Showing total 5,828 results

1. Optimal Sizing and Operation of Hybrid Renewable Energy System: A Techno-Economic Analysis of Residential Building Considering Seasonal Storage

Author

Qu, Kaichen, Zhang, Hong, and Peng, Zhijun, editor

Published

2024

2. Intermetallic TiFe particles generation within porous monolithic carbon materials arising from paper mill waste and their cooperative hydrogen storage properties.

Author

Poupart, Romain, Cona, Christophe, Labrugère-Sarroste, Christine, Deleuze, Hervé, Backov, Rénal, and Bobet, Jean-Louis

Abstract

A new materials composed of TiFe particles stabilized onto a carbon support is described. The carbon support is derived from a waste from the paper industry called Kraft Black liquor. The particles are generated through an impregnation/reduction process of a mixture of titanium ethoxide and iron nitrate followed by a thermal treatment. The generated particles have been investigated through XPS, XRD and SEM analysis as well as tested for hydrogen storage. The hydrogen storage at 25 °C leads to a capacity of up to 0.5 wt% while at 150 °C, free of the carbon absorption, leads to a capacity of 0.2 wt% without any prior activation process. Novel TiF@carbo(HIPE) materials have been synthesized while employing Kraft black liquor as carbonaceous source. A specific carbo-reduction thermal treatment allows a synergetic TiFe particles external shell reduction concomitant with the surrounding carbonaceous backbone oxidation enhancing thereby the materials specific surface area and associated microporosity. Pre-activation free, TiFe@Carbo(HIPE) can achieve a capacity up to 0.5 wt% at 25 °C where TiFe particles and the carbonaceous host support are acting cooperatively. [Display omitted] • Generation and characterization of carbon from a waste from the paper industry. • Generation of TiFe nanoparticles on the carbon. • Characterization of the TiFe nanoparticles. • Use of the hybrid composite TiFe@Carbon for hydrogen storage. [ABSTRACT FROM AUTHOR]

Published

2024

3. Optimal Design and Operation of Community Hydrogen Generation and Storage Applications

Author

Katholnigg, Manuel, Golla, Armin, Scheidt, Frederik vom, Henni, Sarah, Weinhardt, Christof, Barbosa-Povoa, Ana Paula, Editorial Board Member, de Almeida, Adiel Teixeira, Editorial Board Member, Gans, Noah, Editorial Board Member, Gupta, Jatinder N. D., Editorial Board Member, Heim, Gregory R., Editorial Board Member, Hua, Guowei, Editorial Board Member, Kimms, Alf, Editorial Board Member, Li, Xiang, Editorial Board Member, Masri, Hatem, Editorial Board Member, Nickel, Stefan, Editorial Board Member, Qiu, Robin, Editorial Board Member, Shankar, Ravi, Editorial Board Member, Slowiński, Roman, Editorial Board Member, Tang, Christopher S., Editorial Board Member, Wu, Yuzhe, Editorial Board Member, Zhu, Joe, Editorial Board Member, Zopounidis, Constantin, Editorial Board Member, Grothe, Oliver, editor, Rebennack, Steffen, editor, and Stein, Oliver, editor

Published

2023

4. Alkali Metal Ion Decorated Crown Ethers as an Enhancing Agent for Hydrogen Storage in the Metal–Organic Framework (MOF): Density Functional Theoretical Investigation

Author

Boda, Anil, Musharaf Ali, Sk., Shenoy, K. T., Mohan, S., Singh, Suneet, editor, and Ramadesigan, Venkatasailanathan, editor

Published

2020

5. Responses to comments on the paper 'two-dimensional Sc2C: A reversible and high capacity hydrogen storage material predicted by first-principles calculations'

Author

Libo Wang, Qinghua Wu, Aiguo Zhou, and Qianku Hu

Subjects

Materials science, Chemical substance, Hydrogen, Renewable Energy, Sustainability and the Environment, Binding energy, Thermodynamics, chemistry.chemical_element, Energy Engineering and Power Technology, 02 engineering and technology, 010402 general chemistry, 021001 nanoscience & nanotechnology, Condensed Matter Physics, 01 natural sciences, Oxygen, 0104 chemical sciences, Hydrogen storage, Fuel Technology, Physisorption, chemistry, Hydrogen fuel, 0210 nano-technology, MXenes

Abstract

A recent commentary by Santhosh and Ravindran on our paper (Int. J. Hydrogen Energy 2014, 39:10606) demonstrated that the interaction between H2 and MXene (Sc2C and Ti2C) phases are not Kubas-type and should be of weak physisorption, and thus made a conclusion that 2D Sc2C and Ti2C are not suitable for practical hydrogen storage applications. In this responses, we recalculated hydrogen adsorption on 2D Sc2C and Ti2C by using different exchange-correlation functionals. And based on the calculated results, bare MXenes (especially the Ti2C) are suitable as hydrogen storage materials at temperatures of several tens degrees lower than room temperature. And the hydrogen adsorptions on the MXenes terminated with oxygen group were also investigated. Among the Ti2C, Sc2C and their oxygen-functional counterparts, the binding energy of H2 on Sc2CO2 surface is the closest to the ideal range of 0.16–0.42 eV/H2 at ambient conditions, and thus the Sc2C with oxygen group is expected to be more suitable as hydrogen storage materials.

Published

2022

6. Comparison of Heuristics Towards Approaching a Scheduling and Capacity Planning MINLP for Hydrogen Storage in Chemical Substances

Author

Schulte Beerbühl, Simon, Fröhling, Magnus, Schultmann, Frank, Huisman, Dennis, editor, Louwerse, Ilse, editor, and Wagelmans, Albert P.M., editor

Published

2014

7. Responses to comments on the paper "two-dimensional Sc2C: A reversible and high capacity hydrogen storage material predicted by first-principles calculations".

Author

Hu, Qianku, Wu, Qinghua, Wang, Libo, and Zhou, Aiguo

Subjects

*HYDROGEN storage, *HYDROGEN as fuel, *BINDING energy, *PHYSISORPTION, *CARBON dioxide, *FUNCTIONALS

Abstract

A recent commentary by Santhosh and Ravindran on our paper (Int. J. Hydrogen Energy 2014, 39:10,606) demonstrated that the interaction between H 2 and MXene (Sc 2 C and Ti 2 C) phases are not Kubas-type and should be of weak physisorption, and thus made a conclusion that 2D Sc 2 C and Ti 2 C are not suitable for practical hydrogen storage applications. In this responses, we recalculated hydrogen adsorption on 2D Sc 2 C and Ti 2 C by using different exchange-correlation functionals. And based on the calculated results, bare MXenes (especially the Ti 2 C) are suitable as hydrogen storage materials at temperatures of several tens degrees lower than room temperature. And the hydrogen adsorptions on the MXenes terminated with oxygen group were also investigated. Among the Ti 2 C, Sc 2 C and their oxygen-functional counterparts, the binding energy of H 2 on Sc 2 CO 2 surface is the closest to the ideal range of 0.16–0.42 eV/H 2 at ambient conditions, and thus the Sc 2 C with oxygen group is expected to be more suitable as hydrogen storage materials. [ABSTRACT FROM AUTHOR]

Published

2022

8. A flexible paper-based hydrogen fuel cell for small power applications

Author

Yifei Wang, Yingguang Zhang, Holly Y.H. Kwok, Huimin Zhang, Dennis Y.C. Leung, Wending Pan, and Xu Lu

Subjects

Materials science, Renewable Energy, Sustainability and the Environment, business.industry, Open-circuit voltage, Energy Engineering and Power Technology, 02 engineering and technology, 010402 general chemistry, 021001 nanoscience & nanotechnology, Condensed Matter Physics, 01 natural sciences, 0104 chemical sciences, Hydrogen storage, Fuel Technology, Power rating, Electrode, Optoelectronics, 0210 nano-technology, business, Faraday efficiency, Power density, Voltage, Hydrogen production

Abstract

In this work, a paper-based hydrogen fuel cell is developed without the need for hydrogen storage. Instead, an embedded aluminum foil inside the paper is utilized for in-situ hydrogen generation. The electrodes and current collectors are also deposited on the paper, leading to a lightweight, compact and flexible hydrogen fuel cell with an OCV reaching 0.93 V and a peak power density of 4 mW cm−2. Benefited from the impeded hydroxyl ion diffusion, the hydrogen generation rate is well controlled, leading to a high faradaic efficiency of 72%. In addition, the cell can be operated under different bending angles with negligible power loss. Furthermore, it can be conveniently stacked in the same piece of paper for higher voltage and power outputs. Such a novel fuel cell design is especially suitable for powering various flexible devices with small rated power.

Published

2019

9. A flexible paper-based hydrogen fuel cell for small power applications.

Author

Wang, Yifei, Kwok, Holly Y.H., Zhang, Yingguang, Pan, Wending, Zhang, Huimin, Lu, Xu, and Leung, Dennis Y.C.

