Your search keyword '"Storage capacity"' showing total 294 results

1. Assessment of core samples through the analysis of CT measurements and its implications for CO2 sequestration potential in a Hungarian depleted oil field

Author

Veres, Gábor Pál, Földes, Tamás, and Szunyog, István

Published

2024

2. Hydrogen injection and withdrawal performance in depleted gas reservoirs.

Author

Muhammed, Nasiru Salahu, Haq, Bashirul, Al Shehri, Dhafer, Badmus, Suaibu O., Adebayo, Abdulrauf R., and Mahmoud, Mohamed

Abstract

Residual gas trapping in porous media is a key indicator of hydrogen storage and recovery performance. The injection scheme of cushion and working gases helps maintain pressure and reduce losses. However, this information is limited in the literature. This work explores core flooding experiments (using electrical resistivity for in-situ saturation monitoring) on Bandera Grey sandstones under reservoir conditions (42 °C, 1400 psi, and 5 wt% NaCl), investigating cushion gas type and injection rate effects on storage and recovery performance. Results indicate that CO 2 injection ahead of hydrogen yielded the highest storage capacity with S gi = 0.255 , then CH 4 : S gi = 0.226 and finally, N 2 : S gi = 0.216. At lower injection rates (0.2–0.6 cc/min), CH 4 cushion gas exhibited the highest recovery (42%), whereas at higher injection rates (1.2–10 cc/min), CO 2 resulted in the highest, with 33%. These findings emphasize cushion gas's role in enhancing hydrogen storage capacity and production efficiency in depleted gas reservoirs. • Injecting CO 2 cushion gas yielded highest storage capacity compared to CH 4 and N 2. • CH 4 cushion achieved 42.0% recovery at lower injection rate (0.2–0.6 cc/min). • At higher injection rate (1.2–10 cc/min), CO 2 recorded the highest recovery (33%). • CH 4 cushion is recommended for tight samples while CO 2 for more porous rock. • Findings present the crucial role of cushion gas in enhancing H 2 storage and recovery. [ABSTRACT FROM AUTHOR]

Published

2024

3. Capacity assessment and economic analysis of geologic storage of hydrogen in hydrocarbon basins: A South Asian perspective.

Author

Guha Roy, Debanjan, Goyal, Jai, and Talukdar, Mayukh

Subjects

*GREEN fuels, *HYDROGEN storage, *UNDERGROUND storage, *HYDROGEN economy, ECONOMIC conditions in Asia

Abstract

The underground hydrogen storage represents a promising long-term, large-volume solution for hydrogen and hydrogen-methane blends, which is crucial for the anticipated "hydrogen economy" in South Asia. The suitability of any storage location hinges on its capacity and the associated costs of storage. This study provides a comparative analysis of the storage capacities for green hydrogen across fifty-nine porous geological reservoirs in India, Bangladesh, Pakistan, and Sri Lanka— the four major South Asian economies. The levelized cost of hydrogen storage (LCHS) was calculated for pure hydrogen storage in these basins. Additionally, the storage capacities of the five largest basins from India, Bangladesh, and Pakistan were evaluated for hydrogen-methane blends at 25%, 50%, and 75% concentrations. The findings indicate that South Asia's total pure hydrogen storage capacity is 29,799.43 TWh, with India contributing over 75%. Furthermore, hydrogen-methane blends were found to store more energy than pure hydrogen, with a 75% hydrogen blend storing over 65% more energy in the same basin. The primary cost factors for hydrogen storage in South Asia are compressor costs, followed by the costs of working gas and well construction. Under the parameters considered, the LCHS in India, Bangladesh, Pakistan, and Sri Lanka are $2.01, $1.28, $1.2, and $2 per kilogram of injected hydrogen. • 59 porous reservoirs of South Asian countries were evaluated for hydrogen storage. • Pure hydrogen storage capacity of South Asia is 29,799.43 TWh. • Hydrogen-methane blends store more energy than pure hydrogen in the same volume. • In South Asia, compressors have the highest capital cost, and working gas the lowest. • The LCHS: India $2.75/kg, Bangladesh $2.03/kg, Pakistan $1.95/kg, Sri Lanka $2.74/kg. [ABSTRACT FROM AUTHOR]

Published

2024

4. The Distributed Xin'anjiang Model Incorporating the Analytic Solution of the Storage Capacity Under Unsteady-State Conditions.

Author

Song, Qifeng, Chen, Xi, and Zhang, Zhicai

Subjects

EVAPORATIVE power, SOIL moisture, SOIL dynamics, ABSOLUTE value, HYDROLOGIC models

Abstract

Developing a functional linkage between hydrological variables and easily accessible terrain and soil information is a novel concept for distributed hydrological models. This approach aims to address limitations imposed by data scarcity and high computational demands. The model hypothesizes that the relationship between the evaporation flux and the absolute value of the matric potential follows a power exponential pattern. Analytic solutions for the groundwater depth, the evaporation capacity, and the storage capacity are derived with respect to the topographic index, considering the relationship between the groundwater depth and the topographic index and the influence of setting off. Subsequently, a distributed Xin'anjiang Model using the analytic solution of the storage capacity under unsteady-state conditions is constructed. This new model is employed to simulate soil moisture and discharge in the Tarrawarra Watershed. The simulation results for soil moisture and discharge are compared with those from the Storage Capacity Model and the DHSVM. Additionally, the computational speeds of all three models are compared. The findings indicate that the simulation accuracy of the new model for soil moisture and discharge surpasses that of the Storage Capacity Model and the DHSVM. Meanwhile, the computational speed of the new model is significantly faster than the DHSVM and slightly slower than the Storage Capacity Model. It offers a balance between computational efficiency, predictive accuracy, and physical mechanism representation. The data requirements of the new model are minimal and easy to procure, and it requires less computational effort. Moreover, it accurately captures the spatial and temporal dynamics of soil moisture and the discharge process of the watershed. [ABSTRACT FROM AUTHOR]

Published

2024

5. ReZNS: Energy and Performance-Optimal Mapping Mechanism for ZNS SSD.

Author

Lee, Chanyong, Lee, Sangheon, Moon, Gyupin, Kim, Hyunwoo, An, Donghyeok, and Kang, Donghyun

Subjects

ENERGY consumption, RESEARCH personnel, HOUSEHOLD electronics, ENGINEERS, STORAGE

Abstract

Today, energy and performance efficiency have become a crucial factor in modern computing environments, such as high-end mobile devices, desktops, and enterprise servers, because data volumes in cloud datacenters increase exponentially. Unfortunately, many researchers and engineers neglect the power consumption and internal performance incurred by storage devices. In this paper, we present a renewable-zoned namespace (ReZNS), an energy and performance-optimal mechanism based on emerging ZNS SSDs. Specifically, ReZNS recycles the remaining capacity of zones that are no longer used by adding a renewable concept into the mapping mechanism. We implemented a prototype of ReZNS based on NVMeVirt and performed comprehensive experiments with diverse workloads from synthetic to real-world workloads to quantitatively confirm power and performance benefits. Our evaluation results present that ReZNS improves overall performance by up to 60% and the total power consumption by up to 3% relative to the baseline on ZNS SSD. We believe ReZNS creates new opportunities to prolong the lifespan of various consumer electronics, such as TV, AV, and mobile devices, because storage devices play a crucial role in their replacement cycle. [ABSTRACT FROM AUTHOR]

Published

2024

6. Typical Case Studies and Classification with Evaluation of Carbon Dioxide Geological Sequestration in Saline Aquifers.

