Lightweight Ultra-High-Barrier Liners for Helium and Hydrogen

Habel, Christoph; Tsurko, Evgeny S.; Timmins, Renee L.; Hutschreuther, Julia; Kunz, Raphael; Schuchardt, Dominik; Rosenfeldt, Sabine; Altstädt, Volker; Breu, Josef

doi:10.1021/acsnano.0c01633

Cited by 30 publications

(27 citation statements)

References 53 publications

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“…At present, only a small number of experts and scholars have researched this, and there are few related references. Generally, the permeability of gas in polymers is mainly affected by external conditions (such as temperature [20,21], pressure [15,22]), material properties (such as crystallinity [23,24], fillers [25,26], etc. ), and the interaction between gas and material [27,28].…”

Section: Factors Affecting Hydrogen Permeabilitymentioning

confidence: 99%

“…where 0 P P represents the ratio of polymer permeability coefficient after filling to before filling, and μ , α , and φ represent geometric factor, aspect ratio, and volume fraction related to the filling, respectively. According to this rule, Habel et al [26] used NaHec with a large aspect ratio as the nanofiller and optimized its arrangement in the polymer to produce a lightweight ultrahigh barrier liner for helium and hydrogen. Sun et al [45] comprehensively investigated the hydrogen permeability of PA6 filled with lamellar inorganic components (LIC).…”

Section: Additivesmentioning

confidence: 99%

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Review of the Hydrogen Permeability of the Liner Material of Type IV On-Board Hydrogen Storage Tank

Zhou

et al. 2021

WEVJ

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The hydrogen storage tank is a key parameter of the hydrogen storage system in hydrogen fuel cell vehicles (HFCVs), as its safety determines the commercialization of HFCVs. Compared with other types, the type IV hydrogen storage tank which consists of a polymer liner has the advantages of low cost, lightweight, and low storage energy consumption, but meanwhile, higher hydrogen permeability. A detailed review of the existing research on hydrogen permeability of the liner material of type IV hydrogen storage tanks can improve the understanding of the hydrogen permeation mechanism and provide references for following-up researchers and research on the safety of HFCVs. The process of hydrogen permeation and test methods are firstly discussed in detail. This paper then analyzes the factors that affect the process of hydrogen permeation and the barrier mechanism of the liner material and summarizes the prediction models of gas permeation. In addition to the above analysis and comments, future research on the permeability of the liner material of the type IV hydrogen storage tank is prospected.

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Section: Factors Affecting Hydrogen Permeabilitymentioning

confidence: 99%

Section: Additivesmentioning

confidence: 99%

Review of the Hydrogen Permeability of the Liner Material of Type IV On-Board Hydrogen Storage Tank

Zhou

et al. 2021

WEVJ

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“…The flexible nanosheets [24] completely encapsulated individual nanoparticles (Figure 1a). Since the nanosheets are impermeable for H 2 , [25] the Pd nanoparticles at this low loading turned out to be not accessible for CO chemisorption or Ar (Figure S5a). More nanoparticles that are closer to each other were required to prevent the nanosheets from collapsing.…”

Section: Resultsmentioning

confidence: 99%

Enhancing Hydrogen Storage Capacity of Pd Nanoparticles by Sandwiching between Inorganic Nanosheets

Ament

Kobayashi

Kusada

et al. 2022

Zeitschrift anorg allge chemie

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H 2 is regarded to play a crucial role in the transition from a fossil fuel-based energy economy towards an environmentally friendly one. However, storage of H 2 is still challenging, but palladium (Pd) based materials show exciting properties. Therefore, nanoparticulate Pd has been intensely studied for hydrogen storage in the past years. Here, we stabilize Pd nanoparticles by intercalation between inorganic nanosheets of hectorite (NaHec). Compared to nanoparticles stabilized by the polymer polyvinylpyrrolidone (PVP), the H 2 storage capacity was found to be 86 % higher for identical Pd nanoparticles being intercalated between nanosheets. We attribute this remarkably enhanced H 2 storage capacity to the partial oxidation of Pd, as evidenced by X-ray photoelectron spectroscopy (XPS). The higher amount of holes in the 4d band leads to a higher amount of H 2 that can be absorbed when Pd is stabilized between the nanosheets of hectorite compared to the PVP stabilized nanoparticles.

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“…Previously in our group, synthetic sodium fluorohectorite (NaHec, [Na 0.5 ] inter [Mg 2.5 Li 0.5 ] oct [Si 4 ] tet O 10 F 2 ) clay has been used to create nanocomposite barrier coatings with various polymer matrices. [26][27][28] NaHec undergoes the rare phenomenon of repulsive osmotic delamination, which is a thermodynamically allowed process, resulting in gentle and quantitative delamination into a nematic liquid crystalline suspension. With an aspect ratio of 20000, rotation even in very dilute suspensions (<1 vol%) is sterically hindered.…”

Section: Introductionmentioning

confidence: 99%

High Barrier Nanocomposite Film with Accelerated Biodegradation by Clay Swelling Induced Fragmentation

Timmins

Kumar

Röhrl

et al. 2021

Macro Materials & Eng

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Conventional biodegradable polymers such as poly(lactic acid) (PLA) are an attractive alternative to replace traditional nondegradable food packaging films which plague the environment. However, PLA has shown to not be degradable in some environmentally relevant conditions, including within the freshwater systems. Additionally, PLA suffers from very poor barrier properties, which could result in food spoilage. Compositing with clay has been used to improve barrier properties according to tortuous path theory. Here a synthetic, large aspect ratio Na-Hectorite is used that may be utterly delaminated in an organic solvent and composited with PLA by modification with 18-crown-6 (18C6Hec), yielding a castable, homogeneous nematic suspension. Upon drying, thermodynamics drive the suspension toward segregation into sublayers of PLA and partially restacked 18C6Hec in situ. This unique self-assembled nanostructure combines the best of two worlds: The aspect ratio remains high and results in a 99.3% reduction in oxygen permeability. Additionally, the film shows surprisingly high resistance to swelling at elevated humidity, but once soaked in water, clay swelling is triggered, which fragments the film and drastically increases the surface area by 2500%. Accelerated degradation is observed under controlled enzymatic conditions and in an environmentally relevant wastewater medium during CO 2 evolution testing.

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Lightweight Ultra-High-Barrier Liners for Helium and Hydrogen

Cited by 30 publications

References 53 publications

Review of the Hydrogen Permeability of the Liner Material of Type IV On-Board Hydrogen Storage Tank

Review of the Hydrogen Permeability of the Liner Material of Type IV On-Board Hydrogen Storage Tank

Enhancing Hydrogen Storage Capacity of Pd Nanoparticles by Sandwiching between Inorganic Nanosheets

High Barrier Nanocomposite Film with Accelerated Biodegradation by Clay Swelling Induced Fragmentation

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