomass porous materials provides an environmentally friendly and economically feasible strategy for gas storage. [Display omitted] • The modified flexible balsa wood was synthesized and applied in energy storage. • Methane hydrate induction time was reduced by ∼88% and the storage capacity was enhanced to 150.6 v /v. • The 400 wt% water loaded case exhibited the best storage performance. • The hydrate started to form in axial parenchyma structures verified by X-ray microscopy. • Tunable storage performance based on hydrophobic and hydrophilic modification. [ABSTRACT FROM AUTHOR]
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- 2024
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27. Sensible heat aided gas production from gas hydrate with an underlying water-rich shallow gas layer.
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Qu, Aoxing, Guan, Dawei, Jiang, Zhibo, Fan, Qi, Li, Qingping, Zhang, Lunxiang, Zhao, Jiafei, Yang, Lei, and Song, Yongchen
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METHANE hydrates , *GAS hydrates , *LATENT heat , *GAS condensate reservoirs , *HYDROGRAPHIC surveying , *PORE water , *GASES , *GEOLOGICAL surveys - Abstract
Increasing the efficiency of gas production from marine gas hydrate still faces significant problems. Based on the geological survey of marine reservoirs, gas hydrates are generally associated with underlying free gas layers with high temperature and water saturation. Here the effect of this gas layer and its characteristics on the gas and water production from the hydrate layer are studied. It was found that a large temperature difference existed between the two layers during gas production due to the different heat demand and consumption in each layer. Slower gas production rate was observed in case of dense distribution of hydrates in the hydrate-bearing layer and the resulting sluggish gas permeation and enormous heat supply. Notably, this was not present when the free gas layer was more water-saturated. The resulting maximum gas production rate could be effectively enhanced by 41 % at most as well. This was attributed to the increased sensible heat available from the pore water and the interbedded heat exchange. It was thus indicated that a hydrate reservoir with an underlying water-rich layer could be more favorable for gas production in terms of heat supply. • Joint exploitation through pre-embedding compartment device and vertical well. • A significant temperature difference between the two layers during exploitation. • Highly water-saturated underlying shallow gas layer enhance hydrate decomposition. [ABSTRACT FROM AUTHOR]
- Published
- 2023
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28. Effect of gas hydrate formation and dissociation on porous media structure with clay particles.
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Feng, Yu, Qu, Aoxing, Han, Yuze, Shi, Changrui, Liu, Yanzhen, Zhang, Lunxiang, Zhao, Jiafei, Yang, Lei, and Song, Yongchen
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METHANE hydrates , *GAS hydrates , *NATURAL gas , *POROUS materials , *CLAY , *NUCLEAR magnetic resonance , *POROSITY , *WATER distribution - Abstract
Natural gas hydrates are a potential future energy modality with the advantages of clean burning and large resource reserves and have attracted worldwide attention. Natural gas hydrates formation and dissociation impact the skeletal structure and mechanical properties of porous media sediments. In addition, there is a synergistic effect between the migration of fine clay particles in porous media and hydrate behavior. In this study, methane hydrate was examined in-situ using a low-field nuclear magnetic resonance system in the presence of two suspensions of clay particles with different stability. The results showed that clay particles impacted methane hydrate formation and dissociation and the pore structure of porous media. Hydrate nucleated preferentially in large pores, causing them to split into smaller pores; the presence of clay particles, especially illite, improved the water conversion rate. The results indicated that water content in large pores increased after hydrate dissociation but was discontinuous among different pores. When illite was present, the distribution was more continuous; when montmorillonite was present, the water distribution of the large pores was similar to that of the original state. This work increases our understanding of the kinetics, water migration, and pore structure alteration of methane hydrate formation and dissociation in sediments with clay particles and provides support for the safe and efficient development of natural gas hydrates. • Clay particles impacted methane hydrate formation and dissociation • Hydrate nucleated preferentially in large pores • Clay particles, especially illite, improved the water conversion rate • Water content in large pores increased after hydrate dissociation but was discontinuous among different pores [ABSTRACT FROM AUTHOR]
- Published
- 2023
- Full Text
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29. A molecular dynamics study on nanobubble formation and dynamics via methane hydrate dissociation.
