Ambient-Temperature Hydrogen Storage via Vanadium(II)-Dihydrogen Complexation in a Metal–Organic Framework

Jaramillo, David E.; Jiang, Henry Z. H.; Evans, Hayden A.; Chakraborty, Romit; Furukawa, Hiroyasu; Brown, Craig M.; Head‐Gordon, Martin; Long, Jeffrey R.

doi:10.1021/jacs.1c01883

Cited by 122 publications

(153 citation statements)

References 63 publications

(122 reference statements)

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“…This usable capacity represents the highest H2 volumetric usable capacity achieved to date for a densified adsorbent operating in this temperature range. Although these values are comparable to the current theoretical benchmarks (Ni2(dobdc), MOF-5 and V2Cl2.8(btdd)) (10,49) under these conditions (Table S21), it is important to highlight that these previous values are based on theoretical crystal densities and not experimental envelope densities, as reported here for monoHKUST-1. A natural assumption is to expect a ca.…”

Section: Figure 5csupporting

confidence: 84%

Densified HKUST-1 Monoliths as a Route to High Volumetric and Gravimetric Hydrogen Storage Capacity

Madden

O’Nolan

Rampal

et al. 2022

Preprint

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We are currently witnessing the dawn of the hydrogen (H2) economy, where H2 will become a primary fuel for heating, transportation, and long-distance and long-term energy storage. Among the diverse possibilities, H2 can be stored as a pressurized gas, cryogenic liquid, or solid fuel via adsorption onto porous materials. Metal-organic frameworks (MOFs) have emerged as the adsorbent materials with the theoretical highest H2 storage densities on both a volumetric and gravimetric basis. However, a critical bottleneck for the use of H2 as a transportation fuel has been the lack of densification methods capable of shaping MOFs into practical formulations whilst maintaining their adsorptive performance. Here, we report a high-throughput screening and deep analysis of a database of MOFs to find optimal materials, followed by the synthesis, characterisation, and performance evaluation of an optimal monolithic MOF (monoMOF) for H2 storage. After densification, this monoMOF stores 46 g L-1 H2 at 50 bar, 77 K, and delivers 41 and 42 g L-1 H2 at operating pressures of 25 and 50 bar, respectively, when deployed in a combined temperature–pressure (25-50 bar/77 K → 5 bar/160 K) swing gas delivery system. This performance represents up to an 80% reduction in the operating pressure requirements for delivering H2 gas when compared with benchmark materials, and an 83% reduction compared to compressed H2 gas. Our findings represent a substantial step forward in the application of high-density materials for volumetric H2 storage applications.

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Section: Figure 5csupporting

confidence: 84%

Densified HKUST-1 Monoliths as a Route to High Volumetric and Gravimetric Hydrogen Storage Capacity

Madden

O’Nolan

Rampal

et al. 2022

Preprint

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“…Metal-organic frameworks (MOFs), which have a microporous crystalline structure comprising metal ions or clusters, are connected via molecular bridges [66][67][68]. MOFs have good stability, high void volumes, well-defined tailorable cavities of uniform size, high surface areas, and adjustable pore sizes [69][70][71]. In particular, the design flexibility for tuning the porosity of MOFs has attracted attention for their usage as hydrogen adsorbents [72].…”

Section: Non-carbonaceous Materials For Hydrogen Storagementioning

confidence: 99%

Recent Progress Using Solid-State Materials for Hydrogen Storage: A Short Review

Lee

Kim

et al. 2022

Processes

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With the rapid growth in demand for effective and renewable energy, the hydrogen era has begun. To meet commercial requirements, efficient hydrogen storage techniques are required. So far, four techniques have been suggested for hydrogen storage: compressed storage, hydrogen liquefaction, chemical absorption, and physical adsorption. Currently, high-pressure compressed tanks are used in the industry; however, certain limitations such as high costs, safety concerns, undesirable amounts of occupied space, and low storage capacities are still challenges. Physical hydrogen adsorption is one of the most promising techniques; it uses porous adsorbents, which have material benefits such as low costs, high storage densities, and fast charging–discharging kinetics. During adsorption on material surfaces, hydrogen molecules weakly adsorb at the surface of adsorbents via long-range dispersion forces. The largest challenge in the hydrogen era is the development of progressive materials for efficient hydrogen storage. In designing efficient adsorbents, understanding interfacial interactions between hydrogen molecules and porous material surfaces is important. In this review, we briefly summarize a hydrogen storage technique based on US DOE classifications and examine hydrogen storage targets for feasible commercialization. We also address recent trends in the development of hydrogen storage materials. Lastly, we propose spillover mechanisms for efficient hydrogen storage using solid-state adsorbents.

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“…Metal–organic frameworks (MOFs) have emerged as a new class of crystalline porous materials; because of their unique features such as high materials variety and designable pores, they are considered for use in various applications such as separation, 1,2 storage, 3,4 delivery, 5,6 and electrolytes. 7–9 MOFs are organic–inorganic hybrid materials and thus have both organic and inorganic characters.…”

Section: Introductionmentioning

confidence: 99%

Support effects of metal–organic frameworks in heterogeneous catalysis

Sadakiyo

2022

Nanoscale

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Ambient-Temperature Hydrogen Storage via Vanadium(II)-Dihydrogen Complexation in a Metal–Organic Framework

Cited by 122 publications

References 63 publications

Densified HKUST-1 Monoliths as a Route to High Volumetric and Gravimetric Hydrogen Storage Capacity

Densified HKUST-1 Monoliths as a Route to High Volumetric and Gravimetric Hydrogen Storage Capacity

Recent Progress Using Solid-State Materials for Hydrogen Storage: A Short Review

Support effects of metal–organic frameworks in heterogeneous catalysis

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