Author

Ping, Lihua, Wang, Huijun, Tian, Yuchen, Zhang, Helong, Wu, Xiuping, Chen, Shiheng, Liu, Yinghai, Liu, Yanzhi, Liu, Shiqi, Sang, Shuxun, and Zheng, Sijian

Subjects

GEOLOGICAL carbon sequestration, CARBON sequestration, CARBON offsetting, NATURAL gas prospecting, PETROLEUM prospecting

Abstract

To achieve carbon neutrality in China's fossil energy sector, saline aquifer CO2 geological storage has become a critical strategy. As research into carbon reduction and storage potential evaluation advances across various geological scales, the need arises for consolidating key CO2 storage cases and establishing a standardized classification system and evaluation methodology. This paper provides a comprehensive review of notable CO2 storage projects in saline aquifers, covering aspects such as project overviews, structural and reservoir characteristics, caprock integrity, and seismic monitoring protocols. Drawing on insights from mineral and oil and gas exploration, as well as international methods, this paper outlines the stages and potential levels of saline aquifer storage in China. It proposes an evaluation framework with formulas and reference values for key coefficients. The study includes successful global projects, such as Sleipner and Snøhvit in Norway, In Salah in Algeria, and Shenhua in China's Ordos Basin, which provide valuable insights for long-term carbon capture and storage (CCS). By examining geological characteristics, injection, and monitoring protocols in these projects, this paper analyzes how geological features impact CO2 storage outcomes. For example, the Sleipner project's success is linked to its straightforward structure, favorable reservoir properties, and stable caprock, while Snøhvit illustrates diverse structural suitability, and In Salah demonstrates the influence of fractures on storage efficacy. CO2 storage activities are segmented into four stages—survey, investigation, exploration, and injection—and are further categorized by storage potential: geological, technical, techno-economic, and engineering capacities. This study also presents evaluation levels (prediction, control, technically recoverable, and engineering) that support effective reservoir selection, potential classification, and calculations considering factors like reservoir stability and sealing efficacy. Depending on application needs, volumetric or mechanistic methods are recommended, with precise determination of geological, displacement, and cost coefficients. For China, a dynamic evaluation mechanism characterized by multi-scale, tiered approaches and increasing precision over time is essential for robust storage potential assessment. The levels and methods outlined here serve as a scientific foundation for regional and stage-based comparisons, guiding engineering approvals and underground space management. To align with practical engineering demands, ongoing innovation through laboratory experiments, simulations, and field practice is crucial, supporting continual refinement of formulas and key parameter determinations. [ABSTRACT FROM AUTHOR]

Published

2024

7. Valence Engineering Boosts Kinetics and Storage Capacity of Layered Double Hydroxides for Aqueous Magnesium‐Ion Batteries.

Author

Kou, Weizhi, Fang, Zhitang, Ding, Hongzhi, Luo, Wei, Liu, Cong, Peng, Luming, Guo, Xuefeng, Ding, Weiping, and Hou, Wenhua

Subjects

*LAYERED double hydroxides, *DIFFUSION kinetics, *PHOTOELECTRON spectroscopy, *DENSITY functional theory, *ORBITAL hybridization, *MAGNESIUM ions

Abstract

The kinetics and storage‐capacity of NiCoMg‐ternary layered double hydroxide (NiCoMg‐LDH) are successfully boosted by valence engineering. As the cathode for aqueous magnesium‐ion batteries (AMIBs), the assembled NiCoMg‐LDH//active carbon (AC) delivers a high specific discharge capacity (121.0 mAh·g−1 at 0.2 A·g−1), long‐term cycling stability (85% capacity retention after 2000 cycles at 1.0 A·g−1) and an excellent performance at −30 °C. Moreover, NiCoMg‐LDH//perylenediimide (PTCDI) is assembled, achieving a high specific discharge capacity and long‐term cycling stability. X‐ray absorption spectra (XAS)/X‐ray photoelectron spectroscopy (XPS) analyses and Density functional theory (DFT) calculations disclose that the electrons are redistributed due to the 3d orbital overlap of Co/Ni atoms in NiCoMg‐LDH, which obviously reduces the valence states of Co/Ni atoms, enhances Mg─O bond strength and degree of hybridization of Co/Ni 3d and O 2p orbitals. Hence, the electronic conductivity is significantly enhanced and the electrostatic repulsion between Mg2+ and host layers is greatly reduced, giving rise to the improved diffusion kinetics and storage‐capacity of Mg2+. Furthermore, in situ Raman/X‐ray diffraction (XRD) and ex situ XPS reveal corresponding energy‐storage mechanism. This paper not only demonstrates the feasibility of LDHs as cathode for AMIBs, but also offers a new modification method of valence engineering for high‐performance electrode materials. [ABSTRACT FROM AUTHOR]

Published

2024

8. CCS: Chancen und Risiken einer umstrittenen Technologie.

Author

Ott, Holger and Kulich, Jakob

Abstract

Copyright of BHM Berg- und Hüttenmännische Monatshefte is the property of Springer Nature and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2024

9. Suitability Assessment and Optimization of Small Dams and Reservoirs in Northern Ghana.

Author

Umukiza, Etienne, Abagale, Felix K., Apusiga Adongo, Thomas, and Petroselli, Andrea

Subjects

ANALYTIC hierarchy process, ENVIRONMENTAL impact analysis, GEOGRAPHIC information systems, ARID regions, WATER storage

Abstract

Water shortages, exacerbated by erratic rainfall, climate change, and population growth, pose significant challenges globally, particularly in semi-arid regions like northern Ghana. Despite the construction of numerous small dams in the region that were intended to provide reliable water for domestic and irrigation purposes, critical water issues persist during dry periods. Key drivers in this failure are attributed to the lack of studies and/or the number of inadequate studies on suitable dam siting. This study focused on assessing the sites of selected small dams in northern Ghana, employing various methods such as stream order analysis and the Analytic Hierarchy Process within a Geographic Information System framework. Results showed that many existing dams are poorly sited, with over half located far from major stream networks, resulting in drying out during the dry season and failing to meet sustainable water storage standards. This study proposed new dam locations that would allow achieving a significant increase in storage capacities from 30% to 60%. These results highlight the necessity for decision-makers to adopt research-based approaches to address water shortages effectively, balancing agricultural, domestic, economic, and environmental needs. Future research should integrate climate change considerations, long-term monitoring, environmental impact assessments, and advanced decision-making techniques such as machine learning. [ABSTRACT FROM AUTHOR]

Published

2024

10. Development of Polyvinyl Alcohol Hydrogels for Controlled Glucose Release in Biomedical Applications.

Author

Quispe-Siccha, Rosa M., Medina-Sandoval, Osvaldo I., Estrada-Tinoco, Abraham, Pedroza-Pérez, Jorge A., Martínez-Tovar, Adolfo, Olarte-Carrillo, Irma, Cerón-Maldonado, Rafael, Reding-Bernal, Arturo, and López-Alvarenga, Juan C.

Subjects

CYTOCOMPATIBILITY, POLYVINYL alcohol, MOLECULAR weights, THERMAL resistance, HEAT capacity, HYDROGELS

Abstract

Polyvinyl alcohol (PVA) hydrogels have a wide range of applications in the pharmaceutical and biomedicine fields due to their exceptional biophysical properties. The study focuses on preparing and characterizing capsule-shaped PVA hydrogels to enhance their biocompatibility and porosity for controlled glucose release and cell proliferation. The hydrogels were prepared using different concentrations (Cs) and molecular weights (MWs) of PVA, with two different lengths, A (10 mm) and B (20 mm), to control glucose release over 60 min. The preparation process involved PVA gel preparation and PVA hydrogel formation. A total of 500 µL of glucose was injected into all dehydrated hydrogels in groups A and B. Glucose release was studied by immersing the hydrogels in saline at 37 °C with stirring at 500 rpm. The SUP-B15 cell line was grown in six A1 hydrogels for biocompatibility testing. The results indicate that all hydrogels remained stable at 37 °C without degrading. Those with a higher C and MW exhibited a denser and less porous structure, lower glucose storage capacity, and higher elongation at break. Significant differences in glucose release, diffusion speed, and flux were observed, which were more evident in A1 > A4, B1 > B4, and B1 > A1 over 60 min. A1 and B1 had higher values because their higher porosity distribution allowed glucose to diffuse more easily. B1, being larger, has more glucose due to its increased length. The cell growth response and viability at 48 h in contact with the hydrogels was similar to that of the control (4.5 × 105 cells/mL, 98.5% vs. 4.8 × 105 cells/mL, 99.7% viability), thus demonstrating biocompatibility. The hydrogels effectively released glucose over 60 min, with variations based on porosity, C, MW, and length, and demonstrated good biocompatibility with the cell line. [ABSTRACT FROM AUTHOR]

Published

2024

11. The effect of functional ingredients on the quality of the curd product and its storage capacity

Author

Pakusina A. P., Zakharova L. M., Pashina L. L., Babukhadiya K. R., and Shkolnikov P. N.

Subjects

functional ingredients, zosterin, honeysuckle, cottage cheese product, storage capacity, функциональные ингредиенты, зостерин, жимолость, творожный продукт, хранимоспособность, General Works

Abstract

The solution to the problem of rationalizing the nutrition of the population, reducing the negative impact on the human body of harmful factors (physical, chemical) of the external environment is possible by creating functional products that include proteins, vitamins, antioxidants, pectins and other essential nutrients, the deficiency of which has been noted by biomedical research. Based on theoretical and experimental studies, the components were selected including functional ingredients: zosterin – a natural polysaccharide and vegetable filler – honeysuckle berry juice. Low-fat cottage cheese, which includes proteins, minerals, sulfur-containing compounds and other substances, was chosen as the basis of the functional product. As a result of the conducted research, technological approaches were formed and the component composition of the curd product with zosterin and berry juice was justified. The ratios of zosterol and honeysuckle juice in relation to the mass of cottage cheese have been established, ensuring proper technological and preventive effect. The organoleptic, structural-mechanical, physico-chemical parameters of the curd product have been studied. The nutritional and energy value is calculated. The developed curd product has an increased nutritional value, it contains biologically important components – vitamins, mineral salts, polyphenolic substances, pectins. It has a high digestibility due to the homogenization of all components and complementary organoleptics: pleasant aroma and taste, homogeneous, delicate consistency, attractive external characteristics. The effect of zosterol and berry juice on the quality of the curd product during storage has been studied. It has been proven that the introduction of zosterol and berry juice allows you to slow down undesirable processes, and, consequently, extend the shelf life of the product.