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Lu, Yi, Feng, Yu, Guan, Dawei, lv, Xin, Li, Qingping, Zhang, Lunxiang, Zhao, Jiafei, Yang, Lei, and Song, Yongchen
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METHANE hydrates , *BUBBLES , *MASS transfer , *MOLECULAR dynamics , *SUPERSATURATION - Abstract
Schematic diagram for nanobubble formation in different hydrate dissociation stage. Methane supersaturation in water is the Prerequisite for nanobubble formation. [Display omitted] • Hydrate dissociation releases plentiful methane molecules to form gas supersaturation. • Closer nanobubbles coalesce to reduce system energy with one nanobubble surviving. • Nanobubble formation breaks mass transfer limitation, improveing dissociation rate. The formation condition of nanobubbles and its effect on the methane hydrate dissociation were studied using molecular dynamics (MD) simulations. To investigate the effect of liquid water proportion on the methane hydrate dissociation path and nanobubble formation conditions, two different initial configurations were built. Considering low liquid water proportion simulation, four main dissociation stages were identified, and nanobubbles formed when the methane supersaturation condition was met. During this period, hydrate dissociation rate decreases and fluctuates around zero, indicating that mass transfer limitation forms and hydrate cages undergo a long-term disappearance and rebuilding process. Nanobubbles can form in two distinct regions: the liquid water region and the final hydrate slice region. Hydrate dissociation rate increased after the first nanobubble formed, which broke the mass transfer limitation. Small nanobubbles formed at the end of the hydrate dissociation process also contributed to the final hydrate slice collapsing by shortening the diffusion distance of methane molecules to the gas phase. At the end of the simulation, only one nanobubble survived in the system with a mole percent of methane in water for two systems remaining at 0.4 and 0.9, respectively. [ABSTRACT FROM AUTHOR]
- Published
- 2023
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30. Investigation of ice evolution during methane hydrate dissociation at different initial temperatures in microporous media.
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Zhang, Yajin, Dong, Bo, Wang, Ping, Geng, Feifan, Zhang, Lunxiang, Qin, Yan, Chen, Cong, and Li, Weizhong
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METHANE hydrates , *GAS hydrates , *FREEZING points , *LATTICE Boltzmann methods - Abstract
In this work, a coupled lattice Boltzmann model is proposed to study the gas hydrate dissociation with consideration of ice evolution in microporous media. The reliability of this model is verified by simulating the dissociation of xenon hydrate and the freezing of water droplets, respectively. The initial temperature is one of the influences on methane hydrate dissociation. In this paper, methane hydrate dissociation and ice evolution characteristics have been analyzed at the initial temperature of 270.5 K–278 K. Within this temperature range, a maximum percentage of methane hydrate dissociation can be obtained near the freezing point. Ice formation inhibits and delays the methane hydrate dissociation at the initial stage. It is demonstrated that for the whole process, heat release caused by the ice-water mixture formation facilitates methane hydrate dissociation. However, the ice formation stage has negative impacts on hydrate dissociation time. Additionally, the whole dissociation can be divided into four processes by analyzing the evolution of dissociation percentage and ice saturation. Especially, three types of ice formation positions are concluded. They are related to the hydrate structure and occurrence state. This paper provides a reference of the effect of ice evolution on methane hydrate dissociation in practical applications. • A lattice Boltzmann model considering gas hydrate dissociation and ice evolution. • Methane hydrate dissociation characteristics at different initial temperatures. • Quantification of ice amount and visualization of microstructure. • The effect of ice-water mixture formation on methane hydrate dissociation. • Local positional distributions of ice formation during methane hydrate dissociation. [ABSTRACT FROM AUTHOR]
- Published
- 2023
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31. Promoting CH4/CO2 replacement from hydrate with warm brine injection for synergistic energy harvest and carbon sequestration.
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Wang, Tian, Sun, Lingjie, Fan, Ziyu, Wei, Rupeng, Li, Qingping, Yao, Haiyuan, Dong, Hongsheng, Zhang, Lunxiang, Yang, Lei, Zhao, Jiafei, and Song, Yongchen
- Subjects
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GEOLOGICAL carbon sequestration , *METHANE hydrates , *CARBON sequestration , *ENERGY harvesting , *SALT , *GAS hydrates , *THERMAL instability , *SALINE water conversion , *MASS transfer - Abstract
[Display omitted] • An approach of warm brine injection to promote CH 4 /CO 2 replacement is proposed. • Warm brine injection provides a 2.0 times enhancement of the cumulative gas yield. • A potential risk of hydrate reformation is alleviated by increasing salinity. • Gas production is insensitive to injected heat as the significant heat loss. • Brine injection scheme should be optimized based on energy harvest and CO 2 storage. CH 4 /CO 2 replacement for natural gas hydrates (NGHs) exploitation is a promising method for CO 2 geological sequestration and energy recovery simultaneously. However, the puzzles of low replacement efficiency and slow reaction rate caused by the mass transfer obstacle of gas exchange are fatal bottlenecks for field application of gas replacement method. Therefore, we propose a method that uses warm brine injection during CH 4 /CO 2 replacement process to break the barrier of CO 2 diffusion and enhance CH 4 recovery as well as CO 2 storage. Benefiting from the synergistic influence of salt effect and thermal stimulation as well as water flow erosion, warm brine injection provides three dimensionally connected channels in hydrate for subsequent mass transfer, improving CH 4 /CO 2 replacement in the deep layer of hydrate. CO 2 sequestration efficiency of the newly proposed method reaches 76.46%, and the maximum amounts of CH 4 recovery is nearly treble than that achieved by single CO 2 replacement method. Notably, a potential risk of secondary hydrate formation could occur upon the pressure surge and fluid migration attached to warm brine injection, which could be effectively alleviated by increasing salinity to destabilize hydrate lattices by reducing water activity. The gas production is insensitive to the injected heat as the significant heat loss during the transportation of injected brine in pipelines and thermal diffusion through boundaries. The introduction of free water increases the complexity of the reactions in hydrate reservoirs, and the formulation of brine injection regimes should be synergistically optimized based on energy harvest, energy efficiency and CO 2 sequestration. This work extends the previous knowledge on CH 4 /CO 2 replacement and shows important practical significance for future field studies of NGHs exploitation and CO 2 geological sequestration. [ABSTRACT FROM AUTHOR]
- Published
- 2023
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32. Enhanced clathrate hydrate formation at ambient temperatures (287.2 K) and near atmospheric pressure (0.1 MPa): Application to solidified natural gas technology.
