Efficient Production of Clean Power and Hydrogen Through Synergistic Integration of Chemical Looping Combustion and Reforming

Khan, Mohammed N.; Cloete, Schalk; Amini, Shahriar

doi:10.3390/en13133443

Cited by 6 publications

(3 citation statements)

References 26 publications

(44 reference statements)

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“…In terms of natural gas production and processing, the utilization of biochemistry technology, thermochemistry technology, and electrochemistry technology can effectively reduce carbon emissions in the process of natural gas production and processing [14,[62][63][64], while innovation in natural gas technology can effectively increase global natural gas reserves and promote the development of unconventional natural gases, such as shale gas [65,66], as well as helping to identify and mitigate potential methane leaks during natural gas production [67]. Advanced natural gas power generation technology, conversion technology, and carbon capture and storage (CCS) technology can facilitate the control of natural gas carbon emissions [68][69][70], reduce energy losses, and increase energy supplies [71]. In addition, the spillover and diffusion of innovations in natural gas technology will also contribute to the synergistic development of renewable energy technologies [43].…”

Section: Research On Technological Innovation In the Natural Gas Indu...mentioning

confidence: 99%

Research into the Spatiotemporal Characteristics and Influencing Factors of Technological Innovation in China’s Natural Gas Industry from the Perspective of Energy Transition

Wang

Yin

2023

Sustainability

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Promoting technological innovation in the natural gas industry is a feasible means of achieving energy transition. Guided by the geographic innovation theory, this article carries out research on the scale, technical fields, capabilities, and influencing factors of technological innovation in the natural gas industry of 312 Chinese prefecture-level cities, making use of the cusp catastrophe model, the center of gravity and standard deviational ellipse, exploratory spatial data analysis, and geographically and temporally weighted regression (GTWR). The research shows the following: (1) Technological innovation in China’s natural gas industry has continuously expanded in terms of scale, with the number of participating cities increasing, showing a spatially uneven pattern of local agglomeration and national diffusion. (2) There have been significant innovation achievements in natural gas equipment and engineering, but natural gas utilization is lagging in comparison, with drilling, new materials, environmental protection, pipe network engineering, and digital services becoming frontier fields, and collaborative innovation with the thermoelectric, metalworking, automotive, and other related industries having been initially established. (3) The unevenness of technological innovation capabilities is obvious, with the core advantages of Beijing–Tianjin being continuously strengthened and Sichuan–Chongqing, the Yangtze River Delta, the Pearl River Delta, Shandong Peninsula, and Liaodong Peninsula forming high-level technological innovation capability agglomerations. (4) The spatiotemporal pattern of technological innovation capability is the result of multiple factors, with northeastern cities mainly being affected by natural gas demands, northwestern cities being highly sensitive to capital strength, eastern cities mostly relying on urban development, and cities in North China mainly being bolstered by the strength of talent. (5) It is necessary to carry out further multi-agent and multi-scale future research on technological innovation in the natural gas industry and its relationship with the energy transition and to explore the interactivity of the influencing factors. This study may provide strategies for technological innovation in the natural gas industry from the perspective of the energy transition.

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Section: Research On Technological Innovation In the Natural Gas Indu...mentioning

confidence: 99%

Research into the Spatiotemporal Characteristics and Influencing Factors of Technological Innovation in China’s Natural Gas Industry from the Perspective of Energy Transition

Wang

Yin

2023

Sustainability

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“…Hydrogen could be produced by natural gas steam reforming and used to produce electricity. A system integrating hydrogen produced from natural gas combined with CCS has been proposed (Khan et al, 2020). The pathways for sustainable natural gas utilization in electricity generation are presented in Figure 2.…”

Section: An Overview Of Natural Gas Utilization For Power Generationmentioning

confidence: 99%

Natural Gas as a Key Alternative Energy Source in Sustainable Renewable Energy Transition: A Mini Review

et al. 2021

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Energy security and sustainability are undeniably the main concerns in combatting climate change. While an immediate call for all-green and renewable energy seems to be impossible due to huge financial implications and inadequate supporting energy structure, an alternative to fossil fuels needs to be established. Natural gas, a naturally occurring fossil gas is a cleaner energy source option compared to other fossil fuels such as coal, bitumen, and diesel. Natural gas makes the best fit for a sustainable renewable energy transition in any country around the globe due to its competitiveness towards other fossil fuels such as coal and its ability to aid the integration of renewables. This review highlights the technological pathways of utilizing natural gas in a transition to sustainable renewable energy systems, with a focus on the natural gas components and resources point of view for ASEAN member states (AMS). Policies that support the development of natural gas as a key alternative energy source in sustainable renewable energy transition would also be reviewed. This review aims to provide a thorough guide to researchers, stakeholders, and policymakers to construct and support efficient, reliable, affordable, sustainable, and environmentally friendly energy systems utilizing the abundant inexpensive natural gas.

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“…Furthermore, the proper selection of the carrier allows the replacement of a high-quality heat supply with isothermal redox operation improving the system efficiency. Therefore, in recent years, the benefits of a chemical looping approach to combustion and reforming processes have drawn increased interest from researchers [25][26][27]. The selection of a proper oxygen carrier is essential to ensure selectivity towards partial oxidation to syngas rather than complete combustion [28].…”

Section: Introductionmentioning

confidence: 99%

Improvement of Process Conditions for H2 Production by Chemical Looping Reforming

Storione,

Boscherini,

Miccio

et al. 2024

Energies

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A syngas production process was studied cyclically, exploiting the redox properties of Ce-based oxygen carriers. The two steps of the looping cycle were investigated through thermogravimetric analysis and fixed bed experiments. While TGA experiments were focused on the identification of the optimal temperatures ranges for methane partial oxidation (900–1000 °C) and carrier regeneration (400–900 °C), fixed bed testing was performed isothermally (at 900 or 950 °C), with a 10% CH4 feed stream in N2 to investigate material stability and cyclic performance reproducibility. The effect of the process times on carbon deposition, specific syngas yields, and selectivity was inspected, together with the investigation of best conditions to fully regenerate the carrier, adjust the syngas final ratio, and to ensure stable performances. The obtained results ensured the possibility to work in fully isothermal operations, with CH4 conversion of up to 38% and specific yields of syngas per mass of O2 carrier between 4.0–6.8 mmol∙g−1, preserved even across cycles, thus paving the path to the development of alternative and effective processes for syngas production. Under the operating conditions of the lab-scale experiment, an effective reforming time was 20 min, corresponding to 1.16 times of the characteristic time of reaction kinetics at 950 °C.

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Efficient Production of Clean Power and Hydrogen Through Synergistic Integration of Chemical Looping Combustion and Reforming

Cited by 6 publications

References 26 publications

Research into the Spatiotemporal Characteristics and Influencing Factors of Technological Innovation in China’s Natural Gas Industry from the Perspective of Energy Transition

Research into the Spatiotemporal Characteristics and Influencing Factors of Technological Innovation in China’s Natural Gas Industry from the Perspective of Energy Transition

Natural Gas as a Key Alternative Energy Source in Sustainable Renewable Energy Transition: A Mini Review

Improvement of Process Conditions for H2 Production by Chemical Looping Reforming

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