Benchmark Study of Hydrogen Storage in Metal–Organic Frameworks under Temperature and Pressure Swing Conditions

García-Holley, Paula; Schweitzer, Benjamin; İslamoğlu, Timur; Liu, Yangyang; Lin, Lu; Rodriguez, Stephanie; Weston, Mitchell H.; Hupp, Joseph T.; Gómez-Gualdrón, Diego A.; Yildirim, Taner; Farha, Omar K.

doi:10.1021/acsenergylett.8b00154

Cited by 182 publications

(179 citation statements)

References 55 publications

(91 reference statements)

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“…The US Department of Energy (DOE) challenged scientists to achieve onboard vehicle H 2 storage systems in 2020 (4.5 wt%) and 2025 (5.5 wt%) and achievable (6.5 wt%) targets for onboard hydrogen storage equipment to be used in light-duty vehicles. 10 Carbon-based nanomaterials 8,[11][12][13][14][15] such as graphene, 3,16 graphite, graphite nanofibers, carbon nanotubes, fullerenes, metal-organic frameworks (MOFs), and covalent-organic frameworks (COFs) [17][18][19][20] have been examined as potential H 2 storage materials because of their chemical stability, large specific surface area, and lightweight. In general, researchers use two different successful hydrogen storage forms: atomic (through chemical adsorption) and molecular forms (through physical adsorption).…”

Section: Discussionmentioning

confidence: 99%

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Boron‐ and nitrogen‐doped penta‐graphene as a promising material for hydrogen storage: A computational study

Sathishkumar

Chen

2019

Int J Energy Res

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Summary We fulfill a comprehensive study based on density functional theory (DFT) computations to cast insight into the dissociation mechanism of hydrogen molecule on pristine, B‐, and N‐doped penta‐graphene. The doping effect has been also illustrated by varying the concentration of dopant from 4.2 at% (one doping atom in 24 host atoms) to 8.3 at% (two doping atoms in 24 host atoms) and by contemplating different doping sites. Our theoretical investigation shows that the adsorption energy of H2 molecule and H atom on the substrate can be substantially enhanced by incorporating boron or nitrogen into penta‐graphene sheet. The B‐ and N‐doped penta‐graphene can effectively decompose H2 molecule into two H atoms. Our results demonstrate that activation energies for H2 dissociation and H diffusion on the B‐ and N‐doped penta‐graphene are much smaller than the pristine penta‐graphene. Further investigation of increasing concentration dopants of the penta‐graphene sheet gives sufficiently low activation barrier for H2 dissociation process. This investigation reveals that the boron and nitrogen dopants can act as effective active site for H2 dissociation and storage.

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Section: Discussionmentioning

confidence: 99%

“…There are strict requirements in ideal materials for H 2 storage practical applications. The US Department of Energy (DOE) challenged scientists to achieve onboard vehicle H 2 storage systems in 2020 (4.5 wt%) and 2025 (5.5 wt%) and achievable (6.5 wt%) targets for onboard hydrogen storage equipment to be used in light‐duty vehicles …”

Section: Introductionmentioning

confidence: 99%

Boron‐ and nitrogen‐doped penta‐graphene as a promising material for hydrogen storage: A computational study

Sathishkumar

Chen

2019

Int J Energy Res

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“…During the past few years, metal–organic assembly has attracted increasing interest due to the potential applications in gas storage, catalysis, photoluminescence sensor, and drug delivery . Very recently, a metal–organic assembly has also shown the potential to be applied in PSCs.…”

Section: Introductionmentioning

confidence: 99%

Enhanced Crystallization and Optimized Morphology of Perovskites Through Doping an Indium‐Based Metal–Organic Assembly: Achieving Significant Solar Cell Efficiency Enhancements

Xia

Jiang

et al. 2019

Energy Tech

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Perovskite crystallization and morphology are two essential factors to the photoelectric performances of perovskite solar cells (PSCs). A 3D metal–organic assembly [In2(phen)3Cl6]·CH3CN·2H2O (In2) is introduced for the first time into lead iodide precursor to modify the quality of a perovskite thin film through a two‐step sequential deposition method. As a result, both the lead iodide and perovskite exhibit improved crystallization and modified morphology. The optimized film presents less trap states and is thus in favor of the charge transfer as well as charge collection. Consequently, open circuit voltage (Voc) and fill factor obviously show enhancements from 0.99 to 1.04 V and from 0.66 to 0.71, respectively, yielding a significant increase in a power conversion efficiency from 15.41% to 17.15%. Meanwhile, the hydrophobic property of In2 can increase the moisture resistance of the perovskite, which offers a simple and effective method to improve the stability of PSCs.