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Sun, Lingjie, Sun, Huilian, Yuan, Chengyang, Zhang, Lunxiang, Yang, Lei, Ling, Zheng, Zhao, Jiafei, and Song, Yongchen
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GAS hydrates , *NATURAL gas , *NATURAL gas storage , *METHANE hydrates , *GAS storage , *POWER resources , *ATMOSPHERIC pressure - Abstract
• A new hydrate formation promoter was selected for methane storage. • The R141b was confirmed to improve the equilibrium condition of methane hydrate. • Thermodynamic characteristics of mixture hydrate was analysed. • Mechanism of mixture hydrate nucleation was proposed. • Gas storage procedure was optimized. Solidified natural gas is a promising alternative for improving natural gas storage owing to its safe and environmentally friendly properties. However, harsh conditions limit its application. In this study, the R141b was used as a thermodynamic promoter to enhance methane hydrate formation under mild conditions. Addition of R141b to the water system significantly shifted the phase equilibrium boundary to lower pressures and higher temperatures, in which the R141b-CH 4 hydrate can be formed at 0.1 MPa and 287.2 K. Notably, the final pressure of the cell after hydrate formation was near the atmospheric pressure even at an initial pressure of 5.384 MPa, suggesting that the R141b-CH 4 mixed hydrate had milder storage conditions and lower costs than liquefied natural gas (approximately 110 K). The higher initial pressure significantly reduces the induction time and increases gas storage. The mechanism of unusual kinetic characteristics of the R141b-CH 4 hydrates that were observed can be attributed to the different nucleation behaviour of CH 4 , R141b, and R141b-CH 4 hydrates. This study provides evidence of a new promoter using the solid hydrate method under mild conditions that can be alternatively used for the storage and transport of natural gas, thereby increasing the supply of clean energy without the high economic costs and safety issues. [ABSTRACT FROM AUTHOR]
- Published
- 2023
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33. Self-driven and directional transport of water during hydrate formation: Potential application in seawater desalination and dewatering.
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Sun, Lingjie, Sun, Huilian, Wang, Tian, Dong, Hongsheng, Zhang, Lunxiang, Yang, Lei, Zhao, Jiafei, and Song, Yongchen
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METHANE hydrates , *SALINE water conversion , *POROUS materials , *NUCLEAR magnetic resonance , *SILICA sand , *GAS-liquid interfaces , *FUSED silica - Abstract
Hydrate-based desalination has attracted considerable attention as an innovative desalination process without extra pollution; however, the slow kinetics of hydrate formation and the difficulty of separating solid hydrate from liquid brine hinder the industrialization of this technology. Hydrates exhibit water absorption effects and can be formed above silica sand beds to promote separation. Unfortunately, the mechanism underlying the self-driven and continuous directional transport of water during hydrate formation is unclear. In this study, the spatial and temporal formation behavior of hydrate in quartz glass beads were observed using a nuclear magnetic resonance system. The results revealed that not all types of guest molecules capable of forming hydrates exhibited the hydrate water absorption effect. The interfacial tension between the hydrate and bound water provided capillary driving force for water migration. Large particle sand had larger pore channels for water migration and low initial water saturation will inhibited water migration. The results of this study improve the understanding of water migration during hydrate formation in porous media. Our findings have significant potential for the application in desalination, sludge dewatering processes, and gas capture. • Not all types of hydrate guest molecules exhibit the hydrate water absorption effect. • Mechanism underlying the self-driven and continuous directional transport of water is analyzed. • Gases with low solubility tend to nucleate at the gas–liquid interface. • The capillary force of water in a porous structure drives water migration. • Sands with large particle sizes have large pore channels, which promote migration. [ABSTRACT FROM AUTHOR]
- Published
- 2023
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34. Fluid flow-induced fine particle migration and its effects on gas and water production behavior from gas hydrate reservoir.
