Addressing Environmental Challenges: The Role of Hydrogen Technologies in a Sustainable Future

Di Nardo, Alessandra; Calabrese, Marcella; Venezia, Virginia; Portarapillo, Maria; Turco, Maria; Di Benedetto, Almerinda; Luciani, Giuseppina

doi:10.3390/en16237908

Cited by 5 publications

(3 citation statements)

References 171 publications

(180 reference statements)

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“…In solid-state storage, hydrogen is physically or chemically stored in solid materials such as carbon nanotubes or metal hydrides, while the use of liquid organic carriers consists of a chemical cycle of hydrogenation and dehydrogenation steps. In both the liquid and solid chemical storage systems, heat is required for the dehydrogenation step, and the typical reaction conditions for the exothermic hydrogenation are a high pressure (1 to 5 MPa) and temperatures from 373 to 523 K [28]. The aforementioned systems are considered to be safe and practical because hydrogen can be stored and transported as a liquid or solid, eliminating the safety and storage problems associated with gaseous hydrogen.…”

Section: Safety Issues In Storagementioning

confidence: 99%

Hydrogen Safety Challenges: A Comprehensive Review on Production, Storage, Transport, Utilization, and CFD-Based Consequence and Risk Assessment

Calabrese,

Portarapillo,

Di Nardo

et al. 2024

Energies

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This review examines the central role of hydrogen, particularly green hydrogen from renewable sources, in the global search for energy solutions that are sustainable and safe by design. Using the hydrogen square, safety measures across the hydrogen value chain—production, storage, transport, and utilisation—are discussed, thereby highlighting the need for a balanced approach to ensure a sustainable and efficient hydrogen economy. The review also underlines the challenges in safety assessments, points to past incidents, and argues for a comprehensive risk assessment that uses empirical modelling, simulation-based computational fluid dynamics (CFDs) for hydrogen dispersion, and quantitative risk assessments. It also highlights the activities carried out by our research group SaRAH (Safety, Risk Analysis, and Hydrogen) relative to a more rigorous risk assessment of hydrogen-related systems through the use of a combined approach of CFD simulations and the appropriate risk assessment tools. Our research activities are currently focused on underground hydrogen storage and hydrogen transport as hythane.

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Section: Safety Issues In Storagementioning

confidence: 99%

Hydrogen Safety Challenges: A Comprehensive Review on Production, Storage, Transport, Utilization, and CFD-Based Consequence and Risk Assessment

Calabrese,

Portarapillo,

Di Nardo

et al. 2024

Energies

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“…It highlights hydrogen's potential to decarbonize challenging sectors and add flexibility to the energy system through storage. However, the report demonstrates significant challenges for hydrogen deployment, such as high costs, infrastructure gaps, and safety concerns [87]. The report particularly recognizes hydrogen's importance in enhancing resilience, especially for remote communities reliant on smaller grids and diesel generators, suggesting hydrogen as a sustainable alternative.…”

Section: Summary and Evaluationmentioning

confidence: 99%

A Review of the Role of Hydrogen in the Heat Decarbonization of Future Energy Systems: Insights and Perspectives

Ameli,

Strbac,

Pudjianto

et al. 2024

Energies

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Hydrogen is an emerging technology changing the context of heating with cleaner combustion than traditional fossil fuels. Studies indicate the potential to repurpose the existing natural gas infrastructure, offering consumers a sustainable, economically viable option in the future. The integration of hydrogen in combined heat and power systems could provide residential energy demand and reduce environmental emissions. However, the widespread adoption of hydrogen will face several challenges, such as carbon dioxide emissions from the current production methods and the need for infrastructure modification for transport and safety. Researchers indicated the viability of hydrogen in decarbonizing heat, while some studies also challenged its long-term role in the future of heating. In this paper, a comprehensive literature review is carried out by identifying the following key aspects, which could impact the conclusion on the overall role of hydrogen in heat decarbonization: (i) a holistic view of the energy system, considering factors such as renewable integration and system balancing; (ii) consumer-oriented approaches often overlook the broader benefits of hydrogen in emission reduction and grid stability; (iii) carbon capture and storage scalability is a key factor for large-scale production of low-emission blue hydrogen; (iv) technological improvements could increase the cost-effectiveness of hydrogen; (v) the role of hydrogen in enhancing resilience, especially during extreme weather conditions, raises the potential of hydrogen as a flexible asset in the energy infrastructure for future energy supply; and finally, when considering the UK as a basis case, (vi) incorporating factors such as the extensive gas network and unique climate conditions, necessitates specific strategies.

