Low Carbon Scenario Analysis of a Hydrogen-Based Energy Transition for On-Road Transportation in California

Vijayakumar, Vishnu; Jenn, Alan; Fulton, Lewis

doi:10.3390/en14217163

Cited by 17 publications

(12 citation statements)

References 22 publications

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“…The production and technology options considered along each pathway are based on our understanding of the status of technology and its regional feasibility. 40 For production, we consider central production using steam methane reforming (SMR) with carbon capture and sequestration (CCS) and grid-connected proton-exchange membrane (PEM) electrolyzers. In one of the sensitivity cases, we also consider forecourt/on-site production (co-located alongside refueling stations) using PEM electrolyzers.…”

Section: Methods and Datamentioning

confidence: 99%

“…39 Hydrogen produced from Renewable Natural Gas (RNG) is as an eligible technology under SB 1505, but we do not consider that option in this study owing to the uncertainty of feedstock supply and the ability to scale. 40 The recently passed “Carbon Capture and Sequestration (CCS) Protocol” within the LCFS encourages fossil derived hydrogen production. However, a HSC overly dependent on fossil derived sources could be risky, owing to the possibility of methane leaks (if not adequately monitored) and the potential of CCS projects to elicit NIMBY (not under my backyard) reactions.…”

Section: Introductionmentioning

confidence: 99%

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Modeling future hydrogen supply chains in the western United States under uncertainties: an optimization-based approach focusing on California as a hydrogen hub

Vijayakumar

Jenn

Ogden

2023

Sustainable Energy Fuels

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Section: Methods and Datamentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Modeling future hydrogen supply chains in the western United States under uncertainties: an optimization-based approach focusing on California as a hydrogen hub

Vijayakumar

Jenn

Ogden

2023

Sustainable Energy Fuels

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“…The establishment of appropriate transportation methods is an important factor when socially implementing hydrogen energy [13,14]. Carbon materials can safely store hydrogen [15,16]; in particular, lithium (Li)-doped graphene and carbon nanotubes (CNTs) have been used as effective storage materials [17,18].…”

Section: Introductionmentioning

confidence: 99%

Hydrogen Storage Mechanism in Sodium-Based Graphene Nanoflakes: A Density Functional Theory Study

Tachikawa

Iyama

et al. 2022

Hydrogen

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Carbon materials, such as graphene nanoflakes, carbon nanotubes, and fullerene, can be widely used to store hydrogen, and doping these materials with lithium (Li) generally increases their H2-storage densities. Unfortunately, Li is expensive; therefore, alternative metals are required to realize a hydrogen-based society. Sodium (Na) is an inexpensive element with chemical properties that are similar to those of lithium. In this study, we used density functional theory to systematically investigate how hydrogen molecules interact with Na-doped graphene nanoflakes. A graphene nanoflake (GR) was modeled by a large polycyclic aromatic hydrocarbon composed of 37 benzene rings, with GR-Na-(H2)n and GR-Na+-(H2)n (n = 0–12) clusters used as hydrogen storage systems. Data obtained for the Na system were compared with those of the Li system. The single-H2 GR-Li and GR-Na systems (n = 1) exhibited binding energies (per H2 molecule) of 3.83 and 2.72 kcal/mol, respectively, revealing that the Li system has a high hydrogen-storage ability. This relationship is reversed from n = 4 onwards; the Na systems exhibited larger or similar binding energies for n = 4–12 than the Li-systems. The present study strongly suggests that Na can be used as an alternative metal to Li in H2-storage applications. The H2-storage mechanism in the Na system is also discussed based on the calculated results.

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“…When it comes to the direct use of hydrogen in mobility applications, light-dut FCEVs now receive the most consumer attention [71]. FCEVs, on the other hand, hav been used in material handling (mostly forklifts), buses, trains, and trucks [72][73][74]. When it comes to the direct use of hydrogen in mobility applications, light-duty FCEVs now receive the most consumer attention [71].…”

mentioning

confidence: 99%

“…When it comes to the direct use of hydrogen in mobility applications, light-duty FCEVs now receive the most consumer attention [71]. FCEVs, on the other hand, have been used in material handling (mostly forklifts), buses, trains, and trucks [72][73][74].…”

mentioning

confidence: 99%

Hydrogen Fuel for Future Mobility: Challenges and Future Aspects

Dash,

Chakraborty,

Roccotelli

et al. 2022

Sustainability

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Nowadays, the combustion of fossil fuels for transportation has a major negative impact on the environment. All nations are concerned with environmental safety and the regulation of pollution, motivating researchers across the world to find an alternate transportation fuel. The transition of the transportation sector towards sustainability for environmental safety can be achieved by the manifestation and commercialization of clean hydrogen fuel. Hydrogen fuel for sustainable mobility has its own effectiveness in terms of its generation and refueling processes. As the fuel requirement of vehicles cannot be anticipated because it depends on its utilization, choosing hydrogen refueling and onboard generation can be a point of major concern. This review article describes the present status of hydrogen fuel utilization with a particular focus on the transportation industry. The advantages of onboard hydrogen generation and refueling hydrogen for internal combustion are discussed. In terms of performance, affordability, and lifetime, onboard hydrogen-generating subsystems must compete with what automobile manufacturers and consumers have seen in modern vehicles to date. In internal combustion engines, hydrogen has various benefits in terms of combustive properties, but it needs a careful engine design to avoid anomalous combustion, which is a major difficulty with hydrogen engines. Automobile makers and buyers will not invest in fuel cell technology until the technologies that make up the various components of a fuel cell automobile have advanced to acceptable levels of cost, performance, reliability, durability, and safety. Above all, a substantial advancement in the fuel cell stack is required.

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Low Carbon Scenario Analysis of a Hydrogen-Based Energy Transition for On-Road Transportation in California

Cited by 17 publications

References 22 publications

Modeling future hydrogen supply chains in the western United States under uncertainties: an optimization-based approach focusing on California as a hydrogen hub

Modeling future hydrogen supply chains in the western United States under uncertainties: an optimization-based approach focusing on California as a hydrogen hub

Hydrogen Storage Mechanism in Sodium-Based Graphene Nanoflakes: A Density Functional Theory Study

Hydrogen Fuel for Future Mobility: Challenges and Future Aspects

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