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Guan, Dawei, Qu, Aoxing, Wang, Zifei, Lv, Xin, Li, Qingping, Leng, Shudong, Xiao, Bo, Zhang, Lunxiang, Zhao, Jiafei, Yang, Lei, and Song, Yongchen
- Subjects
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METHANE hydrates , *PARTICULATE matter , *WATER-gas , *GAS migration , *GAS reservoirs , *GAS seepage , *GAS hydrates , *RESERVOIRS - Abstract
• Presence of fine particle could block the pores and hinder gas production. • Water content determines the behavior of fine particle aggregation. • Distribution pattern of fine particles directly affects the gas production efficiency. Natural gas hydrates are widely distributed in silty marine sediments containing fine particles less than 75 μm in size. The effects of WC (water content) on the behavior of fine particle migration and their role in gas and water production do not appear well understood. This work found that the WC slightly affected the gas production pattern in uniform sandy reservoirs. Yet upon a mixture of coarse and fine particles, the fine particles would instantly aggregate at the nearby pore throat reducing the reservoir permeability and prolonging the production by more than 3 times. Surprisingly, 16% of the fine particles at the edge and 19% at the middle were found to migrate with the fluid flow upon increasing water content, resulting in a less hindered initial gas production but a following more complete blockage or even production failure. This behavior can be consolidated in the scenario of a sand-kaolin mixture. The findings could provide new knowledge on the particle migration behavior upon gas and especially water production and guide the strategy design on dealing with the sand problem in the field test. [ABSTRACT FROM AUTHOR]
- Published
- 2023
- Full Text
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35. Pyrolytic aerogels with tunable surface groups for efficient methane solidification storage via gas hydrates.
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Shi, Changrui, Wang, Shuai, Liu, Huiquan, Zhang, Lunxiang, Yang, Mingjun, Song, Yongchen, Zhao, Jiafei, and Ling, Zheng
- Subjects
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GAS hydrates , *AEROGELS , *PHASE transitions , *METHANE hydrates , *PYROLYTIC graphite , *GAS storage , *SURFACE enhanced Raman effect , *RAMAN scattering - Abstract
• Aerogels with tunable surface properties significantly promoted hydrate formation. • C O and –OH were found to dominate nucleation and growth of hydrate. • The finely tuned oxygen-containing groups lead to the enhanced kinetics. • Aerogels exhibit high storage capacity and excellent cycling stability. • Aerogels can be prepared in a large scale for hydrate-based applications. Gas hydrate, composed of water molecule cages, is promising for safe and sustainable gas storage with minor energy consumption. However, the practical utilization of hydrate-based technologies is hindered by the sluggish formation kinetics of gas hydrate. Central to the challenge of utilizing hydrate-based gas storage is developing effective promoters and improving the understanding of the complicated interplay between a promoter's structure and chemical composition. Herein, we reported a simple and scalable strategy to produce pyrolytic composite aerogels assembled from vermiculite nanosheets and sodium alginate as efficient promoters for the methane hydrate formation. Benefiting from the high specific surface area and finely tuned surface functional groups, the as-made aerogels significantly improve methane hydrate formation kinetics with high storage capacity and excellent cycling stability. It is found that the phase change process of water to methane hydrate conversion can be controlled by adjusting the content of carbonyl and hydroxyl groups of the as-made aerogels. Raman spectra were used to elucidate the molecular mechanisms for the enhanced methane hydrate formation due to the interaction between oxygen-containing surface functional groups and water molecules close to used aerogels. This work not only provides an effective way to fabricate aerogel-based promoters for methane hydrate formation but also sheds light on the underlying mechanism of the surface composition dependent performance for improving gas hydrate formation. [ABSTRACT FROM AUTHOR]
- Published
- 2023
- Full Text
- View/download PDF
36. CO2 storage behavior via forming hydrate from N2/CO2 gas mixtures in the presence of initial SI CO2 hydrate seeds.
- Author
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Lu, Yi, Wang, Hui, Li, Qingping, Lv, Xin, Ge, Yang, Zhang, Lunxiang, Zhao, Jiafei, Yang, Lei, and Song, Yongchen
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METHANE hydrates , *ATMOSPHERIC carbon dioxide , *GAS mixtures , *CARBON dioxide , *FLUE gases , *FOSSIL fuels - Abstract
Schematic diagram for N 2 /CO 2 gas enrichment process during hydrate growth process. Blue sticks and spheres: N 2 in the gas phase; yellow spheres: CO 2 in the gas phase or hydrate phase; red sticks: hydrate seeds. [Display omitted] • Proper subcooling can improve the hydrate growth rate and final occupancy of CO 2 molecules. • Mass transfer process could impact the hydrate growth rate, with a higher pressure improving the concentrations of N 2 and CO 2 in the free water. • Higher pressure decreased the selectivity of CO 2 for 51262, and lower subcooling assisted CO 2 in entering 51262 cages easily. The climate system is changing and becoming warmer due to the consumption of fossil energy, which results in a large quantity of CO 2 emitted into the atmosphere. The hydrate formation process can encapsulate guest molecules in hydrate cages, enabling a promising storage of CO 2 in the form of hydrate under the seafloor. Here, we performed molecular dynamics (MD) simulations to validate the hydrate-based gas storage method for low-concentration flue gas. The direct phase method was applied at four target pressures to obtain the melting temperature of mixed gas hydrate in the presence of SI hydrate seeds that are fully occupied by CO 2 molecules. Hydrate growth simulations showed that a proper subcooling can improve the hydrate growth rate and final occupancy of CO 2 molecules in newly formed hydrate cages. The mass transfer process could impact the hydrate growth rate, with a higher pressure improving the concentrations of N 2 and CO 2 in the free water. This enhanced the hydrate growth at both 260 K and low subcooling temperatures. The influence of pressure and subcooling on cage selectivity presented a different tendency for CO 2 and N 2. A higher pressure decreased the selectivity of CO 2 for 51262, and lower subcooling assisted CO 2 in entering 51262 cages easily. Interestingly, the CO 2 occupancy at 260 K is larger than that of the simulations at the melting temperature. The results could be of help in revealing the behavior of case filling during hydrate formation from a gas mixture. [ABSTRACT FROM AUTHOR]
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- 2022
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37. Effects of the vertical heterogeneity on the gas production behavior from hydrate reservoirs simulated by the fine sediments from the South China Sea.