Subjects

*FUEL cells, *INTERSTITIAL hydrogen generation, *FUEL cell design & construction, *POWER density, *HYDROGEN storage, *MICROBIAL fuel cells, *CARBON dioxide reduction

Abstract

In this work, a paper-based hydrogen fuel cell is developed without the need for hydrogen storage. Instead, an embedded aluminum foil inside the paper is utilized for in-situ hydrogen generation. The electrodes and current collectors are also deposited on the paper, leading to a lightweight, compact and flexible hydrogen fuel cell with an OCV reaching 0.93 V and a peak power density of 4 mW cm−2. Benefited from the impeded hydroxyl ion diffusion, the hydrogen generation rate is well controlled, leading to a high faradaic efficiency of 72%. In addition, the cell can be operated under different bending angles with negligible power loss. Furthermore, it can be conveniently stacked in the same piece of paper for higher voltage and power outputs. Such a novel fuel cell design is especially suitable for powering various flexible devices with small rated power. • A paper-based hydrogen fuel cell is developed with an OCV of 0.93 V. • The peak power density is 4 mW cm−2 and the maximum current density is 8 mA cm−2. • Faradaic efficiency and energy efficiency are as high as 72% and 18%, respectively. • 75–87.5% of the cell performance remains when bended by angles from 45° to 135°. • A 4-cell stack is developed with an OCV of 3.8 V and a stacking efficiency of 90.6%. [ABSTRACT FROM AUTHOR]

Published

2019

10. Hydrogen storage characteristics of carbon fibers derived from rice straw and paper mulberry

Author

Sung-Ho Hwang, Sang Kyoo Lim, and Won Mi Choi

Subjects

Materials science, Hydrogen, biology, Carbonization, Mechanical Engineering, Paper mulberry, chemistry.chemical_element, 02 engineering and technology, Rice straw, 010402 general chemistry, 021001 nanoscience & nanotechnology, Condensed Matter Physics, biology.organism_classification, 01 natural sciences, 0104 chemical sciences, Hydrogen storage, chemistry, Mechanics of Materials, Specific surface area, Gravimetric analysis, General Materials Science, Composite material, 0210 nano-technology, Spinning

Abstract

Highly porous carbon fibers based on rice straw and paper mulberry have been successfully prepared via wet spinning and carbonization process. From the comparison of the morphological structure and specific surface area, the porous carbon fibers derived from rice straw shows a high specific surface area of 2260 m 2 /g. This material exhibits excellent hydrogen storage properties with a gravimetric hydrogen uptakes of 4.35 wt% at 77 K and 10 bar.

Published

2016

11. Responses to comments on the paper "Two-dimensional Sc2C: A reversible and high capacity hydrogen storage material predicted by first-principles calculations".

Author

Hu, Qianku, Wu, Qinghua, Wang, Libo, and Zhou, Aiguo

Subjects

*HYDROGEN storage, *HYDROGEN as fuel, *PHYSISORPTION, *BINDING energy, *FUNCTIONALS, *MATERIALS

Abstract

A recent commentary by Santhosh and Ravindran on our paper (Int. J. Hydrogen Energy 2014, 39:10606) demonstrated that the interaction between H 2 and MXene (Sc 2 C and Ti 2 C) phases are not Kubas-type and should be of weak physisorption, and thus made a conclusion that 2D Sc 2 C and Ti 2 C are not suitable for practical hydrogen storage applications. In this responses, we recalculated hydrogen adsorption on 2D Sc 2 C and Ti 2 C by using different exchange-correlation functionals. And based on the calculated results, bare MXenes (especially the Ti 2 C) are suitable as hydrogen storage materials at temperatures of several tens degrees lower than room temperature. And the hydrogen adsorptions on the MXenes terminated with oxygen group were also investigated. Among the Ti 2 C, Sc 2 C and their oxygen-functional counterparts, the binding energy of H 2 on Sc 2 CO 2 surface is the closest to the ideal range of 0.16–0.42 eV/H 2 at ambient conditions, and thus the Sc 2 C with oxygen group is expected to be more suitable as hydrogen storage materials. [ABSTRACT FROM AUTHOR]

Published

2020

12. Comment on the paper titled'Two-dimensional Sc2C: A reversible and high capacity hydrogen storage material predicted by first-principles calculations' by Hu et al., International Journal of Hydrogen Energy, 2014; 69, 1–4

Author

Ponniah Ravindran and Archa Santhosh

Subjects

Materials science, Renewable Energy, Sustainability and the Environment, Binding energy, Energy Engineering and Power Technology, Thermodynamics, 02 engineering and technology, 010402 general chemistry, 021001 nanoscience & nanotechnology, Condensed Matter Physics, 01 natural sciences, 0104 chemical sciences, Hydrogen storage, Fuel Technology, Adsorption, Hydrogen fuel, CASTEP, Density functional theory, Local-density approximation, 0210 nano-technology, MXenes

Abstract

Hu et al. reported the hydrogen storage properties of Sc2C and Ti2C based MXene phases utilizing density functional theory (DFT) as implemented in the CASTEP code [1, 2]. Based on such calculations, the authors suggest that the MXenes should be a new family of potential hydrogen storage media. Their results claim a maximum hydrogen storage capacity of 9.0 wt% with an average binding energy of 0.164 eV/H2 in Sc2C MXene indicating Kubas-type interaction between H2 and the MXene. These investigations are of prime importance since they provide insight about further applications of MXenes for hydrogen storage. In these calculations they have used local density approximation (LDA) to estimate the adsorption energies. However, binding energies for H2 with the MXene phases mentioned above obtained from more accurate calculations based on Generalised Gradient Approximation (GGA) and calculation including dispersion correction (GGA + vdW) show very weak binding energy ( ∼ 0.064 e V / H 2 ) suggesting weak physical interactions between H2 and the MXene phases. Our accurate DFT calculations predict that these MXene phases are not suitable for hydrogen storage at realistic conditions. So we conclude that appropriate exchange-correlation functional should be used to extract hydrogen adsorption energies in nano-phases to describe their hydrogen storage properties reliably.

Published

2020

13. Enhanced hydrogen storage in sandwich-structured rGO/Co1−xS/rGO hybrid papers through hydrogen spillover

Author

Xiaohong Wu, Lu Han, Wei Qin, Jiawei Liu, Peng Gao, Gang Wu, Jiahuang Jian, and Benjamin Hultman

Subjects

Materials science, Hydrogen, Renewable Energy, Sustainability and the Environment, Graphene, Inorganic chemistry, Oxide, Energy Engineering and Power Technology, chemistry.chemical_element, 02 engineering and technology, 010402 general chemistry, 021001 nanoscience & nanotechnology, Electrochemistry, 01 natural sciences, Cobalt sulfide, 0104 chemical sciences, law.invention, chemistry.chemical_compound, Hydrogen storage, chemistry, Chemical bond, law, Electrical and Electronic Engineering, Physical and Theoretical Chemistry, Hydrogen spillover, 0210 nano-technology

Abstract

Reduced graphene oxide (rGO) based two-dimensional (2D) structures have been fabricated for electrochemical hydrogen storage. However, the effective transfer of atomic hydrogen to adjacent rGO surfaces is suppressed by binders, which are widely used in conventional electrochemical hydrogen storage electrodes, leading to a confining of the performance of rGO for hydrogen storage. As a proof of concept experiment, a novel strategy is developed to fabricate the binder-free sandwich-structured rGO/Co1−xS/rGO hybrid paper via facile ball milling and filtration process. Based on the structure investigation, Co1−xS is immobilized in the space between the individual rGO sheets by the creation of chemical “bridges” (C S bonds). Through the C S bonds, the atomic hydrogen is transferred from Co1−xS to rGO accompanying a C H chemical bond formation. When used as an electrode, the hybrid paper exhibits an improved hydrogen storage capacity of 3.82 wt% and, most importantly, significant cycling stability for up to 50 cycles. Excluding the direct hydrogen storage contribution from the Co1−xS in the hybrid paper, the hydrogen storage ability of rGO is enhanced by 10× through the spillover effects caused by the Co1−xS modifier.

Published

2017

14. Hydrogen storage characteristics of carbon fibers derived from rice straw and paper mulberry.

Author

Hwang, Sung-Ho, Choi, Won Mi, and Lim, Sang Kyoo

Subjects

*HYDROGEN storage, *CARBON fibers, *RICE straw, *PAPER mulberry, *SPINNING (Textiles), *CARBONIZATION

Abstract

Highly porous carbon fibers based on rice straw and paper mulberry have been successfully prepared via wet spinning and carbonization process. From the comparison of the morphological structure and specific surface area, the porous carbon fibers derived from rice straw shows a high specific surface area of 2260 m 2 /g. This material exhibits excellent hydrogen storage properties with a gravimetric hydrogen uptakes of 4.35 wt% at 77 K and 10 bar. [ABSTRACT FROM AUTHOR]

Published

2016

15. Position Paper: Hydrogen Spillover Limitations for Onboard Hydrogen Storage

Author

Thomas Gennett

Subjects

Hydrogen storage, Materials science, Nuclear engineering, Hydrogen spillover

Published

2019

16. Kinetic and dynamic analysis of hydrogen-enrichment mixtures in combustor systems – A review paper

Author

Mahar Diana Hamid, Sina Davazdah Emami, Rafiziana Md. Kasmani, Khairiah Mohd Mokhtar, and Che Rosmani Che Hassan

Subjects

Pollutant, Waste management, Hydrogen, Renewable Energy, Sustainability and the Environment, business.industry, Fossil fuel, Kinetic analysis, chemistry.chemical_element, 02 engineering and technology, 010402 general chemistry, 021001 nanoscience & nanotechnology, Kinetic energy, Combustion, 01 natural sciences, 0104 chemical sciences, Hydrogen storage, chemistry, Combustor, 0210 nano-technology, business

Abstract

Based on recent developments, hydrogen-based combustion systems have received wide attention, mainly due to increasing awareness of enduring environmental pollutants and restricted access to fossil fuel usage. In the relevant literature, there are evidences of the possibilities on the partial or total replacement of hydrocarbon fuels with hydrogen in power plants and vehicle engines. However, some challenging issues particularly on hydrogen storage are remained to be resolved. This paper reviews and comments on addressing the effectiveness of hydrogen-enrichment on the engines and burners׳ performance includes the chemical kinetic analysis, the flame propagation structures and the effects of inhibitors on global burning velocity of hydrogen–hydrocarbon mixtures in different combustion bombs, chambers and vessels. It is recommended that future researches should aim towards the different application of hydrogen–hydrocarbon i.e. transportation and clean energy carrier.