Published

2024

12. تخمین نرخ رسوبگذاری و ظرفیت ذخیرهسازی مخزن سدها با استفاده از تصاویر ماهوارهای.

Author

حامد فیضآبادی, عبدالرضا ظهیری, and خلیل قربانی

Abstract

Reservoirs are very important for storing rainwater and floods, and water shortage management. In nearly all reservoirs, storage capacity is steadily lost due to trapping and accumulation of sediment. Sediment deposition in water reservoirs has major implications for storage capacity, reservoir lifetime and water quality. The present study aimed to evaluate the temporal dynamics of water stored and sedimentation rate in a reservoir using remote sensing data. For this purpose, the study was carried out in O. H. Ivie reservoir located in the America country. The techniques used to carry out this study have been pre-processing of Landsat 8 images, modeling and identifying water pixels using MNDWI index, evaluating reservoir capacity, and compression of results with recent bathymetric survey data to assessment sedimentation rate. According to the results, the average errors of computing the volume of water stored in the reservoir was about 9%. Based on this, the storage capacity of O. H. Ivie reservoir has decreased from 695 million cubic meters at the beginning of operation (1991) to 472 million cubic meters in 2019. The results showed that the lost storage capacity of the reservoir due to sedimentation is about 32% of the original volume and the annual sedimentation rate is 1.4%. Also, by evaluating the obtained results, the average height of sediment deposited in the reservoir between 2004 and 2019 was estimated to be about 9 meters. This research confirmed that remote sensing can estimate storage capacity and sedimentation rate in the reservoir with minimal cost and time. [ABSTRACT FROM AUTHOR]

Published

2024

13. Two-dimensional AsP3 monolayer as an efficient anode material for Li-Ion batteries: a theoretical perspective.

Author

Zyane, Mohamed Said, Rghioui, Hamza, Ait Tamerd, Mohamed, Boujibar, Ouassim, Achahbar, Abdelfattah, Marjaoui, Adil, and Zanouni, Mohamed

Subjects

*DIFFUSION barriers, *DENSITY functional theory, *ELECTRIC vehicle charging stations, *STRUCTURAL stability, *ELECTRONIC equipment

Abstract

Enhancing the rate performance of lithium-ion batteries (LIBs) is crucial to developing electronic devices. In light of the growing demand for consumer electronics, researchers have developed two-dimensional (2D) materials to achieve elevated performance levels. In this study, we applied the density functional theory (DFT) approach to assess the suitability of the novel 2D triphosphide AsP3 as a potential anode candidate for LIBs. The AsP3 monolayer exhibits high cohesive energy, outstanding structural stability, and impressive electronic properties. Our finding demonstrates that the valley site As2 is the optimal adsorption site for the Li atom on the AsP3 monolayer, with a high negative adsorption energy of -2.42 eV and considerable charge transfer. Moreover, the transition in behavior from semiconductor to metallic after the adsorption of Li on the substrate makes the AsP3 appropriate as an anode material of LIBs. Meanwhile, the AsP3 monolayer features a high theoretical storage capacity of around 638.71 mAhg− 1, exceeding that of commercial graphite and numerous other 2D materials. The diffusion barrier energy of the Li atom on the AsP3 monolayer is 0.29 eV, which is quite lower than that of many other 2D materials. This indicates rapid charge and discharge processes and underscores the high performance of the AsP3 monolayer. All these results demonstrate that the AsP3 monolayer could be a promising candidate for anode material in LIBs, paving the way for feature experimental studies in the development of battery technology. [ABSTRACT FROM AUTHOR]

Published

2024

14. Towards a dynamic effective drainage area map for the Canadian Prairie: Sensitivity of contributing area to wetland storage capacity.

Author

Bacsu, Stephanie and Spence, Christopher

Subjects

WATERSHEDS, STREAMFLOW, PRAIRIES, RUNOFF, EXTRAPOLATION, WETLANDS

Abstract

Copyright of Canadian Water Resources Journal / Revue Canadienne des Ressources Hydriques is the property of Taylor & Francis Ltd and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2024

15. Shrimp Depots: Quality Management Practices and Strategic Approaches in Bangladesh.

Author

Alam, S. M. Nazmul

Abstract

This study provides valuable insights into the sustainability of shrimp farming and supply chain practices in Bangladesh by focusing on quality management practices in shrimp depots across Paikgacha, Dacope, and Chokoria locations. Using qualitative interviews, surveys, and on-site observations, this study evaluates quality control measures focusing on procurement, processing, storage, product management, and record maintenance in shrimp depots. The depots typically maintained separate storage for shrimp and ice, with significant variability in capacity. The quality of the procured shrimp was assessed through visual and tactile inspections, with common contaminants including 'push' (adulterated shrimp), wood, and metal. The competition among depots was intense and driven by the need to secure stable shrimp supplies amid frequent shortages. The hygiene and sanitary conditions varied, with Paikgacha generally showing higher compliance with standards compared to Dacope and Chokoria. The record-keeping practices for shrimp sources were inconsistent, with most depots being unable to trace the exact origins of the purchased shrimp. The study reveals the complex dynamics of shrimp quality management practices in the depots. It highlights areas for improvement that can foster more sustainable and responsible practices in the shrimp industry. These improvements benefit the environment, the economy, and society at large, ensuring product quality and market competitiveness. [ABSTRACT FROM AUTHOR]

Published

2024

16. A multi-collaborative technique for assessing the reservoir sedimentation with futuristic capacity prediction using ANN model.

Author

Mishra, Kartikeya and Tiwari, H. L.

Subjects

SEDIMENTATION analysis, ARTIFICIAL neural networks, RESERVOIR sedimentation, SEDIMENTATION & deposition, GEOGRAPHIC information systems

Abstract

This study illustrates the comprehensive investigation to assess the sedimentation, deposition pattern, and futuristic active capacity of the reservoir in a minimal period. A multi-collaborative methodology was developed using Geographic information system (GIS) & Artificial Neural Networks (ANN). The sedimentation analysis was carried out on a GIS environment using satellite rasters. The satellite data captures the live water region with a combination of visible and Near-Infrared (NIR) bands. The ANN model was developed using feed-forward backpropagation algorithm to forecast the revised water spread. A Multi-Layer Perceptron [2-1(10)-1(1)-1] ANN structure best captures the trend of water-spread reduction with the coefficient of determination (R2)1,1,1 & 0.977 for training, testing, validation, and overall performance respectively. The designed approach provides a performance comparison of GIS and ANN methods for the prediction of reservoir capacity. Also, the observations of sedimentation analysis were superimposed on the Borland & Miller graph to portray the pattern of deposition. The research framework was applied to the Kerwan reservoir located in the capital of central India. This analysis reveals that the useful capacity of the reservoir had reduced from 22.67 to 15.13 Mm3 in 46 years (1976–2022) and the depositing pattern was shifting towards Type-II (Flood Plain-Foot Hill) which was designed as Type-III like Hilly reservoir. From the Neural Network fittings, it was concluded that Kerwan would be suppressed to 59.95% in 2030 and reduced up to 49.49% & 40.84% for 2050 & 2070 respectively, if siltation carried on. [ABSTRACT FROM AUTHOR]

Published

2024

17. Determining CO2 storage efficiency within a saline aquifer using reduced complexity models.

Author

de Jonge-Anderson, Iain, Ramachandran, Hariharan, Nicholson, Uisdean, Geiger, Sebastian, Widyanita, Ana, and Doster, Florian

Subjects

*CARBON sequestration, *GREENHOUSE gas mitigation, *CARBON dioxide, *CLIMATE change, *RESERVOIRS

Abstract

Carbon capture and storage is vital for reducing greenhouse gas emissions and mitigating climate change. Most projects involve the permanent geological storage of CO2 within deep sedimentary rock formations, but accurately constraining storage capacity usually involves detailed and computationally demanding reservoir modeling and simulation. Efficiency factors can also be used but these often lead to capacity overestimations. To address this, a workflow is proposed harnessing various existing, reduced complexity models that account for the surface topography and dynamic fluid behavior in a computationally efficient manner. This workflow was tested in an area of the Malay Basin mapped from three-dimensional seismic data but with illustrative reservoir parameters. A static analysis was first undertaken using algorithms within MRST-co2lab. Structural traps, spill paths and spill regions were identified using the reservoir topography. This provided initial indications into optimal well placement and led to refinement of the total capacity of the area into the capacity available within structural traps. This was followed with a dynamic analysis, also within MRST-co2lab, using computationally efficient Vertical Equilibrium models. Hundreds of simulations were undertaken and the optimal well placement was determined based on the maximum storage efficiency achieved. The results indicated that the amount that can be contained within this area is 15 times less than equivalent predictions using static storage efficiency factors. The advantage of such a light approach is that sensitivity and uncertainty analysis can be carried out at speed, before targeting certain parameters/areas for more detailed study. [ABSTRACT FROM AUTHOR]