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Shi, Kangji, Wang, Zifei, Jia, Yuxin, Li, Qingping, Lv, Xin, Wang, Tian, Zhang, Lunxiang, Liu, Yu, Zhao, Jiafei, Song, Yongchen, and Yang, Lei
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METHANE hydrates , *GAS condensate reservoirs , *GAS distribution , *GAS hydrates , *MARINE sediments , *WATER temperature , *PORE fluids - Abstract
There have been several field tests worldwide to recover natural gas from marine gas hydrate reservoirs. The resulting intrinsic characteristics of the sediments are recognized as the major challenge hindering the large-scale gas production; of particular interest is the heterogeneous spatial distribution of natural gas hydrates in the sediments. Open issues still remain on mimicking the locally varying reservoir and revealing its role in the production process. Here in this work, reservoirs with a heterogeneous distribution of gas hydrates were prepared by controlling the uneven distribution of moisture in the fine natural sediments drilled from the South China Sea; special interest was put in the effects of the well location and depressurization schemes on the gas production performance. The results showed that the production efficiency in the heterogeneous reservoirs was significantly weakened compared with the homogeneous case; this was ascribed to the ununiform distribution of methane hydrates and pore fluids and a resulting locally different energy demand. Consequently, the production behavior showed a strong dependence on the depressurization location. A wellbore arranged in the layer with a high permeability can help improve the gas production efficiency by up to 38.25%. This yet resulted in an uneven temperature distribution; the rapid gas production and methane hydrate dissociation decreased the reservoir temperature to −3.33 °C. Further applying a cycling and step-wise depressurization could raise the minimum reservoir temperature up to 1.12 °C. Whereas, relieving temperature decline only through consuming the sensible heat in the reservoir and the surroundings was found to seriously weaken the gas production rate; an external heat supply was thus suggested in the hydrate-abundant regions for efficient gas production. Our findings expand the understanding of the spatially varying gas production behavior from the vertically heterogeneous hydrate-bearing fine marine sediments and may guide the operation of well location and depressurization schemes for field production in similar reservoirs. [Display omitted] • Heterogeneous hydrate samples were prepared by unevenly distributing the moisture. • Production behavior from the vertically heterogeneous hydrate reservoir was studied. • The optimized wellbore location would increase the production efficiency by 38.25%. • Heat supply was suggested in the hydrate-rich area to compensate the sensible heat. [ABSTRACT FROM AUTHOR]
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- 2022
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38. Dependence of thermal conductivity on the phase transition of gas hydrate in clay sediments.
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Wei, Rupeng, Xia, Yongqiang, Qu, Aoxing, Lv, Xin, Fan, Qi, Zhang, Lunxiang, Zhang, Yi, Zhao, Jiafei, and Yang, Lei
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GAS hydrates , *PHASE transitions , *CLAY , *SEDIMENTS , *METHANE hydrates - Published
- 2022
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39. Atomistic insights into the performance of thermodynamic inhibitors in the nucleation of methane hydrate.