Published

2016

17. Enhanced hydrogen storage in sandwich-structured rGO/Co1−xS/rGO hybrid papers through hydrogen spillover.

Author

Han, Lu, Qin, Wei, Jian, Jiahuang, Liu, Jiawei, Wu, Xiaohong, Gao, Peng, Hultman, Benjamin, and Wu, Gang

Subjects

*HYDROGEN storage, *GRAPHENE oxide, *ATOMIC hydrogen, *COBALT sulfide, *CHEMICAL bonds

Abstract

Reduced graphene oxide (rGO) based two-dimensional (2D) structures have been fabricated for electrochemical hydrogen storage. However, the effective transfer of atomic hydrogen to adjacent rGO surfaces is suppressed by binders, which are widely used in conventional electrochemical hydrogen storage electrodes, leading to a confining of the performance of rGO for hydrogen storage. As a proof of concept experiment, a novel strategy is developed to fabricate the binder-free sandwich-structured rGO/Co 1−x S/rGO hybrid paper via facile ball milling and filtration process. Based on the structure investigation, Co 1−x S is immobilized in the space between the individual rGO sheets by the creation of chemical “bridges” (C S bonds). Through the C S bonds, the atomic hydrogen is transferred from Co 1−x S to rGO accompanying a C H chemical bond formation. When used as an electrode, the hybrid paper exhibits an improved hydrogen storage capacity of 3.82 wt% and, most importantly, significant cycling stability for up to 50 cycles. Excluding the direct hydrogen storage contribution from the Co 1−x S in the hybrid paper, the hydrogen storage ability of rGO is enhanced by 10× through the spillover effects caused by the Co 1−x S modifier. [ABSTRACT FROM AUTHOR]

Published

2017

18. The hydrogen economy – Vision or reality? 1 1This paper is also published as Chapter 11 ‘The hydrogen economy – vision or reality?’ in Compendium of Hydrogen Energy Volume 4: Hydrogen Use, Safety and the Hydrogen Economy, Edited by Michael Ball, Angelo Basile and T. Nejat Veziroglu, published by Elsevier in 2015, ISBN: 978-1-78242-364-5. For further details see: http://www.elsevier.com/books/compendium-of-hydrogen-energy/ball/978-1-78242-364-5

Author

Marcel Weeda and Michael Ball

Subjects

Hydrogen infrastructure, Power to gas, Flexibility (engineering), Renewable Energy, Sustainability and the Environment, business.industry, Energy Engineering and Power Technology, Environmental economics, Condensed Matter Physics, Renewable energy, Hydrogen storage, Fuel Technology, Range (aeronautics), Hydrogen economy, Fuel cells, business

Abstract

When looking at future energy systems, hydrogen offers a range of benefits as a clean energy carrier, which are receiving great attention as policy priorities. This is first and foremost as an alternative fuel in the transport sector. Car makers have recently started the market introduction of fuel cell electric vehicles and are currently entering a pre-commercial phase, as they are progressing from prototype vehicles for demonstration to producing small volumes. At the same time, market development initiatives aiming at implementing hydrogen refuelling station networks are spreading in Europe, Asia, and the USA. But also in recent years, hydrogen electrolysis has gained considerable attention as a potential flexibility option to help facilitate the large-scale integration of intermittent renewable energies. Given the sustained interest in and controversial discussions on the prospects of hydrogen, this paper aims to provide a comprehensive coverage of the most relevant aspects related to the wider use of hydrogen in the energy system, including the most recent developments and insights.

Published

2015

19. Exploring the Technological Advances and Opportunities of Developing Fuel Cell Electric Vehicles: Based on Patent Analysis.

Author

Yuan, Yuxin, Duan, Xuliang, and Yuan, Xiaodong

Subjects

NATURAL language processing, FUEL cells, MANUFACTURING cells, HYDROGEN storage, ELECTRIC motors, FUEL cell vehicles

Abstract

In general, the fuel cell electric vehicle (FCEV) is regarded as more environmentally friendly than other vehicles. However, the commercialization of FCEV technology is hardly fulfilled due to high-cost fuel cells and an inadequate refueling infrastructure. Different technological trajectories of fuel cells are fiercely competitive, and related technologies are iterating quickly. It is an open issue in terms of what are the technological advances achieved or the opportunities for innovators. The paper proposes a novel approach to identify the key components of an FCEV by constructing the directed co-occurrence network of the International Patent Classification (IPC) and then adopts the Natural Language Processing (NLP) to construct the matrix of technology characteristics and functions. It is suitable to analyze the sentence structure of Subject–Action–Object (SAO) in patent documents by utilizing the NLP technology, which can help computers understand the text and communicate with us. The paper finds that the advances achieved in the fuel cell field are fuel cell composition, manufacturing fuel cells, and providing energy using fuel cells, and the advance in electric motors is supplying power for fuel cell vehicles, while the advances in hydrogen storage are to manage and store hydrogen. By contrast, the opportunities for innovators are to develop the control, diagnosis, and performance of the control system and hydrogen filling. This paper will be a contribution towards a better understanding of the advances and opportunities for developing FCEV technology. [ABSTRACT FROM AUTHOR]

Published

2024

20. Comment on the paper titled"Two-dimensional Sc2C: A reversible and high capacity hydrogen storage material predicted by first-principles calculations" by Hu et al., International Journal of Hydrogen Energy, 2014; 69, 1–4.

Author

Santhosh, Archa and Ravindran, P.

Subjects

*HYDROGEN storage, *HYDROGEN as fuel, *BINDING energy, *DENSITY functional theory, *MAGNESIUM hydride

Abstract

Hu et al. reported the hydrogen storage properties of Sc 2 C and Ti 2 C based MXene phases utilizing density functional theory (DFT) as implemented in the CASTEP code [1, 2]. Based on such calculations, the authors suggest that the MXenes should be a new family of potential hydrogen storage media. Their results claim a maximum hydrogen storage capacity of 9.0 wt% with an average binding energy of 0.164 eV/H 2 in Sc 2 C MXene indicating Kubas-type interaction between H 2 and the MXene. These investigations are of prime importance since they provide insight about further applications of MXenes for hydrogen storage. In these calculations they have used local density approximation (LDA) to estimate the adsorption energies. However, binding energies for H 2 with the MXene phases mentioned above obtained from more accurate calculations based on Generalised Gradient Approximation (GGA) and calculation including dispersion correction (GGA + vdW) show very weak binding energy (∼ 0.064 e V / H 2 ) suggesting weak physical interactions between H 2 and the MXene phases. Our accurate DFT calculations predict that these MXene phases are not suitable for hydrogen storage at realistic conditions. So we conclude that appropriate exchange-correlation functional should be used to extract hydrogen adsorption energies in nano-phases to describe their hydrogen storage properties reliably. [ABSTRACT FROM AUTHOR]

Published

2020

21. Electrochemical hydrogen storage in single-walled carbon nanotube paper

Author

Gordon G. Wallace, Zhenguo Huang, Zaiping Guo, Hua-Kun Liu, S.H. Ng, Chee O. Too, and Jiazhao Wang

Subjects

Paper, Nanotube, Materials science, Hydrogen, Biomedical Engineering, chemistry.chemical_element, Ultrafiltration, Bioengineering, Carbon nanotube, Electrochemistry, law.invention, Absorption, Hydrogen storage, law, Materials Testing, Nanotechnology, General Materials Science, Composite material, Particle Size, Nanotubes, Carbon, General Chemistry, Carbon black, Condensed Matter Physics, chemistry, Chemical engineering, Cyclic voltammetry, Carbon

Abstract

Single-walled carbon nanotube (SWNT) papers were successfully prepared by dispersing SWNTs in Triton X-100 solution, then filtered by PVDF membrane (0.22 μm pore size). The electrochemical behavior and the reversible hydrogen storage capacity of single-walled carbon nanotube (SWNT) papers have been investigated in alkaline electrolytic solutions (6 N KOH) by cyclic voltammetry, linear micropolarization, and constant current charge/discharge measurements. The effect of thickness and the addition of carbon black on hydrogen adsorption/desorption were also investigated. It was found that the electrochemical charge–discharge mechanism occurring in SWNT paper electrodes is somewhere between that of carbon nanotubes (physical process) and that of metal hydride electrodes (chemical process), and consists of a charge-transfer reaction (Reduction/Oxidation) and a diffusion step (Diffusion).