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“…The development of the H 2 economy is based on four cornerstones (production, storage, transportation, and use). 1 Nowadays, more than 90% of the H 2 production (estimated to be 120 million tons by 2024) 2 is carried out by the catalytic steam reforming (SR) of fossil feedstock (methane, natural gas, naphtha, propane), with high emissions of greenhouse gases (110 g CO 2 e per MJ of H 2 from methane). 3 To avoid the impact of these emissions on the climate change, the development of H 2 production technologies from biomass feedstock is experiencing a growing interest in the transition scenario toward the H 2 production through water electrolysis.…”

Section: Introductionmentioning

confidence: 99%

Global Vision of the Reaction and Deactivation Routes in the Ethanol Steam Reforming on a Catalyst Derived from a Ni–Al Spinel

Iglesias-Vázquez,

Valecillos,

Remiro

et al. 2024

Energy Fuels

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Ethanol steam reforming (ESR) over a Ni/Al 2 O 3 catalyst prepared by reduction of a NiAl 2 O 4 spinel is a promising alternative route to produce H 2 from biomass. This work deepens into the effect of reaction conditions (450−650 °C, a steam/ ethanol (S/E) ratio of 3−9, and a weight space time up to 1.3 h) and evaluates the time on stream evolution of the yields of H 2 , gaseous byproducts (CO, CO 2 , CH 4 , C 2 H 4 , C 2 H 4 O), and formed carbon/coke. The results are explained taking into consideration the thermodynamics, the extent of each individual reaction, and the catalyst deactivation. Up to 600 °C, the predominant intermediate in the H 2 formation is C 2 H 4 (formed by ethanol dehydration) with the preferential formation of nanostructured carbon (nanotubes/ filaments) by C 2 H 4 decomposition. The deposition of this type of carbon partially deactivates the catalyst, mainly affecting the extent of the C 2 H 4 decomposition causing a sharp decrease in the H 2 and carbon yields. Nevertheless, the catalyst reaches a pseudosteady state with an apparent constant activity for other reactions in the kinetic scheme. At 650 °C, C 2 H 4 O (formed by the ethanol dehydrogenation) is the main intermediate in the H 2 formation, which is the precursor of an amorphous/turbostratic carbon (coke) formation that initially causes a rapid deactivation of the catalyst, affecting the ethanol dehydration and, to a lower extent, the reforming and water gas shift reactions. The increase in the S/E ratio favors the H 2 formation, attenuates the catalyst deactivation due to the suppression of the ethanol dehydration to C 2 H 4 , and promotes the reforming, water gas shift, and carbon/coke gasification reactions. A H 2 yield of 85% stable for 48 h on stream is achieved at 600 °C, with a space time of 0.1 h and an S/E ratio of 9.

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Addressing Environmental Challenges: The Role of Hydrogen Technologies in a Sustainable Future

Cited by 5 publications

References 171 publications

Hydrogen Safety Challenges: A Comprehensive Review on Production, Storage, Transport, Utilization, and CFD-Based Consequence and Risk Assessment

Hydrogen Safety Challenges: A Comprehensive Review on Production, Storage, Transport, Utilization, and CFD-Based Consequence and Risk Assessment

A Review of the Role of Hydrogen in the Heat Decarbonization of Future Energy Systems: Insights and Perspectives

Global Vision of the Reaction and Deactivation Routes in the Ethanol Steam Reforming on a Catalyst Derived from a Ni–Al Spinel

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