Published

2024

18. Assessment of core samples through the analysis of CT measurements and its implications for CO2 sequestration potential in a Hungarian depleted oil field

Author

Gábor Pál Veres, Tamás Földes, and István Szunyog

Subjects

CO2 storage, Computed tomography, Reservoir simulation, Storage capacity, Technology

Abstract

This article focuses on potential of refining the CO2 storage capacity and rock parameters of a specific reservoir in Hungary. As part of a comprehensive laboratory measurement program, drilling core samples were analyzed using a human computed tomography (CT). The primary results of these evaluations provide critical insights that will be utilized as input parameters for developing a dynamic reservoir model. This approach aims to achieve a more accurate understanding of the reservoir. These preliminary data will be instrumental in enhancing our knowledge of this storage site, ultimately contributing to more effective CO2 storage solutions and advancing the field of geological carbon sequestration.

Published

2024

19. Estimate of the Storage Capacity of q-Correlated Patterns in Hopfield Neural Networks

Author

Wedemann, Roseli S., Plastino, Angel R., Tsallis, Constantino, Curado, Evaldo M. F., Goos, Gerhard, Series Editor, Hartmanis, Juris, Founding Editor, Bertino, Elisa, Editorial Board Member, Gao, Wen, Editorial Board Member, Steffen, Bernhard, Editorial Board Member, Yung, Moti, Editorial Board Member, Wand, Michael, editor, Malinovská, Kristína, editor, Schmidhuber, Jürgen, editor, and Tetko, Igor V., editor

Published

2024

20. Analysis of Current Possibilities of CO2 Storage in Coal Bed Methane Deposits in the Czech Part of the Upper Silesian Coal Basin (USCB) Based on Archival Data

Author

Klempa, M., Kunz, A., Hemza, P., Labus, K., Matloch Porzer, M., Mora, Pedro, editor, and Acien Fernandez, F. Gabriel, editor

Published

2024

21. Study on Expansion Mechanism and Displacement Efficiency of Reservoir Gas Storage

Author

Tang, Ying-na, Yang, Shu-he, Zhuang, Tian-lin, Zhang, Zhi-ming, Yin, Shun-li, Wu, Wei, Series Editor, and Lin, Jia'en, editor

Published

2024

22. Research on Capacity and Influencing Factors of Underground Gas Storage Transformed from Oil Reservoirs

Author

Yang, Shu-he, Tang, Ying-na, Zhang, Zhi-ming, Zhuang, Tian-lin, Wu, Wei, Series Editor, and Lin, Jia'en, editor

Published

2024

23. No saturation of soil carbon under long-term extreme manure additions

Author

Heinemann, Henrike, Don, Axel, Poeplau, Christopher, Merbach, Ines, Reinsch, Thorsten, Welp, Gerhard, and Vos, Cora

Published

2024

24. Cost-Benefit Analysis of Minor Irrigation Tank Rehabilitation Using Run-Off and Storage Capacity: A Case Study from Ambuliyar Sub-Basin, Tamil Nadu, India

Author

Nasir Nagoor Pitchai, Somasundharam Magalingam, Sakthi Kiran Duraisamy Rajasekaran, and Selvakumar Radhakrishnan

Subjects

tanks, run-off, storage capacity, SCS-CN curve number, land use and land cover, Environmental sciences, GE1-350

Abstract

This research examines the significance of restoring efficient water management systems in India’s semiarid environment, with special emphasis on the role of traditional irrigation structures, such as tanks, in collecting and storing limited water resources. Assessing the benefits of any restoration program, especially when socioeconomic and environmental benefits are involved, is challenging. In the context of tank rehabilitation, a cost-benefit analysis will be conducted regarding economic and ecological returns in the post-desiltation phase. Since the restoration process requires a significant investment, assessing the project’s viability during the planning stage is better. The present study proposes a novel method to indirectly analyse the cost-benefit of the tank restoration process by correlating run-off and storage capacity of tanks before the planning phase. The Ambuliyar sub-basin, which covers an area of 930 square kilometres in Tamil Nadu, India, comprising 181 tanks (water bodies) of varying sizes and shapes, was taken for this study. This study employed the Soil Conservation Service Curve Number (SCS-CN) method, incorporating factors such as soil type, land cover, land use practices, and advanced remote sensing and Geographic Information System (GIS) tools to simulate surface run-off. Run-off volume and tank capacity were compared for all seasons at the micro-watershed level. The results demonstrated that the run-off volume in each micro-watershed significantly exceeded the tank capacity across all seasons. Even during the summer, the run-off volumes in the micro-watershed were considerably higher than the tank capacity. The findings suggest tank restoration can effectively store run-off and significantly fulfil agricultural and other essential needs throughout the year, thereby improving the local rural economy. This study also highlights the need for periodic maintenance and rehabilitation of these tank systems to retain their functionality.

Published

2024

25. 煤层亚临界 / 超临界 CO2 吸附特征与封存模式.

Author

王帅峰, 韩思杰, 桑树勋, 郭常建, 郭 庆, 徐 昂, and 张金超

Abstract

Copyright of Natural Gas Industry is the property of Natural Gas Industry Journal Agency and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2024

26. Cost-Benefit Analysis of Minor Irrigation Tank Rehabilitation Using Run-Off and Storage Capacity: A Case Study from Ambuliyar Sub-Basin, Tamil Nadu, India.

Author

Nagoor Pitchai, Nasir, Magalingam, Somasundharam, Rajasekaran, Sakthi Kiran Duraisamy, and Radhakrishnan, Selvakumar

Subjects

COST benefit analysis, RUNOFF, WATER management, SOCIOECONOMICS, GEOGRAPHIC information systems, REMOTE sensing

Abstract

This research examines the significance of restoring efficient water management systems in India's semiarid environment, with special emphasis on the role of traditional irrigation structures, such as tanks, in collecting and storing limited water resources. Assessing the benefits of any restoration program, especially when socioeconomic and environmental benefits are involved, is challenging. In the context of tank rehabilitation, a cost-benefit analysis will be conducted regarding economic and ecological returns in the post-desiltation phase. Since the restoration process requires a significant investment, assessing the project's viability during the planning stage is better. The present study proposes a novel method to indirectly analyse the cost-benefit of the tank restoration process by correlating run-off and storage capacity of tanks before the planning phase. The Ambuliyar sub-basin, which covers an area of 930 square kilometres in Tamil Nadu, India, comprising 181 tanks (water bodies) of varying sizes and shapes, was taken for this study. This study employed the Soil Conservation Service Curve Number (SCS-CN) method, incorporating factors such as soil type, land cover, land use practices, and advanced remote sensing and Geographic Information System (GIS) tools to simulate surface run-off. Run-off volume and tank capacity were compared for all seasons at the micro-watershed level. The results demonstrated that the run-off volume in each micro-watershed significantly exceeded the tank capacity across all seasons. Even during the summer, the run-off volumes in the micro-watershed were considerably higher than the tank capacity. The findings suggest tank restoration can effectively store run-off and significantly fulfil agricultural and other essential needs throughout the year, thereby improving the local rural economy. This study also highlights the need for periodic maintenance and rehabilitation of these tank systems to retain their functionality. [ABSTRACT FROM AUTHOR]

Published

2024

27. Numerical simulation of the hydrogen charging process in an adsorption storage tank.

Author

Yang, Donghai, Liang, Lisha, Zhang, Hongyang, Sun, Yaqian, Li, Mofan, and He, Limin

Subjects

*STORAGE tanks, *HYDROGEN storage, *CARBON nanotubes, *ACTIVATED carbon, *COMPUTER simulation, *TEMPERATURE distribution

Abstract

Adsorption storage utilizing activated carbon is acknowledged as a promising approach for hydrogen storage duo to its high efficiency. This study compares the activated carbon adsorption storage method with the conventional empty tank storage approach. Finite element simulation is conducted to analyze the hydrogen charging process. Results reveal that under conditions with an initial temperature of 281 K and a storage pressure of 50 MPa, the adsorption tank exhibits a higher system volumetric capacity compared to the empty tank, with an increase of 12.6%. Furthermore, the influence of activated carbon's macroporosity and adsorption performance on storage capacity is investigated. It is indicated that increasing macroporosity effectively enhances storage capacity. Additionally, a comparison between the hydrogen storage performance of AX-21 activated carbon and carbon nanotubes (CNTs) highlights the significant impact of adsorption performance of the adsorbent materials on the storage capacity and temperature distribution. [Display omitted] • The adsorption tank has a 12.6% higher system volumetric capacity compared to the empty tank. • The maximum temperature in the adsorption tank is lower than that in the empty tank. • The hydrogen storage capacity in the adsorption tank increases with the increase in the macroporosity of activated carbon. • The hydrogen storage capacity of the AX-21 adsorption tank is 50% higher than that of the CNTs adsorption tank. [ABSTRACT FROM AUTHOR]