Published

2006

22. A multi-objective stochastic optimization model for combined heat and power virtual power plant considering carbon recycling and utilizing.

Author

Zhang, Fuqiang, Gong, Yichun, Zhang, Xiangcheng, Liu, Fei, Zhou, Qingqing, Yang, Shenbo, Fan, Wei, Pan, Xianyou, and Zhang, Suhan

Subjects

CARBON sequestration, HYDROGEN storage, CARBON emissions, POTENTIAL energy, POWER resources

Abstract

In order to give full play to the energy supply potential of distributed energy resources, this paper studies the scheduling optimization of CHP-VPP. First, the CHP unit and various distributed energy sources are aggregated into VPP. Carbon recycling and utilizing are realized through carbon capture and power-to-gas devices. At the same time, carbon storage and hydrogen storage devices are added to decouple carbon capture and P2G procedures. Then, the risk of VPP real-time scheduling is quantified through uncertainty scenario generation and CVaR. Finally, with the goals of operating cost, carbon emission, and operation risk, a multi-objective stochastic scheduling optimization model of VPP is constructed, and the subjective and objective ensemble weighting method is used to solve the problem. The example results show that the proposed method can boost the wastage of wind and photovoltaic power, and also lower the carbon emissions of VPPs. [ABSTRACT FROM AUTHOR]

Published

2024

23. Interagency coordination meeting on energy storage. [15 papers]

Published

1977

24. Lightweight Type-IV Hydrogen Storage Vessel Boss Based on Optimal Sealing Structure.

Author

Shao, Weidong, Wang, Jing, Hu, Donghai, Lu, Dagang, and Xu, Yinjie

Subjects

HYDROGEN storage, FUEL cell vehicles, TRAFFIC safety, THREE-dimensional printing

Abstract

The seal and weight of the Type IV hydrogen storage vessel are the key problems restricting the safety and driving range of fuel cell vehicles. The boss, as a metal medium connecting the inner liner of the Type IV hydrogen storage vessel with the external pipeline, affects the sealing performance of the Type IV hydrogen storage vessel, and there is no academic research on the weight of the boss. Therefore, according to the force characteristics of the boss, this paper divides the upper and lower areas (valve column and plate). The valve column with seal optimization and light weight is manufactured with a 3D printing additive, while the plate bearing and transferring the internal pressure load is manufactured by forging. Firstly, a two-dimensional axisymmetric simulation model of the sealing ring was established, and the effects of different compression rates on its seal performance were analyzed. Then, the size and position of the sealing groove were sampled, simulated, and optimized based on the Latin Hypercube method, and the reliability of the optimal seal structure was verified by experiments. Finally, the Solid Isotropic Material with Penalization (SIMP) topology method was used to optimize the weight of the boss with optimal sealing structure, and the reconstructed model was checked and analyzed. The results show that the weight of the optimized boss is reduced by 9.6%. [ABSTRACT FROM AUTHOR]

Published

2024

25. 氢储能系统容量双层鲁棒随机优化配置方法.

Author

刘明波, 曾贵华, 董萍, and 林舜江

Subjects

ENERGY storage equipment, COLUMN generation (Algorithms), ENERGY storage, HYDROGEN storage, ENERGY consumption, STOCHASTIC programming

Abstract

Copyright of Journal of South China University of Technology (Natural Science Edition) is the property of South China University of Technology 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. Revolution in Renewables: Integration of Green Hydrogen for a Sustainable Future.

Author

Zhang, Jimiao and Li, Jie

Subjects

GREEN fuels, CLEAN energy, ENERGY development, RENEWABLE energy sources, SUSTAINABILITY, MICROGRIDS

Abstract

In recent years, global efforts towards a future with sustainable energy have intensified the development of renewable energy sources (RESs) such as offshore wind, solar photovoltaics (PVs), hydro, and geothermal. Concurrently, green hydrogen, produced via water electrolysis using these RESs, has been recognized as a promising solution to decarbonizing traditionally hard-to-abate sectors. Furthermore, hydrogen storage provides a long-duration energy storage approach to managing the intermittency of RESs, which ensures a reliable and stable electricity supply and supports electric grid operations with ancillary services like frequency and voltage regulation. Despite significant progress, the hydrogen economy remains nascent, with ongoing developments and persistent uncertainties in economic, technological, and regulatory aspects. This paper provides a comprehensive review of the green hydrogen value chain, encompassing production, transportation logistics, storage methodologies, and end-use applications, while identifying key research gaps. Particular emphasis is placed on the integration of green hydrogen into both grid-connected and islanded systems, with a focus on operational strategies to enhance grid resilience and efficiency over both the long and short terms. Moreover, this paper draws on global case studies from pioneering green hydrogen projects to inform strategies that can accelerate the adoption and large-scale deployment of green hydrogen technologies across diverse sectors and geographies. [ABSTRACT FROM AUTHOR]

Published

2024

27. The Progress of Autoignition of High-Pressure Hydrogen Gas Leakage: A Comprehensive Review.

Author

Cui, Gan, Li, Yixuan, Wu, Di, Li, Hongwei, Liu, Huan, Xing, Xiao, and Liu, Jianguo

Subjects

HYDROGEN as fuel, GAS leakage, HYDROGEN storage, CLEAN energy, ENERGY storage

Abstract

As a paradigm of clean energy, hydrogen is gradually attracting global attention. However, its unique characteristics of leakage and autoignition pose significant challenges to the development of high-pressure hydrogen storage technologies. In recent years, numerous scholars have made significant progress in the field of high-pressure hydrogen leakage autoignition. This paper, based on diffusion ignition theory, thoroughly explores the mechanism of high-pressure hydrogen leakage autoignition. It reviews the effects of various factors such as gas properties, burst disc rupture conditions, tube geometric structure, obstacles, etc., on shock wave growth patterns and autoignition characteristics. Additionally, the development of internal flames and propagation characteristics of external flames after ignition kernels generation are summarized. Finally, to promote future development in the field of high-pressure hydrogen energy storage and transportation, this paper identifies deficiencies in the current research and proposes key directions for future research. [ABSTRACT FROM AUTHOR]

Published

2024

28. A two-stage robust configuration optimization model and solution algorithm for new flexibility resources considering uncertainty response characterization.

Author

Hailin Yang, Fei Liu, Hui Yang, Xiangcheng Zhang, and Liantao Liu

Subjects

STRUCTURAL optimization, ROBUST optimization, WIND power, STOCHASTIC programming, ENERGY storage, RENEWABLE energy sources, HYDROGEN storage

Abstract

As the proportion of new energy continues to increase, the safety and stability of the new power system are challenged, urgently requiring the allocation of new flexible resources. This paper proposes a two-stage robust capacity optimization model considering flexibility demand constraints. Firstly, the uncertain characteristics of new energy are described, and a model of flexible resource adjustment capacity is established. Then, uncertain parameters are introduced to construct a robust capacity optimization model considering supply-demand balance, solved by column constraint generation algorithm and KKT theorem. Finally, a power system in a certain region of China is selected as the simulation object for empirical analysis to verify the effectiveness of the constructed model. The results show that the two-stage robust configuration optimization model constructed in this paper can address the uncertainty of power system and the flexibility demand brought by new energy, and the planning results can achieve a balance between the safety and economy of the new power system. [ABSTRACT FROM AUTHOR]

Published

2024

29. Green Hydrogen Energy Systems: A Review on Their Contribution to a Renewable Energy System.

Author

Gómez, Julián and Castro, Rui

Subjects

GREEN fuels, CLEAN energy, RENEWABLE energy sources, CLIMATE change, RENEWABLE energy transition (Government policy), HYDROGEN as fuel

Abstract

Accelerating the transition to a cleaner global energy system is essential for tackling the climate crisis, and green hydrogen energy systems hold significant promise for integrating renewable energy sources. This paper offers a thorough evaluation of green hydrogen's potential as a groundbreaking alternative to achieve near-zero greenhouse gas (GHG) emissions within a renewable energy framework. The paper explores current technological options and assesses the industry's present status alongside future challenges. It also includes an economic analysis to gauge the feasibility of integrating green hydrogen, providing a critical review of the current and future expectations for the levelized cost of hydrogen (LCOH). Depending on the geographic location and the technology employed, the LCOH for green hydrogen can range from as low as EUR 1.12/kg to as high as EUR 16.06/kg. Nonetheless, the findings suggest that green hydrogen could play a crucial role in reducing GHG emissions, particularly in hard-to-decarbonize sectors. A target LCOH of approximately EUR 1/kg by 2050 seems attainable, in some geographies. However, there are still significant hurdles to overcome before green hydrogen can become a cost-competitive alternative. Key challenges include the need for further technological advancements and the establishment of hydrogen policies to achieve cost reductions in electrolyzers, which are vital for green hydrogen production. [ABSTRACT FROM AUTHOR]