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Lu, Yi, Yuan, Chengyang, Wang, Hui, Yang, Lei, Zhang, Lunxiang, Zhao, Jiafei, and Song, Yongchen
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METHANE hydrates , *SMALL molecules , *ETHYLENE glycol , *NUCLEATION , *MOLECULAR interactions , *NATURAL gas pipelines , *MOLECULAR clusters - Abstract
Figure TOC Comparison of methane hydrate nucleation process (a) without or (b) with EG molecules. Critical nucleus size increase under the influence of Thermodynamic hydrate inhibitors. [Display omitted] • Hydrophobic groups from the alcohols could approach the initial hydrate cages and destroy initial clusters. • The –OH groups were observed to form hydrogen bonds with the cage clusters and even initiate a new hydrate cage. • Alcohols can increase the critical nucleus size of gas hydrate. Thermodynamic inhibitors are intensively used in oil and gas pipelines to modify the formation conditions of gas hydrate, preventing the blockage of pipelines. However, their kinetic performance in hydrate nucleation is largely unclear. Herein, the molecular interactions of the small molecules of ethylene glycol and methanol with hydrate clusters were investigated. It was found that the hydrophobic groups from the glycols could approach the initial hydrate cages, thereby constricting the regional distribution of adjacent water molecules; thus, they functioned in the same way as the guest molecules that transiently helped to stabilize the water framework. However, these glycols would eventually dissolve into the solution to stay at the water/nanobubble interface; this would consequently destroy the initial cages upon losing the constraint from the surrounding hydrophobic molecules. In addition, the –OH groups were observed to form hydrogen bonds with the cage clusters and even initiate a new hydrate cage; however, they cannot stably reside there due to different atom coordination. Notably, these glycols can increase the critical nucleus size, which is considered the intrinsic mechanism of thermodynamic inhibition. Our results provide atomistic insights into the performance of glycols in the kinetic nucleation of gas hydrates and can help understand the interactions between guest and host molecules in the presence of hydrophobic and hydrophilic functional groups. [ABSTRACT FROM AUTHOR]
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- 2022
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40. Synthesis and application of magnetically recyclable nanoparticles as hydrate inhibitors.
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Zhao, Yang, Liu, Yanzhen, Dong, Hongsheng, Chen, Chong, Zhang, Tianxiang, Yang, Lei, Zhang, Lunxiang, Liu, Yu, Song, Yongchen, and Zhao, Jiafei
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IRON oxide nanoparticles , *METHANE hydrates , *MAGNETIC separation - Abstract
[Display omitted] • A magnetically recoverable nanoparticle inhibitor was synthesized. • The induction time with inhibitors was 3 times longer than pure water case. • The inhibitors exhibit good cycling performance and magnetic separation efficiency. • The inhibition mechanism based on in-situ Raman was proposed. Current schemes dealing with hydrate blockage problems in gas pipelines suffer a high dosage of inhibitors and thus are associated with a significant risk of environmental damage. Overcoming these issues requires the development of novel recoverable inhibitors with persistent cycle performance. In this work, a new approach involving coating poly(vinylcaprolactam) (PVCap) and poly(vinylpyrrolidone) (PVP) onto the surface of γ-methacryloxypropyltrimethoxy silane (MPS)-modified Fe 3 O 4 nanoparticles was proposed; this procedure enables the magnetic recovery of the inhibitory particles. It was found that the onset time of hydrate formation was extended 3 times compared to pure water with the help of the synthesized inhibitors showing better performance than commercial inhibitors. Excellent magnetic separation from sandy matrices in solution was achieved with a recovery efficiency of 86%. This was followed by a good cycle performance: the induction time remained still over 2 times longer than the pure water case after 5 cycles of recovery. The in-situ Raman spectra revealed that the recyclable inhibitors functioned through disturbing the construction of the large cages; a resulting mechanism was proposed with nanoparticles isolating the early hydrate patches preventing their further explosive bulk growth. In addition, the simple synthesis method makes it possible to coat various polymer inhibitors onto recovery particles. The results indicate that magnetically recovering the inhibitory particles and reusing them to hinder hydrate generation could be an alternative method to tackle the environmental and economic problems associated with current flow assurance procedures. [ABSTRACT FROM AUTHOR]
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- 2022
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41. Fast nucleation of methane hydrate enhanced by bulk MNBs combined with analysis of memory effect.