Published

2024

28. ReZNS: Energy and Performance-Optimal Mapping Mechanism for ZNS SSD

Author

Chanyong Lee, Sangheon Lee, Gyupin Moon, Hyunwoo Kim, Donghyeok An, and Donghyun Kang

Subjects

ZNS SSD, zoned namespaces interface, energy efficiency, performance, storage capacity, Technology, Engineering (General). Civil engineering (General), TA1-2040, Biology (General), QH301-705.5, Physics, QC1-999, Chemistry, QD1-999

Abstract

Today, energy and performance efficiency have become a crucial factor in modern computing environments, such as high-end mobile devices, desktops, and enterprise servers, because data volumes in cloud datacenters increase exponentially. Unfortunately, many researchers and engineers neglect the power consumption and internal performance incurred by storage devices. In this paper, we present a renewable-zoned namespace (ReZNS), an energy and performance-optimal mechanism based on emerging ZNS SSDs. Specifically, ReZNS recycles the remaining capacity of zones that are no longer used by adding a renewable concept into the mapping mechanism. We implemented a prototype of ReZNS based on NVMeVirt and performed comprehensive experiments with diverse workloads from synthetic to real-world workloads to quantitatively confirm power and performance benefits. Our evaluation results present that ReZNS improves overall performance by up to 60% and the total power consumption by up to 3% relative to the baseline on ZNS SSD. We believe ReZNS creates new opportunities to prolong the lifespan of various consumer electronics, such as TV, AV, and mobile devices, because storage devices play a crucial role in their replacement cycle.

Published

2024

29. Development of Polyvinyl Alcohol Hydrogels for Controlled Glucose Release in Biomedical Applications

Author

Rosa M. Quispe-Siccha, Osvaldo I. Medina-Sandoval, Abraham Estrada-Tinoco, Jorge A. Pedroza-Pérez, Adolfo Martínez-Tovar, Irma Olarte-Carrillo, Rafael Cerón-Maldonado, Arturo Reding-Bernal, and Juan C. López-Alvarenga

Subjects

polyvinyl alcohol hydrogel, dehydration, storage capacity, thermal resistance, permeability, glucose release, Science, Chemistry, QD1-999, Inorganic chemistry, QD146-197, General. Including alchemy, QD1-65

Abstract

Polyvinyl alcohol (PVA) hydrogels have a wide range of applications in the pharmaceutical and biomedicine fields due to their exceptional biophysical properties. The study focuses on preparing and characterizing capsule-shaped PVA hydrogels to enhance their biocompatibility and porosity for controlled glucose release and cell proliferation. The hydrogels were prepared using different concentrations (Cs) and molecular weights (MWs) of PVA, with two different lengths, A (10 mm) and B (20 mm), to control glucose release over 60 min. The preparation process involved PVA gel preparation and PVA hydrogel formation. A total of 500 µL of glucose was injected into all dehydrated hydrogels in groups A and B. Glucose release was studied by immersing the hydrogels in saline at 37 °C with stirring at 500 rpm. The SUP-B15 cell line was grown in six A1 hydrogels for biocompatibility testing. The results indicate that all hydrogels remained stable at 37 °C without degrading. Those with a higher C and MW exhibited a denser and less porous structure, lower glucose storage capacity, and higher elongation at break. Significant differences in glucose release, diffusion speed, and flux were observed, which were more evident in A1 > A4, B1 > B4, and B1 > A1 over 60 min. A1 and B1 had higher values because their higher porosity distribution allowed glucose to diffuse more easily. B1, being larger, has more glucose due to its increased length. The cell growth response and viability at 48 h in contact with the hydrogels was similar to that of the control (4.5 × 105 cells/mL, 98.5% vs. 4.8 × 105 cells/mL, 99.7% viability), thus demonstrating biocompatibility. The hydrogels effectively released glucose over 60 min, with variations based on porosity, C, MW, and length, and demonstrated good biocompatibility with the cell line.

Published

2024

30. Suitability Assessment and Optimization of Small Dams and Reservoirs in Northern Ghana

Author

Etienne Umukiza, Felix K. Abagale, Thomas Apusiga Adongo, and Andrea Petroselli

Subjects

water shortage, stream order, dam optimal locations, multicriteria decision-making, storage capacity, northern Ghana, Science

Abstract

Water shortages, exacerbated by erratic rainfall, climate change, and population growth, pose significant challenges globally, particularly in semi-arid regions like northern Ghana. Despite the construction of numerous small dams in the region that were intended to provide reliable water for domestic and irrigation purposes, critical water issues persist during dry periods. Key drivers in this failure are attributed to the lack of studies and/or the number of inadequate studies on suitable dam siting. This study focused on assessing the sites of selected small dams in northern Ghana, employing various methods such as stream order analysis and the Analytic Hierarchy Process within a Geographic Information System framework. Results showed that many existing dams are poorly sited, with over half located far from major stream networks, resulting in drying out during the dry season and failing to meet sustainable water storage standards. This study proposed new dam locations that would allow achieving a significant increase in storage capacities from 30% to 60%. These results highlight the necessity for decision-makers to adopt research-based approaches to address water shortages effectively, balancing agricultural, domestic, economic, and environmental needs. Future research should integrate climate change considerations, long-term monitoring, environmental impact assessments, and advanced decision-making techniques such as machine learning.

Published

2024

31. Application of B3S Monolayer as a Promising Anode in K-Ion Batteries

Author

Alali, Rasha, Ismael, Thulfiqar Najah, Rajab, Wurood J., Shather, A. H., Jabbar, Abdullah Hasan, Elawady, Ahmed, Omran, Alaa A., Hawas, Majli Nema, and Yadav, Anupam

Published

2024

32. Study of the effect of salt deposition on production capacity and storage capacity in underground gas storage.

Author

Zhongxin, Ren, Xiaoping, Yang, Dawei, Chang, Ning, Wang, Da, Meng, and Sedaee, Behnam

Subjects

UNDERGROUND storage, GAS storage, INDUSTRIAL capacity, WATER salinization, EVAPORATIVE power, GAS condensate reservoirs, SALT

Abstract

Underground gas storage (UGS) is the most economical and effective means to guarantee stable gas supply. During gas production process, the evaporation of formation water leads to the increase of water content in the gas, and the salinity of the remaining formation water increases. This work applied numerical simulation to analyze the effect of salt deposition on flowing bottomhole pressure, production capacity and storage capacity. The simulation results show that the minimum and maximum pressure of UGS is more likely to be reached during multi-cycle production under the conditions of salt deposition. Under the initial water condition, reservoir drying can improve the gas storage capacity. At the end of the tenth cycle, the storage capacity increases by 1.4%. It is concluded that the study on the impact of formation water evaporation on storage capacity is helpful for the prevention and control of salt formation water in UGS with high salinity. [ABSTRACT FROM AUTHOR]

Published

2024

33. Experimental Investigation of Injection and Production Cycles for Limestone Reservoirs via Micro-CT: Implications for Underground Gas Storage.