Published

2024

30. Isolated Work of a Multi-Energy Carrier Microgrid.

Author

Knežević, Sonja and Šošić, Darko

Subjects

DISTRIBUTED power generation, FUEL cell vehicles, RENEWABLE energy sources, FUEL cells, MICROGRIDS, ELECTRIC vehicle batteries, ENERGY storage, ENERGY consumption

Abstract

With the increasing use of renewable energy sources and decentralized power systems, certain challenges have emerged in meeting consumers' electrical energy demands. The intermittent nature of renewable energy generation means that it cannot always align with consumers' needs, resulting in periods of excess energy production when it is not required. To bridge this gap between production and consumption, energy storage systems are necessary. This paper defines the work of an isolated microgrid, which consists of renewable sources (wind and PV) for energy production, households with electric vehicles as consumers, and a combined storage system. This storage system is made from batteries, hydrogen storage, and a control system that defines the best use of the storage. Stored energy is utilized through fuel cells to generate electricity for consumption when renewable sources cannot meet the demand. This paper presents the principles of electrolysis and models of individual elements within such a system, as well as the definition and principle of control of the system functionality based on rules and conditions. The proposed control system aims to increase the energy storage lifecycle by deciding when and how to utilize which type of storage and define a self-sufficient microgrid based on renewable sources of production. An economic analysis of the storage part of the system was carried out in which the levelized cost of energy stored and the NPC of the storage systems are calculated. A simulation of the system's operation is conducted using one-hour measurements of wind turbines, solar panels, and household consumption in Serbia. To analyze the system's behavior, a one-week time horizon is considered. [ABSTRACT FROM AUTHOR]

Published

2024

31. State of the Art on Relative Permeability Hysteresis in Porous Media: Petroleum Engineering Application.

Author

Lan, Yubo, Guo, Ping, Liu, Yong, Wang, Shuoshi, Cao, Sheng, Zhang, Jiang, Sun, Wenjing, Qi, Dongyan, and Ji, Qiang

Subjects

PETROLEUM engineering, PERMEABILITY, CARBON sequestration, ENHANCED oil recovery, OIL fields, POROUS materials, HYSTERESIS

Abstract

This paper delivers an examination of relative permeability hysteresis in porous media in the field of petroleum engineering, encompassing mathematical modeling, experimental studies, and their practical implications. It explores two-phase and three-phase models, elucidating the generation of scanning curves and their applications in various porous materials. Building on the research of traditional relative permeability hysteresis models, we have incorporated literature on forward calculations of relative permeability based on digital rock core models. This offers a new perspective for studying the hysteresis effect in relative permeability. Additionally, it compiles insights from direct relative permeability and flow-through experiments, accentuating the methodologies and key findings. With a focus on enhanced oil recovery (EOR), carbon capture, utilization and sequestration (CCUS), and hydrogen storage applications, the paper identifies existing research voids and proposes avenues for future inquiry, laying the groundwork for advancing recovery techniques in oil and gas sectors. [ABSTRACT FROM AUTHOR]

Published

2024

32. Innovative Design of Solid-State Hydrogen Storage and Proton Exchange Membrane Fuel Cell Coupling System with Enhanced Cold Start Control Strategy.

Author

Gao, Jianhua, Zhou, Su, Fan, Lei, Zhang, Gang, Jiang, Yongyuan, Shen, Wei, and Zhai, Shuang

Subjects

PROTON exchange membrane fuel cells, HYDROGEN storage, FUEL cells, THERMODYNAMICS, COLD storage

Abstract

This paper presents an innovative thermally coupled system architecture with a parallel coolant-heated metal hydride tank (MHT) designed to satisfy the hydrogen supply requirements of proton exchange membrane fuel cell s(PEMFCs). This design solves a problem by revolutionising the cold start capability of PEMFCs at low temperatures. During the design process, LaNi5 was selected as the hydrogen storage material, with thermodynamic and kinetic properties matching the PEMFC operating conditions. Afterwards, the MHT and thermal management subsystem were customised to integrate with the 70 kW PEMFC system to ensure optimal performance. Given the limitations of conventional high-pressure gaseous hydrogen storage for cold starting, this paper provides insights into the challenges faced by the PEMFC-MH system and proposes an innovative cold start methodology that combines internal self-heating and externally assisted preheating techniques, aiming to optimise cold start time, energy consumption, and hydrogen utilisation. The results show that the PEMFC-MH system utilises the heat generated during hydrogen absorption by the MHT to preheat the PEMFC stack, and the cold start time is only 101 s, which is 59.3% shorter compared to that of the conventional method. Meanwhile, the cold start energy consumption is reduced by 62.4%, achieving a significant improvement in energy efficiency. In conclusion, this paper presents a PEMFC-MH system design that achieves significant progress in terms of time saving, energy consumption, and hydrogen utilisation. [ABSTRACT FROM AUTHOR]

Published

2024

33. Challenges of Green Transition in Polymer Production: Applications in Zero Energy Innovations and Hydrogen Storage.

Author

Rezić, Iva and Meštrović, Ernest

Subjects

HYDROGEN storage, HYDROGEN as fuel, SUSTAINABILITY, ENVIRONMENTAL responsibility, POLYMERS, GREEN technology, TECHNOLOGICAL innovations, HYDROGEN production

Abstract

The green transition in the sustainable production and processing of polymers poses multifaceted challenges that demand integral comprehensive solutions. Specific problems of presences of toxic trace elements are often missed and this prevents shifting towards eco-friendly alternatives. Therefore, substantial research and the development of novel approaches is needed to discover and implement innovative, sustainable production materials and methods. This paper is focused on the most vital problems of the green transition from the aspect of establishing universally accepted criteria for the characterization and classification of eco-friendly polymers, which is essential to ensuring transparency and trust among consumers. Additionally, the recycling infrastructure needs substantial improvement to manage the end-of-life stage of polymer products effectively. Moreover, the lack of standardized regulations and certifications for sustainable polymers adds to the complexity of this problem. In this paper we propose solutions from the aspect of standardization protocols for the characterization of polymers foreseen as materials that should be used in Zero Energy Innovations in Hydrogen Storage. The role model standards originate from eco-labeling procedures for materials that come into direct or prolonged contact with human skin, and that are monitored by different methods and testing procedures. In conclusion, the challenges of transitioning to green practices in polymer production and processing demands a concerted effort from experts in the field which need to emphasize the problems of the analysis of toxic ultra trace and trace impurities in samples that will be used in hydrogen storage, as trace impurities may cause terrific obstacles due to their decreasing the safety of materials. Overcoming these obstacles requires the development and application of current state-of-the-art methodologies for monitoring the quality of polymers during their recycling, processing, and using, as well as the development of other technological innovations, financial initiatives, and a collective commitment to fostering a sustainable and environmentally responsible future for the polymer industry and innovations in the field of zero energy applications. [ABSTRACT FROM AUTHOR]

Published

2024

34. Stabilité mécanique à long terme des cavités salines de stockage d'hydrogène.

Author

Djizanne, Hippolyte, Brouard, Benoit, Hévin, Grégoire, and Lekoko, Carelle

Subjects

HYDROGEN storage, SAFETY factor in engineering, GAS storage, CAVES, ENERGY storage

Abstract

Copyright of Revue Française de Géotechnique is the property of EDP Sciences 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

35. The Storage Process of Electric Energy Produced from Renewable Sources from Hydrogen to Domestic Hot Water Heating.

Author

Stoica, Dorel, Mihăescu, Lucian, Lăzăroiu, Gheorghe, and Lăzăroiu, George Cristian

Subjects

GREEN fuels, HYDROGEN storage, ELECTRIC power distribution grids, RENEWABLE energy sources, ENERGY storage

Abstract

The expansion of renewable electricity storage technologies, including green hydrogen storage, is spurred by the need to address the high costs associated with hydrogen storage and the imperative to increase storage capacity. The initial section of the paper examines the intricacies of storing electricity generated from renewable sources, particularly during peak periods, through green hydrogen. Two primary challenges arise: firstly, the complexity inherent in the storage technology and its adaptation for electricity reproduction; and secondly, the cost implications throughout the technological chain, resulting in a significant increase in the price of the reproduced energy. Electric energy storage emerges as a pivotal solution to accommodate the growing proportion of renewable energy within contemporary energy systems, which were previously characterized by high stability. During the transition to renewable-based energy systems, optimizing energy storage technology to manage power fluctuations is crucial, considering both initial capital investment and ongoing operational expenses. The economic analysis primarily focuses on scenarios where electricity generated from renewable sources is integrated into existing power grids. The subsequent part of this paper explores the possibility of localizing excess electricity storage within a specific system, illustrated by domestic hot water. [ABSTRACT FROM AUTHOR]

Published

2024

36. The Role of Flexibility in the Integrated Operation of Low-Carbon Gas and Electricity Systems: A Review.

Author

Amiri, Mohammad Mehdi, Ameli, Mohammad Taghi, Strbac, Goran, Pudjianto, Danny, and Ameli, Hossein