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Cheng, Chuanxiao, Hu, Shen, Zhang, Zhiping, Jin, Tingxiang, Qi, Tian, Zhu, Shiquan, Zhang, Jun, Liu, Jianxiu, Wang, Jiaqi, and Zhang, Lunxiang
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METHANE hydrates , *RATE of nucleation , *MICROBUBBLES , *PHASE equilibrium , *DISCONTINUOUS precipitation , *GAS-liquid interfaces , *NUCLEATION , *PHASE transitions - Abstract
• The micro-nano bubbles shorten the induction period of methane hydrate nucleation. • The nucleation rate of methane hydrate increased by 4.73 times. • Micro-nano bubbles of guest molecules with milder phase equilibrium conditions have more advantages in promoting methane hydrate nucleation. • The concentration of micro-nano bubbles affects the memory effect of hydrate, and the memory effect disappears when the concentration of micro bubbles decreases by 73.5%. Hydrate technology has significant application potential in the fields of phase-change cold storage, seawater desalination, gas separation, etc. The key factors influencing the development of hydrate technology are the reduction in the induction time and the promotion of nucleation and growth of hydrates. Micro-nano bubbles (MNBs) can significantly increase the nucleation rate of hydrates owing to their advantages of increasing the gas–liquid interface, enhancing mass transfer, and providing sites for nucleation. In this study, a visualization experimental system for in situ hydrate formation promoted by MNBs was developed. The induction time and the nucleation rate of methane hydrate under the action of MNBs, and the influence mechanism of different guest molecule bulk MNBs on the induction time of methane hydrate were studied. Furthermore, the effects of hydrate formation with injection of bulk MNBs and the reformation with dissociation solution were compared, and the mechanism of bulk MNBs on the memory effect of hydrates was analyzed. The results show that under the action of bulk MNBs (size 80–240 nm), the average induction time of hydrate nucleation is reduced by 80.9%, and the average nucleation rate is increased by 4.73 times. At the same time, by comparing the bulk MNBs of different guest molecules (CH 4 , N 2 , CO 2 , R134a), it was found that R134a has relatively mild phase equilibrium conditions and is easier to nucleate, which has an enhancement effect on the nucleation of methane hydrate. Finally, compared with the concentration changes of bulk MNBs in the dissociated solution, it was found that bulk MNBs play an important role in the hydrate memory effect. When the concentration of bulk MNBs in the dissociated solution decreases by 73.5%, the memory effect disappears, which quantitatively proves the mechanisms of bulk MNBs on memory effects. [ABSTRACT FROM AUTHOR]
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- 2022
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42. Characterizing Mass-Transfer mechanism during gas hydrate formation from water droplets.
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Liang, Huiyong, Guan, Dawei, Shi, Kangji, Yang, Lei, Zhang, Lunxiang, Zhao, Jiafei, and Song, Yongchen
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METHANE hydrates , *GAS hydrates , *COMPUTED tomography , *PORE water , *DIFFUSION coefficients , *THERMAL diffusivity , *LEAD in water - Abstract
• 3D morphologies and time-dependent parameters of the hydrate shell are obtained. • Water is more mobile than gas in hydrates in the diffusion-controlled growth stage. • Protrusions growth on the outer surface of a hydrate shell is due to water permeation. • Effective diffusion coefficients of gas and water in hydrate are determined. Understanding the transport properties of water and guest molecules in dense hydrate structures is pivotal in controlling their formation and stability; this is nevertheless hindered by challenges in characterizing the time-varying diffusion and permeation process. This paper reports experimental results on the mass-transfer characteristics of water and guest molecules across hydrate shells during their formation from water droplets. The time-dependent 3D morphologies and parameters of hydrate shells were in-situ obtained via X-ray computed tomography to reveal the transport mechanism in hydrates. It was found that in the mass-transfer-limited stage, hydrate growth occurred primarily at the hydrate-gas interface, indicating a more mobile characteristic of water molecules in those hydrate shells than gas. The resulting outward permeation of water led to the growth of hydrate protrusions on the outer surface of the hydrate shell, suggesting a transition of the water transport schema through the hydrate shell from diffusion to permeation. Consequently, a diffusion-based shell growth model was developed to quantify the diffusivity of gas and water molecules in hydrates. Combining the measurements in the temperature range of 275.15–283.15 K, the effective diffusion coefficient of gas through the hydrates was estimated to be in the range of 1.34 × 10−14 − 1.90 × 10−13 m2/s, with that of interstitial water in the range of 2.87 × 10−12 − 3.83 × 10−11 m2/s. These results are of fundamental value in developing an improved understanding of the kinetics of hydrate formation from gas-water interfaces, which is essential in the optimization of hydrate-based techniques. [ABSTRACT FROM AUTHOR]
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- 2022
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43. Pressure oscillation controlled CH4/CO2 replacement in methane hydrates: CH4 recovery, CO2 storage, and their characteristics.
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Sun, Lingjie, Wang, Tian, Dong, Bo, Li, Man, Yang, Lei, Dong, Hongsheng, Zhang, Lunxiang, Zhao, Jiafei, and Song, Yongchen
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METHANE hydrates , *PRESSURE control , *GAS hydrates , *METHANE , *CARBON dioxide , *DEBYE temperatures - Abstract
Pressure oscillation controlled CH 4 /CO 2 replacement in methane hydrates to enhance CH 4 recovery and CO 2 storage. [Display omitted] • The oscillated pressure control is proposed to enhance CH 4 /CO 2 replacement. • Inner replacement cause CH 4 hydrate decomposition and mixed hydrate regeneration. • Optimized depressurization is crucial to improve CH 4 production and CO 2 storage. The recovery of CH 4 from natural gas hydrates via CH 4 /CO 2 replacement is a highly attractive method for achieving the recovery of CH 4 and storing CO 2. However, although extensive simulation and experimental studies have been conducted, applying CH 4 /CO 2 replacement is currently hampered by a lack of in-depth understanding about the replacement mechanism and the insufficient replacement efficiency and rate achieved. Therefore, to enhance CH 4 recovery and CO 2 storage, we propose a method that uses pressure oscillation during CH 4 /CO 2 replacement. The effects of depressurization pressure, depressurization time, and depressurization frequencies were analyzed in this study. The characteristics of pressure and temperature were analyzed during the depressurization process, and the decomposition and regeneration of hydrates relating to the oscillation pressure were observed on a macro level. The results show that this newly proposed combined method effectively improves CH 4 /CO 2 replacement, and the maximum amounts of CH 4 recovered and the CO 2 storage efficiency are nearly double than those achieved without pressure oscillation. CH 4 /CO 2 replacement is promoted by the pressure oscillation mechanism by breaking the balance of the hydrate layer, which results in the dissociation of CH 4 hydrates and finally forms a CO 2 /CH 4 mixed hydrate layer with free water. The results of this study provide a valuable method that can be used to enhance CH 4 recovery and CO 2 sequestration. [ABSTRACT FROM AUTHOR]