Author

Wang, Mengyu, Wang, Guanqun, Hu, Yong, Zhou, Yuan, Li, Wei, Han, Dan, Zhao, Zihan, Wang, Xia, Li, Longxin, and Long, Wei

Subjects

*UNDERGROUND storage, *X-ray computed microtomography, *GAS storage, *LIMESTONE, *WATER distribution, *GAS condensate reservoirs

Abstract

Global demand for underground gas storage (UGS) is steadily increasing, with the limestone-based UGS system situated in the Sichuan Basin of China gathering considerable interest in recent years. However, studies focusing on the fundamental mechanisms of the injection-production process in these systems are limited. Moreover, existing studies utilizing physical experimental methods frequently fall short in effectively visualizing micro-flow or incorporating real core samples from the reservoir. To address these gaps, we performed a coreflood experiment, integrating micro-Computed Tomography (CT) scanning to investigate mechanisms of fluid flow and storage capacity during the injection and production cycles in limestone reservoirs. Our approach involved utilizing core plugs with artificially engraved fracture-vuggy structures, which mimic the characteristics of the reservoir. Micro-CT scans were performed to visualize the microscopic changes in fractured-vuggy structures and the distribution of irreducible water during each cycle. This study reveals that increased cycles correspondingly affect gas storage capacity, particularly by expanding it in relative larger vuggy structures while reducing it in finer fissure network structures. The amount of irreducible water decreases after injection-production cycles, likely being expelled alongside the extracted dry gas. This plays a critical role in expanding the storage capacity in larger vuggy systems. Conversely, there is a decrease in storage capacity within fissure network systems, as the irreducible water is replaced by gas. This leads to a reduction in the opening force of the fine conduit. The dense matrix has a very limited effect on the flow mechanism and its influence on storage capacity. Overall, these findings offer practical insights for optimizing injection and production strategies in limestone UGS systems within the Sichuan Basin, contributing to a deeper understanding and efficient utilization of this vital infrastructure. [ABSTRACT FROM AUTHOR]

Published

2024

34. Research and Development of New High-Entropy Alloys for Hydrogen Storage †.

Author

Varcholová, Dagmara, Oroszová, Lenka, Kušnírová, Katarína, and Saksl, Karel

Subjects

RESEARCH & development, ALLOYS, HYDROGEN storage, RARE earth metal compounds, FOSSIL fuels

Abstract

Hydrogen is a key element in the changing energy sector and presents an accessible alternative to conventional fossil fuel sources. In this work, a system of ten high-entropy alloys was prepared based on the Hume-Rothery rules. One of the biggest advantages of these alloys is their storage capacity, which reaches the highest value among all known alloys intended for hydrogen storage. Alloys based on Al-Ti-Nb-Zr elements with different atomic fractions show interesting accumulation capabilities with fast absorption kinetics and low specific gravity. Each alloy in this study underwent high-pressure gravimetric absorption and desorption tests. The main goals of this work were to prepare alloys with the lowest-possible specific gravity and the highest-possible storage capacity. One alloy from our system shows storage capacity values similar to commercial alloys, without any rare-earth elements. [ABSTRACT FROM AUTHOR]

Published

2024

35. The influence of roads on depressional storage capacity estimates from high-resolution LiDAR DEMs in a Canadian Prairie agricultural basin.

Author

Annand, Holly J., Wheater, Howard S., and Pomeroy, John W.

Subjects

WETLANDS, AGRICULTURE, ECOLOGICAL integrity, LIDAR, GROUNDWATER recharge, DIGITAL elevation models, EMBANKMENTS

Abstract

Copyright of Canadian Water Resources Journal / Revue Canadienne des Ressources Hydriques is the property of Taylor & Francis Ltd and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2024

36. Rooftop rainwater harvesting potential for kitchen gardening in the Rawal watershed, Pakistan.

Author

Akbar, Ghani, Hameed, Shahid, Islam, Zafar, Asif, Muhammad, and Ashraf, Arshad

Subjects

WATER harvesting, KITCHEN gardens, GROUNDWATER recharge, WATERSHEDS, WATER table, WELLS, RURAL geography, DEVELOPING countries

Abstract

Conserving rainwater at the household level is generally overlooked in many developing countries. Therefore, rooftop rainwater potential for kitchen gardening or aquifer recharge was explored using 30 years of weather data in the Rawal watershed, which is facing water table decline (> 1 m/year) due to urbanization and climate change. The results revealed that harvesting rainwater from rooftops of available household sizes (single to five-room) in the Rawal watershed area is capable of growing vegetables (onion, tomato, cucumber, and garlic) on 25 (1 Marla) to 1339 m2 (53 Marla) using storage tanks of suitable capacity (10 to 59 m3). Furthermore, by recharging the groundwater through the available rainwater of around 1.2 m per year can stop or reduce the current water table decline in the study area. Rainwater storage during the monsoon can increase productivity by reusing in dry periods while recharging aquifers can sustain flow from springs, dug wells, and tube wells in rural and urban areas. The new information and knowledge can be helpful for decision support in designing site-specific rooftop rainwater harvesting systems for kitchen gardening, which can be instrumental in improving food security and raising groundwater levels in both urban and rural areas. [ABSTRACT FROM AUTHOR]

Published

2024

37. Geomorphic features of Lake Havasu with impacts on its water resource capacity.

Author

Wilson, Doyle C.

Abstract

Wilson DC. 2024. Geomorphic features of Lake Havasu with impacts on its water resource capacity. Lake Reserv Manage. 40:93–108. Determining a reservoir's available storage capacity and its possible rate of change over time through in-filling are 2 of many parameters needed to conduct efficient and flexible water delivery operations, particularly in cascading river-reservoir systems. This study focused on this issue through generating the first bathymetric elevation map of Lake Havasu on the Colorado River (CR) with enough detail to identify geomorphic features, including areas of deposition, to assess the current storage capacity of the reservoir. Two main areas of deposition were identified, the CR inlet delta and the Bill Williams River (BWR) delta at the reservoir's northern and southern ends, respectively. The physical distribution of the CR inlet deposits well into the main reservoir and to some extent those of the BWR delta also may have been influenced by one episode of drastic water level lowering early in the reservoir's history that probably re-mobilized sediments when fluvial dynamics temporarily resumed. High resolution sonar images compared with the CR channel position on a pre-reservoir topographic map, a sonar-generated reservoir bottom hardness map coupled with grain-size analyses of sediment samples, and modeling reservoir water level changes support this notion. Post-reservoir dam construction up both rivers has cut off sediment sources that historically reached Lake Havasu, effectively reducing sedimentation rates. Determined thicknesses of the sediment packages indicate that Lake Havasu has lost more than 7% of its available storage capacity since inception, which is an important parameter for adjusting management of water deliveries and storage in the Colorado River system. [ABSTRACT FROM AUTHOR]

Published

2024

38. The Effect of Electrolyte Composition on the Performance of a Single‐Cell Iron–Chromium Flow Battery.

Author

Mans, Nico, Krieg, Henning M., and van der Westhuizen, Derik J.

Subjects

FLOW batteries, ELECTROLYTES, ENERGY storage, IRON chlorides, ENERGY consumption, VANADIUM, IRON

Abstract

Flow batteries are promising for large‐scale energy storage in intermittent renewable energy technologies. While the iron–chromium redox flow battery (ICRFB) is a low‐cost flow battery, it has a lower storage capacity and a higher capacity decay rate than the all‐vanadium RFB. Herein, the effect of electrolyte composition (active species and supporting electrolyte concentrations), Fe/Cr molar ratio, and supporting electrolyte type (HCl and H2SO4) on the performance (current efficiency (CE), voltage efficiency (VE), energy efficiency, discharge capacity, and capacity decay) of an ICRFB is investigated. The storage capacity of the optimum electrolyte (1.3 m FeCl2, 1.4 m CrCl3, 5.0 mm Bi2O3 in 1.0 m HCl) is 40% higher (from 17.5 to 24.4 Ah L−1), while the capacity decay rate is tenfold lower (from 3.0 to 0.3% h−1) than the performance of the previously used 1.0 m FeCl2, 1.0 m CrCl3 in 3.0 m HCl. At the optimum Fe and Cr concentrations and ratio in 0.5 m HCl, a near constant CE (92.3%), VE (78.7%), and EE (72.6%) are obtained over 50 cycles. The significantly higher capacity decay when using 1.0 m H2SO4 (1.6% h−1) compared to 1.0 m HCl (0.3% h−1) confirms that HCl is the more suitable supporting electrolyte. [ABSTRACT FROM AUTHOR]

Published

2024

39. Locational Role Analysis of Energy Storage Systems Based on Optimal Capacity Needs and Operations under High Penetration of Renewable Energy.

Author

Park, Heejung

Subjects

*ENERGY storage, *RENEWABLE energy sources, *INDEPENDENT system operators, *RENEWABLE natural resources, *HEAT capacity, *MICROGRIDS

Abstract

As the need for energy storage systems (ESSs) capacity is increasing due to high accommodation of renewable resources, it is crucial to analyze in which location and for what purpose the ESSs are required to achieve the highest efficiency. Investors and system operators can place and operate the ESSs as expected based on this analysis. Therefore, this study assesses the specific roles of ESSs in a grid system based on their optimal capacity needs, locations, and operations. A long-term simulation model using mixed-integer programming is proposed to obtain these optimal solutions, such as ESS capacity and operational schedules for energy and reserves. Four-week operational simulations are performed for each month using data from the California Independent System Operator. ESSs are placed at sites with solar photovoltaic (PV) systems or wind farms, at baseload generator buses, and at load buses to verify the role of ESSs, depending on the locational differences. The detailed roles are analyzed from the aspects of flexible capacity supply, reserve deployments, time-shifting renewable and thermal energy generation, and costs. The results show that the ESSs on the baseload generation side provide flexibility by time-shifting baseload generation and turn on baseload generators, even when the net load is small. For instance, the required capacity of the flexible thermal generators, such as natural gas turbine generators, is about 3004 MW without the ESS operations in May. When 450 MW ESSs colocated with solar PVs are operated, the required flexible capacity of the thermal generators is lowered to 2404 MW. Moreover, ESSs are highly utilized as a downward reserve provider, although their costs for reserves are higher than thermal generators. [ABSTRACT FROM AUTHOR]