Subjects

RENEWABLE energy sources, ENERGY demand management, ELECTRICITY, GASES, RESEARCH personnel

Abstract

The integration of gas and electricity networks has emerged as a promising approach to enhance the overall flexibility of energy systems. As the transition toward sustainable and decarbonized energy sources accelerates, the seamless coordination between electricity and gas infrastructure becomes increasingly crucial. This paper presents a comprehensive review of the state-of-the-art research and developments concerning the flexibility in the operation of low-carbon integrated gas and electricity networks (IGENs) as part of the whole system approach. Methods and solutions to provide and improve flexibility in the mentioned systems are studied and categorized. Flexibility is the system's ability to deal with changes and uncertainties in the network while maintaining an acceptable level of reliability. The presented review underscores the significance of this convergence in facilitating demand-side management, renewable energy integration, and overall system resilience. By highlighting the technical, economic, and regulatory aspects of such integration, this paper aims to guide researchers, policymakers, and industry stakeholders toward effective decision-making and the formulation of comprehensive strategies that align with the decarbonization of energy systems. [ABSTRACT FROM AUTHOR]

Published

2024

37. Reactivity of Coinage Metal Hydrides for the Production of H 2 Molecules

Author

Iribarren, Iñigo, Sánchez‐Sanz, Goar, Elguero, José, Alkorta, Ibon, Trujillo, Cristina, Ministerio de Ciencia, Innovación y Universidades (España), Comunidad de Madrid, Science Foundation Ireland, Elguero, José [0000-0002-9213-6858], Alkorta, Ibon [0000-0001-6876-6211], Elguero, José, and Alkorta, Ibon

Subjects

Materials science, Full Paper, Hydrogen, chemistry.chemical_element, Coinage metals, coinage hydrides, General Chemistry, Full Papers, Coinage hydrides, hydrogen storage, Metal, Chemistry, Hydrogen storage, QTAIM, chemistry, Group (periodic table), visual_art, visual_art.visual_art_medium, Physical chemistry, Molecule, Reactivity (chemistry), QD1-999, Metallic bonding

Abstract

The formation of molecular hydrogen as well as the possibility of using coinage metal hydrides as a prospective complex to produce hydrogen was presented in this work. Therefore, the reactions involving the interaction between two coinage metal hydrides, MH (M=Cu, Ag and Au, homo and heterodimers), were studied. The free energy profiles corresponding to aforementioned complexation were analysed by means of ab initio methods of quantum chemistry. The characteristics of these intermediates, final complexes and the electron density properties of the established interactions were discussed., The research was financially supported by the Spanish Ministerio de Ciencia, Innovación y Universidades (Projects PGC2018-094644- B-C2), Comunidad de Madrid (PS2018/EMT-4329 AIRTEC-CM) and Science Foundation of Ireland (SFI), grant number 18/SIRG/5517. For the purpose of Open Access, the author has applied a CC BY public copyright licence to any Author Accepted Manuscript version arising from this submission. Thanks are given to the CTI (CSIC) and the Irish Centre for High-End Computing (ICHEC) for their continued computational support. We would like to thank Dr. José A. Gámez for all useful ideas and discussions

Published

2021

38. Progress in hydrogen fuel cell vehicles and up-and-coming technologies for eco-friendly transportation: an international assessment

Author

Soleimani, Alireza, Hosseini Dolatabadi, Sayed Hamid, Heidari, Mehrdad, Pinnarelli, Anna, Mehdizadeh Khorrami, Behrouz, Luo, Yang, Vizza, Pasquale, and Brusco, Giovanni

Published

2024

39. High‐performance metallic materials for applications in infrastructure and energy sectors.

Author

Afshan, Sheida, Li, Weiran, Wang, Zhenzhou, Bailey, Wendell, and Wang, Yikun

Subjects

ENERGY infrastructure, INFRASTRUCTURE (Economics), ENERGY industries, STAINLESS steel, STEEL tanks, STORAGE tanks, BOLTED joints

Abstract

High performance steels, such as stainless steels, have many desirable characteristics that warrant their use in various sectors, including infrastructure and energy applications. This paper is concerned with two of such applications: (i) the use of stainless steel for large‐scale liquid hydrogen storage tanks, which is a requirement for the future hydrogen energy network, and (ii) the use of stainless steel in steel‐framed buildings to enhance their robustness under extreme loading conditions. The paper begins with a discussion of the technical challenges associated with the material behaviour of stainless steel storage tanks under extreme temperature and pressure conditions. It presents and discusses the results of a pilot experimental programme that investigates the mechanical behaviour of stainless steel 304 L material under cryogenic 20 k hydrogen environment. Next, to demonstrate the benefits of the strategic use of stainless steel in the key connection parts of steel‐framed structures, the paper presents the setup for a new test programme that investigates the behaviour of stainless steel beam‐to‐column connections, using A4‐70 bolts and EN1.4301 plates, under a column removal scenario. The numerical modelling prediction results of the specimens are presented, and comparisons with carbon steel counterparts are made and discussed. [ABSTRACT FROM AUTHOR]

Published

2023

40. Research Progress and Application Prospects of Solid-State Hydrogen Storage Technology.

Author

Xu, Yaohui, Zhou, Yang, Li, Yuting, and Ding, Zhao

Subjects

HYDROGEN storage, ELECTRIC vehicles, HYDROGEN as fuel, CARBON offsetting, POWER resources

Abstract

Solid-state hydrogen storage technology has emerged as a disruptive solution to the "last mile" challenge in large-scale hydrogen energy applications, garnering significant global research attention. This paper systematically reviews the Chinese research progress in solid-state hydrogen storage material systems, thermodynamic mechanisms, and system integration. It also quantitatively assesses the market potential of solid-state hydrogen storage across four major application scenarios: on-board hydrogen storage, hydrogen refueling stations, backup power supplies, and power grid peak shaving. Furthermore, it analyzes the bottlenecks and challenges in industrialization related to key materials, testing standards, and innovation platforms. While acknowledging that the cost and performance of solid-state hydrogen storage are not yet fully competitive, the paper highlights its unique advantages of high safety, energy density, and potentially lower costs, showing promise in new energy vehicles and distributed energy fields. Breakthroughs in new hydrogen storage materials like magnesium-based and vanadium-based materials, coupled with improved standards, specifications, and innovation mechanisms, are expected to propel solid-state hydrogen storage into a mainstream technology within 10–15 years, with a market scale exceeding USD 14.3 billion. To accelerate the leapfrog development of China's solid-state hydrogen storage industry, increased investment in basic research, focused efforts on key core technologies, and streamlining the industry chain from materials to systems are recommended. This includes addressing challenges in passenger vehicles, commercial vehicles, and hydrogen refueling stations, and building a collaborative innovation ecosystem involving government, industry, academia, research, finance, and intermediary entities to support the achievement of carbon peak and neutrality goals and foster a clean, low-carbon, safe, and efficient modern energy system. [ABSTRACT FROM AUTHOR]

Published

2024

41. Highly dispersed Pd nanoparticles on a SiO2 support for dehydrogenation of dodecahydro-N-ethylcarbazole.

Author

Shi, Monan, Zhang, Chunying, Ma, Mengnan, Zhang, Chen, and Huang, Long

Subjects

DEHYDROGENATION, SILANE coupling agents, LIQUID hydrogen, HYDROGEN storage, PRECIOUS metals

Abstract

Liquid organic hydrogen carriers (LOHC) are regarded as a promising hydrogen storage and transportation technology. However, problems of incomplete dehydrogenation and the high dehydrogenation catalyst costs have hindered the development and application of this technology. Therefore, the research and development of a dehydrogenation catalyst with low cost and high reactivity have become the focus of current research in this field. In this paper, we report on a dehydrogenation catalyst with low noble metal loading prepared using amino silane coupling agent. The catalyst showed excellent catalytic performance on dodecahydro-N-ethylcarbazole (12H-NECZ). At 473 K, the hydrogen release of 0.3% Pd–NH2(1) catalyst prepared by the amino modification method is 4.44 wt%, which is 2.1 times that of Pd catalyst prepared using the traditional impregnation method. The amino-modified catalysts with increasing Pd loading of 0.5, 0.8, and 1.0 wt% displayed hydrogen release of 4.96, 5.14 and 5.21 wt%, respectively. The characterization of amnio-modified Pd catalysts showed that Pd was uniformly distributed on the SiO2 support, and the Pd particle size of the 0.3% Pd–NH2(1) catalyst was only 1.6 nm. The reaction kinetic parameters of two catalysts in the 12H-NECZ dehydrogenation were calculated, and the results indicated that the activation energy of the rate-limiting step (4H-NECZ to NECZ) in dehydrogenation was reduced with amnio-modified catalysts compared to impregnated catalysts. By analyzing the relationship between the Pd particle size and turnover frequency (TOF), the optimal Pd particle size in the overall dehydrogenation reaction and each step of the 12H-NECZ dehydrogenation was obtained. [ABSTRACT FROM AUTHOR]

Published

2024

42. An Exploration of Safety Measures in Hydrogen Refueling Stations: Delving into Hydrogen Equipment and Technical Performance.

