High-capacity hydrogen storage in lithium and sodium amidoboranes

Xiong, Zhitao; Yong, Chaw-Keong; Wu, Guotao; Chen, Ping; Shaw, Wendy J.; Karkamkar, Abhi; Autrey, Tom; Jones, Martin O.; Johnson, Simon R.; Edwards, Peter P.; David, William I. F.

doi:10.1038/nmat2081

Cited by 585 publications

(378 citation statements)

References 24 publications

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“…The Na-N distances in the range of 2.414-2.545 Å are close to the Na-N distance (2.35 Å) in NaNH 2 BH 3 . 13 Such cationic chains are then surrounded by BH 4 À anions with Na and B distances in a range of 2.97 to 3.05 Å. For Mg(BH 4 ) 2 -NH 2 NH 2 complex a new phase with Mg(BH 4 ) 2 /NH 2 NH 2 = 1/3 was identified, which can be indexed using a trigonal P% 31c cell with lattice parameters of a = 13.8385 Å, c = 7.8284 Å, and V = 1298.32 Å 3 .…”

Section: +mentioning

confidence: 99%

Alkali and alkaline-earth metal borohydride hydrazinates: synthesis, structures and dehydrogenation

Chen

et al. 2013

Phys. Chem. Chem. Phys.

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on the other hand, the Li and Na counterparts lost part or all of the hydrazine components under the same condition. In addition, reducing NH 2 NH 2 content in the complexes leads to improved dehydrogenation properties. Mechanistic investigation of Mg(BH 4 ) 2 hydrazinates using isotopic labelling indicates that hydrogen desorption is via homogeneous dissociation of N-N bond of NH 2 NH 2 followed by the establishment of B-N bond and combination of H d + (N) and H dÀ (B).

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Section: +mentioning

confidence: 99%

Alkali and alkaline-earth metal borohydride hydrazinates: synthesis, structures and dehydrogenation

Chen

et al. 2013

Phys. Chem. Chem. Phys.

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“…The interaction between ammonia borane and LiH leads to the formation of LiNH 2 BH 3 with substantially different dehydrogenation behavior. [97,98] Maintaining high-weight-percent hydrogen storage, whilst reducing T dec and enhancing reversibility, will represent a major milestone and a potential "show-stopper" for the transition to a hydrogen economy. However, much more fundamental research is required to understand the physical and chemical Figure 13.…”

Section: Hydrogen Storage Materialsmentioning

confidence: 99%

Functional Materials for Sustainable Energy Technologies: Four Case Studies

Кузнецов

Edwards

2010

ChemSusChem

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The critical topic of energy and the environment has rarely had such a high profile, nor have the associated materials challenges been more exciting. The subject of functional materials for sustainable energy technologies is demanding and recognized as a top priority in providing many of the key underpinning technological solutions for a sustainable energy future. Energy generation, consumption, storage, and supply security will continue to be major drivers for this subject. There exists, in particular, an urgent need for new functional materials for next‐generation energy conversion and storage systems. Many limitations on the performances and costs of these systems are mainly due to the materials′ intrinsic performance. We highlight four areas of activity where functional materials are already a significant element of world‐wide research efforts. These four areas are transparent conducting oxides, solar energy materials for converting solar radiation into electricity and chemical fuels, materials for thermoelectric energy conversion, and hydrogen storage materials. We outline recent advances in the development of these classes of energy materials, major factors limiting their intrinsic functional performance, and potential ways to overcome these limitations.

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“…1) In contrast to the compressed hydrogen and the liquefaction hydrogen, hydrogen storage in the solid state is the most promising alternative. [2][3][4][5] In the past decades, the complex hydrides consisting of light elements, e.g., alanates, [6][7][8][9][10] amides, [11][12][13][14][15] borohydrides [16][17][18][19][20] and ammonia borane (AB), [21][22][23] have been attracting extensive attention as the potential hydrogen storage materials due to their high gravimetric and volumetric hydrogen storage densities. In particular, significant efforts have been made in recent years with metal amide-hydride combined systems since Chen et al reported that lithium nitride, Li 3 N could absorb/desorb reversibly 11.4 mass% of hydrogen in 2002.…”

Section: Introductionmentioning

confidence: 99%

“…12) Recently, a dramatically improved dehydrogenation performance was obtained through substituting one or two H atoms in the NH 3 group of ammonia borane (AB) by alkali or alkaline-earth metals. 22,29) Xiong et al reported that $ 10:9 mass% hydrogen was librated from LiNH 2 BH 3 obtained by ball milling the mixture of NH 3 BH 3 and LiH at significantly lower temperatures with respect to NH 3 BH 3 itself. 22) More interestingly, the reaction between NH 3 BH 3 and LiH in THF delivers more than 14 mass% of hydrogen at a temperature as low as 40 C. 30) Significantly, combining compounds containing NH x group with metal hydrides results in interesting hydrogen storage systems with improved thermodynamics and kinetics.…”

Section: Introductionmentioning

confidence: 99%

Hydrogen Storage Properties of the Mg(NH3)6Cl2-LiH Combined System

Liu

Luo

et al. 2011

Mater. Trans.

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Metal ammine complexes (MACs) were recently regarded as one of promising materials for reversible hydrogen storage due to their high hydrogen content. In this work, a first attempt is conducted to elucidate the hydrogen storage reversibility by combining Mg(NH 3 ) 6 Cl 2 with LiH. It is found that hydrogen is gradually evolved from the combined system during ball milling. After 24 h of milling, approximate 3.5 mass% of hydrogen, equivalent to 6 mol of H 2 molecules, is released from the Mg(NH 3 ) 6 Cl 2 -18LiH mixture. Additional 3.4 mass% of hydrogen is further desorbed from the combined system milled for 24 h with a two-step reaction in heating process. Totally $ 12 mol of H 2 molecules are librated from the Mg(NH 3 ) 6 Cl 2 -18LiH mixture along with the formation and consumption of Mg(NH 2 ) 2 and LiNH 2 in the ball milling and subsequent heating process. The resultant products consist of Li 2 Mg(NH) 2 , Li 2 NH, LiH and LiCl after dehydrogenation at 310 C. Further hydrogenation experiment indicates that $ 6 mol of H 2 molecules are reversibly stored in the Mg(NH 3 ) 6 Cl 2 -12LiH mixture.

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High-capacity hydrogen storage in lithium and sodium amidoboranes

Cited by 585 publications

References 24 publications

Alkali and alkaline-earth metal borohydride hydrazinates: synthesis, structures and dehydrogenation

Alkali and alkaline-earth metal borohydride hydrazinates: synthesis, structures and dehydrogenation

Functional Materials for Sustainable Energy Technologies: Four Case Studies

Hydrogen Storage Properties of the Mg(NH<SUB>3</SUB>)<SUB>6</SUB>Cl<SUB>2</SUB>-LiH Combined System

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