Published

2024

40. Theoretical Investigation of 2D M3C2S2 (M = Cr, Zr) as Potential Electrode Materials for Li-Ion Batteries.

Author

Yu, Jiale, Wang, Yun, Li, Xiang, and Wu, Fang

Abstract

Herein, the electronic and magnetic properties of 2D M3C2S2 (M = Cr, Zr) monolayers and their potential as lithium-ion battery electrodes are systematically studied by density functional theory (DFT). The geometric structures of the M3C2S2 monolayers are both thermally and dynamically stable. The Cr3C2S2 monolayer acts as a magnetic metal, while the Zr3C2S2 monolayer shows a nonmagnetic metallicity nature. The diffusion energy barriers are only 0.23 eV (Cr3C2S2) and 0.26 eV (Zr3C2S2), and lithium storage capacities are 439.35 mA h g−1 for the Cr3C2S2 monolayer and 296.41 mA h g−1 for the Zr3C2S2 monolayer, respectively. Compared with the pristine M3C2 monolayers, although the diffusion energy barriers are slightly increased after the S group modification, the lithium storage capacity of Cr3C2S2 and Zr3C2S2 monolayers both have obvious improvement. Our work indicates that the S-functionalized M3C2S2 hold promise for future use as electrode materials for Li-ion batteries. [ABSTRACT FROM AUTHOR]

Published

2024

41. Green hydrogen levelized cost assessment from wind energy in Argentina with dispatch constraints.

Author

Schmidhalter, Ignacio, Mussati, Miguel C., Mussati, Sergio F., Oliva, Diego G., Fuentes, Mauren, and Aguirre, Pio A.

Subjects

*WIND power, *WIND power plants, *HYDROGEN, *HYDROGEN production, *COST

Abstract

This study assesses the optimal levelized cost of hydrogen (LCOH) production from wind farms. The study investigates 84 locations in the south of Argentina with nodes spaced 100 km apart, as well as one location each in Chile, the USA, Spain, Japan, and Australia. A model is presented to optimize the design of the wind farm, electrolyzer plant, compressor station, and storage capacity (gaseous 160 bar), with different hydrogen demands (hydrogen dispatch constraints) and minimizing the LCOH. Hourly data for wind resources from NASA is used to define a characteristic year. The model involves energy and mass balances in hourly basis for the whole year. Sequential solution procedures with heuristic rules are implemented. The optimal costs and their relation to the main variables, as well as production and storage, are analyzed. By imposing dispatch constraints, increase in levelized cost ranges from 25 % to 40 %, and decrease in annual hydrogen production ranges from 5 % to 30 %. Best levelized cost without considering electric transport between wind farm and electrolyzer plant is 2700 USD/t. • Attain the optimal hydrogen cost from wind energy. • Analize 84 sites in a 100 km × 100 km grid covering the Argentina's south region. • Identify the representative year (2011–2020) for wind resources. • Determine the site-specific optimal wind farm-to-electrolyzer power ratio. • Investigate the influence of dispatch constraints on the optimal LCOH. [ABSTRACT FROM AUTHOR]

Published

2024

42. Hydrogen Storage Potential in Natural Gas Deposits in the Polish Lowlands.

Author

Uliasz-Misiak, Barbara, Lewandowska-Śmierzchalska, Joanna, and Matuła, Rafał

Subjects

*HYDROGEN storage, *NATURAL gas storage, *GAS reservoirs, *GAS fields, *RENEWABLE energy sources, *GEOLOGICAL research

Abstract

In the future, the development of a zero-carbon economy will require large-scale hydrogen storage. This article addresses hydrogen storage capacities, a critical issue for large-scale hydrogen storage in geological structures. The aim of this paper is to present a methodology to evaluate the potential for hydrogen storage in depleted natural gas reservoirs and estimate the capacity and energy of stored hydrogen. The estimates took into account the recoverable reserves of the reservoirs, hydrogen parameters under reservoir conditions, and reservoir parameters of selected natural gas reservoirs. The theoretical and practical storage capacities were assessed in the depleted natural gas fields of N and NW Poland. Estimates based on the proposed methodology indicate that the average hydrogen storage potential for the studied natural gas fields ranges from 0.01 to 42.4 TWh of the hydrogen energy equivalent. Four groups of reservoirs were distinguished, which differed in recovery factor and technical hydrogen storage capacity. The issues presented in the article are of interest to countries considering large-scale hydrogen storage, geological research organizations, and companies generating electricity from renewable energy sources. [ABSTRACT FROM AUTHOR]

Published

2024

43. A numerical investigation on the utilization of a depleted natural gas field for seasonal hydrogen storage: A case study for Değirmenköy gas field.

Author

Sarı, Emrah and Çiftçi, Erdem

Subjects

*HYDROGEN storage, *GAS reservoirs, *NATURAL gas storage, *UNDERGROUND storage, *NATURAL gas

Abstract

The growing interest in hydrogen (H 2) within the energy sector has necessitated the development of alternative storage systems for H 2. Depleted natural gas reservoirs, currently utilized for large-scale natural gas storage, are also seen as a feasible choice for storing H 2. This study presents the results of numerical simulations to assess the applicability of utilizing the Değirmenköy gas field for underground hydrogen storage. The Değirmenköy gas field is onshore and depleted in the Thrace region of Türkiye. Cyclic storage simulations were run in four distinct scenarios to assess the reservoir's injection and withdrawal capacities and the H 2 ratio of the withdrawn gas from the reservoir. If the injection and withdrawal flow rates are 1.5 million Sm3/day (250.0 thousand Sm3/day/well), a constant flow rate can be achieved on almost all days of the injection and withdrawal periods, and annual average H 2 injection and withdrawal capacities were estimated as 221.5 million Sm3 and 177.7 million Sm3, respectively. Besides, H 2 ratio of the withdrawn gas increased as storage cycles repeated and average H 2 ratio increased to 88% in the last cycle. On the other hand, in the simulations performed with constant bottom hole pressure (BHP), both injection and withdrawal flow rates are quite variable during injection and withdrawal periods and peak flow rates at the beginning of each period is higher during H 2 storage as compared to natural gas. Nevertheless, in both cases the flow rate gradually diminished and eventually ceased before the related period ended. Hence, it can be inferred that conducting storage operations with a steady flow rate, as opposed to a constant BHP, is deemed more suitable for the field under investigation due to the stability of flow rate. As a result, depleted natural gas reservoirs are considered a suitable option for H 2 storage in large-scale, especially for applications without the need to obtain pure H 2 , considering their storage, injection, and withdrawal capacities. • Underground hydrogen storage capability of the Değirmenköy gas field was studied. • Large-scale and seasonal hydrogen storage in a depleted gas field was examined. • A reservoir model was generated using MATLAB MRST based on real-field data. • Annual injection and withdrawal capacities of the recovered hydrogen were assessed. • Injection and withdrawal flow rates for hydrogen/natural gas storage were compared. [ABSTRACT FROM AUTHOR]

Published

2024

44. Reservoir Characterisation and Modelling for CO2 Sequestration in ‘‘Han’’ Field, Onshore Niger Delta, Nigeria.

Author

Oyero, S. Kemisola, Olubola, Abiola, and Ayinde, O. Kazeem

Subjects

*CARBON sequestration, *GEOLOGICAL carbon sequestration, *OIL fields, *GAS condensate reservoirs, *WORKING gases, *GAS industry, *EARTH scientists

Abstract

Geoscientists working in the oil and gas industry have a crucial role in combating climate change. In particular, by carrying out regional and local characterization and field projects to demonstrate that different types of geologic storage reservoirs distributed over different basins can permanently and safely store CO2. Therefore, this work is aimed at determining the storage capacity, injectivity, and containment of the reservoir intended for CO2 sequestration. Well logs and 3D seismic data were used to analyze a depleted oil field, (the “HAN” field), in the Niger Delta, Nigeria. Petrophysical analysis was done on the well logs to estimate the net thickness, porosity, water saturation, and injectivity of the reservoirs. Structural interpretation was done on the seismic data, and the volumetric method was used to estimate the storage capacity of the delineated reservoirs. The fault’s sealing capacity was determined, and the resulting containment of the reservoirs was estimated. Two sand reservoirs, RES 1 and RES 2, of average thicknesses of 79 m and 93 m, respectively, were delineated across the three analysed wells. The reservoirs effective porosity was 18% and 19%, respectively, and water saturation was 18% and 35%, respectively. The storage capacity of RES 1 was estimated to be 28 MT, and RES 2 was 22 MT. The assessed storage capacity for both reservoirs gave “HAN” field a total storage capacity of approximately 50 MT. The injectivity for RES 1 and RES 2 was determined to be 337 mD and 323 mD, respectively. Based on the threshold set by the International Energy Agency, parameters obtained were observed to be greater than 10 m, 10%, 10%, 200 mD, and 4 MT for thickness, effective porosity, water saturation, injectivity, and storage capacity, respectively. The Han field is suggested as a good field for CO2 sequestration. Furthermore, the Shale Gouge Ratio (SGR) was estimated to be 29% (poor sealing zone) and 44% (moderately sealing zone) in Fault F9 for regions with RES 1 and 2, respectively, to validate their containment. It is evident from the SGR that F9 can serve as a barrier to the migration of CO2 away from the reservoir at deeper depths. [ABSTRACT FROM AUTHOR]