- Published
- 2021
- Full Text
- View/download PDF
44. Understanding the inhibition performance of kinetic hydrate inhibitors in nanoclay systems.
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Liu, Yanzhen, Zhao, Yang, Jia, Yuxin, Zhang, Lunxiang, Yang, Lei, and Zhao, Jiafei
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NATURAL gas pipelines , *SURFACE charges , *SURFACE potential , *PARTICULATE matter , *METHANE hydrates , *GAS hydrates - Abstract
[Display omitted] • Inhibitors are used to prevent gas hydrates from clogging pipelines. • Effects of clay particles on polyvinylcaprolactam hydrate inhibition were studied. • Clay particles adsorbed the inhibitor, and the particle surface potential changed. • In the presence of clay particles, the inhibitory effects were weakened. Kinetic hydrate inhibitors are widely used during upstream activities in the oil industry to prevent gas hydrates from clogging pipelines. Yet their performance in the pipelines transporting natural gas from marine environment is largely veiled where clay particles and their adsorbability are generally present. In this study, it was found that the fine clay particles from a hydrate rich area in the South China Sea are majorly composed of layered silicate with a negative surface charge. Consequently, the clay particles would adsorb the inhibitor through Van der Waals attractions and ion–dipole interactions. The resulting weakened surface potential of the particles would trigger an aggregation of the clays together with the inhibitors attached on their surfaces. This will thereby result in less active components in the solution, significantly weakening the inhibition effect. It is therefore suggested that the effects of clay-rich conditions on the performance of the inhibitors should be carefully considered for an efficient dosage in the marine environments. [ABSTRACT FROM AUTHOR]
- Published
- 2021
- Full Text
- View/download PDF
45. An improved model for predicting the critical velocity in the removal of hydrate particles from solid surfaces.
- Author
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Liu, Zheyuan, Chen, Bingbing, Lang, Chen, Zhang, Lunxiang, Yang, Lei, and Guo, Xianwei
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CRITICAL velocity , *SOLIDS , *METHANE hydrates - Abstract
[Display omitted] • An improved model for hydrate particles removal from surface is proposed. • Hydrate particle diameter influencing the critical velocity than the initial liquid bridge volume. • Hydrate particles decomposition happening in the removal process. Understanding the critical velocity at which hydrate particles can be removed from a solid surface is crucial for flow assurance issues. An improved model is proposed to predict the critical velocity in hydrate particle removal process by considering a deformed liquid bridge. In situ experiments were performed for validation, and it was observed that hydrate particle decomposition occurred during the removal process. The particle diameter was determined to be a more dominant factor influencing the critical velocity than the initial liquid bridge volume. The resulting confidence level was 95% within a 30% error, showing its robust capability for engineering applications. [ABSTRACT FROM AUTHOR]
- Published
- 2021
- Full Text
- View/download PDF
46. Potential applications based on the formation and dissociation of gas hydrates.
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Dong, Hongsheng, Wang, Jiaqi, Xie, Zhuoxue, Wang, Bin, Zhang, Lunxiang, and Shi, Quan
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METHANE hydrates , *GAS hydrates , *SEPARATION of gases , *WASTEWATER treatment , *GAS storage , *INDUSTRIAL capacity - Abstract
Owing to the substantial deposits and widespread applications of gas hydrates, research in gas hydrates has been increasing in recent decades. The inherent excellent physiochemical properties of gas hydrates determine the prominent roles that they play in a wide range of areas including energy and environment. Particularly, gas hydrates represent an attractive way for gas storage, gas separation, wastewater treatment, and other fields. The review summarizes the potential applications based on hydrate formation and dissociation. Challenges, limitation, and future visions of every application are discussed. The whole purpose of this paper is to give readers with a comprehensive understand of hydrate-based applications, stimulate further innovation application research using hydrate formation and dissociation, and give some useful guidance for their industrialization. • The excellent physiochemical properties of gas hydrates determine their great potential in industrial applications. • The potential applications including gas storage, gas separation, wastewater treatment, and other fields are reviewed. • Challenges, limitation, and future perspectives of each field are discussed. [ABSTRACT FROM AUTHOR]
- Published
- 2021
- Full Text
- View/download PDF
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