Author

Genovese, Matteo, Blekhman, David, and Fragiacomo, Petronilla

Subjects

FUELING, SAFETY, HYDROGEN as fuel, HYDROGEN, FIRE detectors, HYDROGEN storage

Abstract

The present paper offers a thorough examination of the safety measures enforced at hydrogen filling stations, emphasizing their crucial significance in the wider endeavor to advocate for hydrogen as a sustainable and reliable substitute for conventional fuels. The analysis reveals a wide range of crucial safety aspects in hydrogen refueling stations, including regulated hydrogen dispensing, leak detection, accurate hydrogen flow measurement, emergency shutdown systems, fire-suppression mechanisms, hydrogen distribution and pressure management, and appropriate hydrogen storage and cooling for secure refueling operations. The paper therefore explores several aspects, including the sophisticated architecture of hydrogen dispensers, reliable leak-detection systems, emergency shut-off mechanisms, and the implementation of fire-suppression tactics. Furthermore, it emphasizes that the safety and effectiveness of hydrogen filling stations are closely connected to the accuracy in the creation and upkeep of hydrogen dispensers. It highlights the need for materials and systems that can endure severe circumstances of elevated pressure and temperature while maintaining safety. The use of sophisticated leak-detection technology is crucial for rapidly detecting and reducing possible threats, therefore improving the overall safety of these facilities. Moreover, the research elucidates the complexities of emergency shut-off systems and fire-suppression tactics. These components are crucial not just for promptly managing hazards, but also for maintaining the station's structural soundness in unanticipated circumstances. In addition, the study provides observations about recent technical progress in the industry. These advances effectively tackle current safety obstacles and provide the foundation for future breakthroughs in hydrogen fueling infrastructure. The integration of cutting-edge technology and materials, together with the development of upgraded safety measures, suggests a positive trajectory towards improved efficiency, dependability, and safety in hydrogen refueling stations. [ABSTRACT FROM AUTHOR]

Published

2024

43. Hydrogen Storage in Porous Rocks: A Bibliometric Analysis of Research Trends.

Author

Uliasz-Misiak, Barbara, Misiak, Jacek, and Lewandowska-Śmierzchalska, Joanna

Subjects

HYDROGEN storage, BIBLIOMETRICS, ROCK analysis, UNDERGROUND storage, TREND analysis

Abstract

Currently, there is an increasing number of research studies on underground storage of hydrogen in porous rocks (aquifers and depleted hydrocarbon fields). An important aspect of this process is the efficiency of hydrogen storage, which is defined as the correct operation of a storage facility (the ability to inject and withdraw an appropriate quantity of gas) and the safety of storage, which is influenced by numerous factors, including geological factors. With an increasing number of publications, gathering knowledge and keeping track of scientific progress is becoming increasingly complex. In addition to the technical interdependence of the parameters analysed, there are also interrelationships between scientific publications addressing issues related to underground hydrogen storage in porous rocks. The aim of this paper is to analyse the literature on hydrogen storage efficiency in porous rocks and, on the basis of the analysis, to identify the most important research trends and issues relevant to their implementation. This article presents an analysis of publications indexed in the SCOPUS database. The analysis included publications that contained expressions related to the relevant search phrases in their title, abstract or keywords. The dynamics of changes in the interest of researchers on the problem of hydrogen storage in porous rocks and the distribution of studies by geographical location (countries) are presented. Based on an analysis of the number of citations, the most influential publications were identified. Using the VOSviewer version 1.6.19 software, clusters reflecting research sub-areas were identified based on co-occurrence analysis, such as geological and reservoir aspects, reservoir engineering aspects, hydrogeological aspects and petrophysical aspects. Bibliometric methods have great potential for performing quantitative confirmation of subjectively delineated research fields and/or examining unexplored areas. The literature on underground hydrogen storage in porous rocks has been growing rapidly since at least 2018, with researchers conducting their studies in four major research streams: geological and reservoir aspects, reservoir engineering aspects, hydrogeological aspects and petrophysical aspects. [ABSTRACT FROM AUTHOR]

Published

2024

44. Key technology and application of AB2 hydrogen storage alloy in fuel cell hydrogen supply system.

Author

Ming Yao, Jianguang Yuan, Bao Zhang, Youhua Yan, Shaoxiong Zhou, and Ying Wu

Subjects

HYDROGEN storage, HYDROGEN absorption & adsorption, FUEL cell power plants, HYDROGEN production, CHEMICAL kinetics

Abstract

At present, there is limited research on the application of fuel cell power generation system technology using solid hydrogen storage materials, especially in hydrogen-assisted two-wheelers. Considering the disadvantages of low hydrogen storage capacity and poor kinetics of hydrogen storage materials, our primary focus is to achieve smooth hydrogen ab-/desorption over a wide temperature range to meet the requirements of fuel cells and their integrated power generation systems. In this paper, the Ti0.9Zr0.1Mn1.45V0.4Fe0.15 hydrogen storage alloy was successfully prepared by arc melting. The maximum hydrogen storage capacity reaches 1.89 wt% at 318 K. The alloy has the capability to absorb 90% of hydrogen storage capacity within 50 s at 7 MPa and release 90% of hydrogen within 220 s. Comsol Multiphysics 6.0 software was used to simulate the hydrogen ab-/desorption processes of the tank. The flow rate of cooling water during hydrogen absorption varied in a gradient of (0.02 + x) m s-1 (x = 0, 0.02, 0.04, 0.06, 0.08, 0.1, 0.12). Cooling water flow rate is positively correlated with the hydrogen absorption rate but negatively correlated with the cost. When the cooling rate is 0.06 m s-1, both simulation and experimentation have shown that the hydrogen storage tank is capable of steady hydrogen desorption for over 6 h at a flow rate of 2 L min-1. Based on the above conclusions, we have successfully developed a hydrogen-assisted two-wheeler with a range of 80 km and achieved regional demonstration operations in Changzhou and Shaoguan. This paper highlights the achievements of our team in the technological development of fuel cell power generation systems using solid hydrogen storage materials as hydrogen storage carriers and their application in two-wheelers in recent years. [ABSTRACT FROM AUTHOR]

Published

2024

45. Flexibilization of Biorefineries: Tuning Lignin Hydrogenation by Hydrogen Partial Pressure

Author

Yun Xu, Ángel Morales-García, Wolfgang Schrader, Michael Dierks, Zhengwen Cao, Pengbo Lyu, Petr Nachtigall, and Ferdi Schüth

Subjects

Hydrogen, General Chemical Engineering, lignin, chemistry.chemical_element, Biomass, 02 engineering and technology, 010402 general chemistry, 01 natural sciences, Oxygen, Catalysis, Hydrogen storage, chemistry.chemical_compound, Environmental Chemistry, Lignin, General Materials Science, Full Paper, biomass, Full Papers, 021001 nanoscience & nanotechnology, renewable energy, Product distribution, 0104 chemical sciences, waste valorization, Hydrogen partial pressure, General Energy, chemistry, Chemical engineering, hydrogen, 0210 nano-technology

Abstract

The present study describes an interesting and practical catalytic system that allows flexible conversion of lignin into aromatic or aliphatic hydrocarbons, depending on the hydrogen partial pressure. A combination of experiment and theory shows that the product distribution between aromatics and aliphatics can be simply tuned by controlling the availability of hydrogen on the catalyst surface. Noticeably, these pathways lead to almost complete oxygen removal from lignin biomass, yielding high‐quality hydrocarbons. Thus, hydrogen–lignin co‐refining by using this catalytic system provides high flexibility in hydrogen storage/consumption towards meeting different regional and temporal demands., Better together: A practical catalytic system is described that allows flexible conversion of lignin into aromatic or aliphatic hydrocarbons, depending on the hydrogen partial pressure. The hydrogen‐lignin co‐refining using this catalytic system provides high flexibility in hydrogen storage/consumption towards meeting different regional and temporal demands.

Published

2020

46. Solar PV system with maximum power tracking.

Author

Gusev, G.N., Zhdaneev, O.V., Gainullin, M.E., Argastsev, A. Yu, and Lapkin, D.N.