Published

2024

45. Metodología para estimar la capacidad de almacenamiento geológico de CO2 en campos maduros de hidrocarburos.

Author

Sánchez de la Vega, Alberto and Dávila, Moisés

Subjects

*WATER temperature, *ENERGY development, *CARBON dioxide, *FOSSIL fuels, *RENEWABLE energy sources, *GEOLOGICAL carbon sequestration, *GREENHOUSE gases

Abstract

The best technological alternative known so far to reduce emissions into the atmosphere of the largest greenhouse gas, carbon dioxide, in the short and medium term, is the capture, utilization and geological storage of CO2 (CCUS). This aspect allows the continued use of fossil fuels while moving towards the massive and comprehensive development of renewable energies. Achieving a significant reduction in CO2 emissions requires knowledge of the available CO2 storage capacity. This research shows a methodology for calculating the geological storage capacity in the part of the porous volume previously occupied by hydrocarbons can be occupied by an equivalent volume of CO2 at reservoir pressure and temperature conditions. The proposed calculation methodology (UCCGCO2) has an estimation efficiency between 90 and 98% was determined to the values obtained currently available methodologies, and its use is simpler than these. [ABSTRACT FROM AUTHOR]

Published

2024

46. Gas Hydrates for Hydrogen Storage: A Comprehensive Review and Future Prospects.

Author

Kim, Min-Kyung and Ahn, Yun-Ho

Abstract

As concerns about environmental pollution grow, hydrogen is gaining attention as a promising solution for sustainable energy. Researchers are exploring hydrogen's potential across various fields including production, transportation, and storage, all thanks to its clean and eco-friendly characteristics, emitting only water during use. One standout option for hydrogen storage is through gas hydrates, unique structures mainly composed of water molecules. These hydrates have attracted interest as a green method for storing hydrogen. A noteworthy advantage is that they release only water vapor when used, aligning with environmental goals. However, ongoing research is essential to improve how efficiently these hydrates form under different conditions. This review paper offers a comprehensive overview of research into using gas hydrates for hydrogen storage. While early efforts focused on storing pure hydrogen, current studies delve into modifying the conditions and speeds of the formation using various promoters that impact the thermodynamics and kinetics involved. Some researchers suggest new strategies that enable trapping multiple hydrogen molecules within a single hydrate cage, potentially enhancing hydrogen storage capacity. Moreover, the use of materials such as porous substances, surfactants, and amino acids has been extensively investigated to enhance interactions between water and gas, resulting in accelerated formation rates. By advancing these strategies, gas hydrates could become a more practical material for hydrogen storage. Given the urgency of reducing carbon emissions and curbing environmental harm, gas hydrates stand out as a promising option for sustainable energy advancement. [ABSTRACT FROM AUTHOR]

Published

2024

47. Assessment of CO₂ storage capacity in the Sureste Basin in Mexico

Author

Arellano Sanchez, Jessica, Watson, Matthew, and Verdon, James

Subjects

CCS, GIS, Mexico, Sureste Basin, Induced Seismicity, Pipeline routing, CO2 Storage, Storage capacity

Abstract

This project will investigate the potential for carbon dioxide (CO₂) storage in the Sureste Basin, in the Southeast of Mexico, the most prolific hydrocarbon Basin in the country, focussing mainly on the Ogarrio mature field. The volume of CO₂ storage will be obtained from seismic reflection and well log analyses, along with a slip tendency analysis to understand the stress state and fault activity in the study area; these analyses will help find the most suitable places for CO₂ injection. Finally, there will be a creation of different pipeline routes from CO₂ sources to the most suitable storage locations in the Ogarrio field. In Mexico, this type of study has not yet been carried out and is essential, as it will show the most effective way to assess the storage capacity and transport of CO₂, reducing costs and time.

Published

2022

48. Assessment of groundwater reservoir and the influence of its characteristics on water dynamic control

Author

Wenli Yao, Xiaoli Liu, Fang Wang, Enzhi Wang, Linshun Cao, Peng Bai, and Nan Hu

Subjects

characteristic water level, groundwater reservoir, numerical simulation, storage capacity, Environmental technology. Sanitary engineering, TD1-1066

Abstract

Groundwater reservoirs play an important role in regional water volume balance. In order to ensure the efficiency of a groundwater reservoir and obtain its maximum value, it is necessary to figure out its characteristics, such as minimum water level, normal water level, and maximum water level. The characteristics not only determined the storage capacity but also influenced the water allocation and utilization. Therefore, this paper took a groundwater reservoir built in an alluvial fan as an example to assess its storage capacity and the influence on water dynamic control. The alluvial fan was located in the front of Lao River, where there were an alluvial-diluvial fan, groundwater storage space, and natural impervious boundary. Therefore, it was an ideal place for constructing a groundwater reservoir. Through theoretical analysis and numerical simulation, the storage capacity was determined, and the influence of groundwater reservoir characteristics on water dynamic control was analyzed. On this basis, the water-supply method in the research area was confirmed. This paper will present a new method for repairing the groundwater system and protecting the ecological environment. HIGHLIGHTS Groundwater reservoir built in an alluvial fan could balance the water contradiction.; Groundwater reservoir characteristics have a great influence on water dynamic control.; Groundwater reservoir capacity and its characteristics were calculated.;

Published

2023

49. Comparison of Renewable Large-Scale Energy Storage Power Plants Based on Technical and Economic Parameters

Author

Klaas, Ann-Kathrin, Beck, Hans-Peter, Zheng, Zheng, Editor-in-Chief, Xi, Zhiyu, Associate Editor, Gong, Siqian, Series Editor, Hong, Wei-Chiang, Series Editor, Mellal, Mohamed Arezki, Series Editor, Narayanan, Ramadas, Series Editor, Nguyen, Quang Ngoc, Series Editor, Ong, Hwai Chyuan, Series Editor, Sun, Zaicheng, Series Editor, Ullah, Sharif, Series Editor, Wu, Junwei, Series Editor, Zhang, Baochang, Series Editor, Zhang, Wei, Series Editor, Zhu, Quanxin, Series Editor, Zheng, Wei, Series Editor, Schossig, Peter, editor, Droege, Peter, editor, Riemer, Antonia, editor, and Speer, Martin, editor

Published

2023

50. The Effect of Electrolyte Composition on the Performance of a Single‐Cell Iron–Chromium Flow Battery

Author

Nico Mans, Henning M. Krieg, and Derik J. van der Westhuizen

Subjects

capacity decay, efficiency, electrolyte compositions, iron–chromium redox flow batteries, single cell performance, storage capacity, Environmental technology. Sanitary engineering, TD1-1066, Renewable energy sources, TJ807-830

Abstract

Flow batteries are promising for large‐scale energy storage in intermittent renewable energy technologies. While the iron–chromium redox flow battery (ICRFB) is a low‐cost flow battery, it has a lower storage capacity and a higher capacity decay rate than the all‐vanadium RFB. Herein, the effect of electrolyte composition (active species and supporting electrolyte concentrations), Fe/Cr molar ratio, and supporting electrolyte type (HCl and H2SO4) on the performance (current efficiency (CE), voltage efficiency (VE), energy efficiency, discharge capacity, and capacity decay) of an ICRFB is investigated. The storage capacity of the optimum electrolyte (1.3 m FeCl2, 1.4 m CrCl3, 5.0 mm Bi2O3 in 1.0 m HCl) is 40% higher (from 17.5 to 24.4 Ah L−1), while the capacity decay rate is tenfold lower (from 3.0 to 0.3% h−1) than the performance of the previously used 1.0 m FeCl2, 1.0 m CrCl3 in 3.0 m HCl. At the optimum Fe and Cr concentrations and ratio in 0.5 m HCl, a near constant CE (92.3%), VE (78.7%), and EE (72.6%) are obtained over 50 cycles. The significantly higher capacity decay when using 1.0 m H2SO4 (1.6% h−1) compared to 1.0 m HCl (0.3% h−1) confirms that HCl is the more suitable supporting electrolyte.

Published

2024