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“…In 1995, a new family of porous materials, MOFs, formed of an organic and inorganic part was introduced . Controllable synthesis conditions, designable organic ligands, tuneable pore sizes, high specific surface area, and the highly porous nature make MOFs attractive in H 2 storage applications …”

Section: Introductionmentioning

confidence: 99%

“…18 Controllable synthesis conditions, designable organic ligands, tuneable pore sizes, high specific surface area, and the highly porous nature make MOFs attractive in H 2 storage applications. 5,14,[19][20][21] MOFs possess incredibly high H 2 adsorption capacities at high pressures and cryogenic temperatures. 5,[22][23][24] However, very low H 2 sorption capacities can be achieved at 298 K and low pressures.…”

Section: Introductionmentioning

confidence: 99%

Engineering MIL‐88B crystallites for enhanced H ₂ uptake capacity: The role of ultramicropores

Yurduşen

Yürüm

2019

Int J Energy Res

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Summary In this study, a strategy that optimizes the pore size to enhance the adsorbed H2 amount (at 298 K) is investigated. Pore size and ultramicropore fraction (ultramicropore volume/total pore volume) were controlled by Fe:TPA ratio. The highest H2 adsorption capacity of 0.47 wt% (298 K and 7.6 bar) belongs to MIL‐88B‐3, which is higher than those of reported metal‐organic frameworks (MOFs) (MIL‐100, MIL‐101 [Cr], HKUST‐1, MOF‐5, and ZIF‐8). The enhanced H2 sorption capacity (1.96 times) is a consequence of the high fraction (89%) and volume (0.22 cm3/g) of ultramicropores with pore diameters of 0.6 nm. Our results demonstrate that pore size, fraction, and volume of ultramicropores control the amount of H2 adsorbed also at 298 K. With the use of perturbation assisted nanofusion synthesis strategy that introduces textural pores to the pore structure, a Brunauer‐Emmett‐Teller (BET) surface area higher than those of reported MIL‐88Bs has been achieved, and a strategy to synthesize MOFs with enhanced H2 sorption capacities is suggested.

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Benchmark Study of Hydrogen Storage in Metal–Organic Frameworks under Temperature and Pressure Swing Conditions

Abstract: lett.8b00154. Details on experimental and computational methods as well as adsorption isotherms, isosteric heats of adsorption, and PXRD patterns (PDF)■ AUTHOR INFORMATION

Cited by 182 publications

References 55 publications

Boron‐ and nitrogen‐doped penta‐graphene as a promising material for hydrogen storage: A computational study

Boron‐ and nitrogen‐doped penta‐graphene as a promising material for hydrogen storage: A computational study

Enhanced Crystallization and Optimized Morphology of Perovskites Through Doping an Indium‐Based Metal–Organic Assembly: Achieving Significant Solar Cell Efficiency Enhancements

Engineering MIL‐88B crystallites for enhanced H ₂ uptake capacity: The role of ultramicropores

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Benchmark Study of Hydrogen Storage in Metal–Organic Frameworks under Temperature and Pressure Swing Conditions

Abstract: lett.8b00154. Details on experimental and computational methods as well as adsorption isotherms, isosteric heats of adsorption, and PXRD patterns (PDF)■ AUTHOR INFORMATION

Cited by 182 publications

References 55 publications

Boron‐ and nitrogen‐doped penta‐graphene as a promising material for hydrogen storage: A computational study

Boron‐ and nitrogen‐doped penta‐graphene as a promising material for hydrogen storage: A computational study

Enhanced Crystallization and Optimized Morphology of Perovskites Through Doping an Indium‐Based Metal–Organic Assembly: Achieving Significant Solar Cell Efficiency Enhancements

Engineering MIL‐88B crystallites for enhanced H 2 uptake capacity: The role of ultramicropores

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Engineering MIL‐88B crystallites for enhanced H ₂ uptake capacity: The role of ultramicropores