Abstract

The paper investigates the state-of-the-art architecture of photovoltaic systems (PVS) by evaluating the performance of the developed maximum power point tracking (MPPT) algorithm of fuzzy particle swarm optimization (FPSO) for temperate continental latitudes. The material of the paper gives an evaluation of traditional MPPT algorithms in relation to the state-of-the-art FPSO algorithm. The study summarizes the problems of On-Grid PV systems and analyzes methods of solving them by combining them with hydrogen technologies. The paper summaries the experience of observations of climatic factors and solar resources on the example of the Russian Federation. Thus, in 2023, the average winter temperature exceeded the norm by 4.7 °C, and the average summer temperature exceeded the norm by 4.9 °C compared to 2022. The paper analyses the level of insolation, which increased by 0.03 kWh/m2 by regions of Russia for the period 2022–2023. The experimental part of the work was carried out at the solar power plant (SPP) «Kalmykskaya» with coordinates 53.422832 north latitude and 55.266895 east longitude. The watt-volt field characteristic of photovoltaic modules (PVM) connected to the inverter was obtained experimentally. When compared, the correlation coefficient between the experimental power (P) and voltage (U) of the panels was found to be higher than that of the ideal panels, 0.933 versus 0.914. The correlation coefficient between the ideal P(U) function and the experimental one is (−0.475). The data for calculating the coefficient of performance (COP) of the implemented MPPT algorithm was also obtained experimentally, which was about 98.7%. The reliability of the data used in the calculations was confirmed by two independent means of measurement, the difference of the obtained results was less than 1%. In the last part of the experiment of this study, the dependence of insolation in a given geographical point on the generated PV field power was evaluated. The correlation coefficient was 0.47, while the inverter output voltage was maintained in the nominal range of (600 ± 20%)V. Thus, the authors of the study experimentally proved the efficiency of using MPPT on FPSO in temperate continental climate with duration of sunshine T = 1850 h per year. The effectiveness of the FPSO algorithm under the conditions of inverter distance from the common point of the DC switching cabinet (DСCC) has been confirmed. The effectiveness of the MPPT algorithm based on FPSO under conditions of partial shading, increased cloud cover and increased air temperature is concluded. Using the description of the current architecture of On-Grid SPP, the authors draw attention to the impossibility of operation of such systems without the presence of voltage in the reference network. In addition, the impossibility of the system operation at the value of PVM power over 1500 kW and at the voltage of panels less than 900 V is noted. To modernize the existing PVS architecture, for the first time, the use of a DCCC and an inverter with implemented MPPT on the FPSO in combination with a hydrogen (H 2) production unit and nickel-hydrogen (Ni–H 2) batteries is proposed. The researchers propose that when the PVM field voltage is below 900 V and when the PVM field power exceeds 1500 kW, energy can be diverted to H2 generation or to charge Ni–H2 batteries via a DCCC controller. Such an architecture will improve the continuity and efficiency of the PVS, reduce the carbon footprint, and allow the PVS to be used as an industrial uninterruptible power supply (UPS). The authors see the lack of standardization of implemented projects based on the ESG principle as the main problem of alternative energy development. [ABSTRACT FROM AUTHOR]

Published

2024

47. Numerical study on hydrogen desorption performance of a new MgH2 solid-state hydrogen storage device.

Author

Wang, Weishu, Wang, Miaojia, Wang, Jie, Chen, Xianzhi, Xu, Weihui, and Wang, Wei

Subjects

*HYDROGEN evolution reactions, *HEAT transfer fluids, *HYDROGEN storage, *HEAT pipes, *HEAT exchangers

Abstract

To explore the factors affecting the hydrogen evolution performance of a new MgH 2 solid-state hydrogen storage heat exchanger, this paper designs the MgH 2 solid-state hydrogen storage device. The study numerically investigates the influence of operating parameters and structural parameters on the hydrogen release reaction. The results demonstrate that the hydrogen desorption rate increases as the pressure decreases from 0.3 MPa to 0.1 MPa. Moreover, the hydrogen evolution reaction rate significantly rises with an increase in the inlet temperature of the heat transfer fluid (HTF) from 600 K to 700 K. Similarly, the rate of hydrogen evolution reaction increases with an increase in the flow rate of the HTF from 0.5 m/s to 1.25 m/s. The hydrogen evolution reaction time can be notably reduced by increasing the thickness of the annular HTF layer. Compared to no annular fluid layer, the completion time of the hydrogen desorption reaction is shortened by 558 s with a 5 mm thickness. The arrangement of heat exchanger pipes plays a crucial role in the hydrogen evolution reaction, and thus a comprehensive index M is defined to evaluate its influence. A higher M value indicates slower hydrogen release efficiency of the device. By optimizing the operating conditions, the hydrogen desorption time can be shortened by 93.4 %. • A new type of solid-state hydrogen desorption system is designed. • The effect of working and structural parameters on hydrogen desorption performance is discussed in detail. • The paper defines a comprehensive performance index M to compare different bed designs. [ABSTRACT FROM AUTHOR]

Published

2024

48. Synthesis of an automatic control system for a voltage inverter as part of an autonomous power supply system with a hydrogen module.

Author

Vavilov, O.A., Yurkevich, V.D., and Korobkov, D.V.

Subjects

*AUTOMATIC control systems, *POWER supply quality, *RENEWABLE energy sources, *HYBRID power systems, *POWER resources

Abstract

This paper examines the problem of synthesizing a two-loop control system for a three-phase voltage source inverter designed for an autonomous power supply system. This type of DC/AC converters is an essential part of power supply systems with renewable energy sources as primary sources, and, accordingly, must corresponds to the requirements for the electric power quality. These requirements are met through circuit design solutions, as well as through the construction of high-precision automatic control systems. The system integrates: a hydrogen electrolyzer, a hydrogen storage system, and a hydrogen fuel cell. The paper proposes a method for calculating the parameters of PI controllers with resonant components, based on the time-scale separation method and allowing independent adjustment of the controller components. The introduction of a resonant component ensures high tracking accuracy for a desired main voltage harmonic and selective suppression of external harmonic influences. The proposed approach allows to synthesize an automatic control system that significantly improves the quality of the voltage inverter output parameters. [ABSTRACT FROM AUTHOR]

Published

2024

49. Novel coupled hydromechanical model considering multiple flow mechanisms for simulating underground hydrogen storage in depleted low-permeability gas reservoir.

Author

Liu, Xianshan, Geng, Shaoyang, Sun, Junchang, Li, Yao, Guo, Qiutian, and Zhan, Qigui

Subjects

*FINITE volume method, *HYDROGEN storage, *UNDERGROUND storage, *WORKING gases, *STORAGE facilities, *GAS reservoirs

Abstract

Depleted low-permeability gas reservoirs are the primary storage media for underground hydrogen storage (UHS). An accurate assessment of the geomechanics and complex flow mechanisms in a depleted low-permeability gas reservoir is crucial for predicting the injection and production capabilities of UHS facilities. This paper proposes a novel hydromechanical multicomponent model that couples non-Darcy flow, relative permeability hysteresis (RPH), and geomechanics to evaluate the hydrogen storage capacity of UHS facilities in a depleted low-permeability gas reservoir. The coupled model was solved using a fully coupled strategy, employing the finite volume method to solve non-Darcy flow equations and the virtual element method to solve geomechanical problems. The results indicate that the high-velocity non-Darcy (hvnD) and geomechanical effects reduce the working gas volume by 12.82% and 10.56%, respectively. Additionally, the low-velocity non-Darcy (lvnD) effect causes the third stress/strain distribution to exhibit a "focusing" phenomenon, resulting in a 13.19% reduction in the working gas volume. This paper also describes a case where residual gas is captured by mechanisms such as "water lock" and "capillary capture" through the RPH effect. Considering the RPH effect, the gas-water transition zone expanded by 30%, and the peak volume of gas-containing pores in the water zone increased by 1.48 times. Ignoring the RPH effect led to a 19.73% overestimation of the utilization rate of the gas-containing pore space. Hence, this study achieves safe and successful seasonal hydrogen storage and provides theoretical support for designing multicycle operational plans. • A novel coupled hydro-mechanical multicomponent model was proposed. • Non-Darcy flow, hysteresis and geomechanical effects were evaluated thoroughly. • The underground hydrogen storage capacity could be evaluated accurately. [ABSTRACT FROM AUTHOR]

Published

2024

50. Hydroelectric and Hydrogen Storage Systems for Electric Energy Produced from Renewable Energy Sources.

Author

Serag, Saif, Echchelh, Adil, and Morrone, Biagio

Subjects

RENEWABLE energy sources, ENERGY industries, ENERGY storage, HYDROGEN storage, POWER resources

Abstract

Renewable energy sources are essential for mitigating the greenhouse effect and supplying energy to resource-scarce regions. However, their intermittent nature necessitates efficient storage solutions to enhance system efficiency and manage energy costs. This paper investigates renewable and clean storage systems, specifically examining the storage of electricity generated from renewable sources using hydropower plants and hydrogen, both of which are highly efficient and promising for future energy production and storage. The study utilizes extensive literature data to analyze the impact of various parameters on the cost per kWh of electricity production in hybrid renewable systems incorporating hydropower and hydrogen storage plants. Results indicate that these hybrid systems can store electricity efficiently and cost-effectively, with production costs ranging from 0.126 to 0.3 $/kWh for renewable-hydropower systems and 0.118 to 0.42 $/kWh for renewable-hydrogen systems, with expected cost reductions over the next decade due to technological advancements and increased market adoption. The novelty of this study lies in its comprehensive comparison of hybrid renewable systems integrating hydropower and hydrogen storage, providing detailed cost analysis and future projections. It identifies key parameters influencing the cost and efficiency of these systems, offering insights into optimizing storage solutions for renewable energy. Moreover, this research underscores the potential of hybrid systems to reduce dependency on fossil fuels, particularly during peak demand periods, and emphasizes the importance of seasonal and geographic considerations in selecting energy sources. The study highlights the importance of policy support and investment in hybrid renewable systems and calls for further research into optimizing these systems for different seasonal and geographic conditions. Overall, the integration of renewable energy sources with hydropower and hydrogen storage offers a promising pathway to a sustainable, economical, and resilient energy future. [ABSTRACT FROM AUTHOR]

Published

2024