One-step direct synthesis of a Ti-doped sodium alanate hydrogen storage material

2005 ◽  
pp. 4732 ◽  
Author(s):  
José M. Bellosta von Colbe ◽  
Michael Felderhoff ◽  
Borislav Bogdanović ◽  
Ferdi Schüth ◽  
Claudia Weidenthaler
Keyword(s):  
Hydrogen Storage ◽  
Direct Synthesis ◽  
Hydrogen Storage Material ◽  
Storage Material ◽  
Sodium Alanate ◽  
One Step

One-Step Direct Synthesis of a Ti-Doped Sodium Alanate Hydrogen Storage Material.

ChemInform ◽  
2005 ◽  
Vol 36 (51) ◽  
Author(s):  
Jose M. Bellosta von Colbe ◽  
Michael Felderhoff ◽  
Borislav Bogdanovic ◽  
Ferdi Schueth ◽  
Claudia Weidenthaler
Keyword(s):  
Hydrogen Storage ◽  
Direct Synthesis ◽  
Hydrogen Storage Material ◽  
Storage Material ◽  
Sodium Alanate ◽  
One Step

Development of Catalyst-Enhanced Sodium Alanate as an Advanced Hydrogen-Storage Material for Mobile Applications

2017 ◽  
Vol 6 (3) ◽  
pp. 487-500 ◽  
Author(s):  
Yongfeng Liu ◽  
Zhuanghe Ren ◽  
Xin Zhang ◽  
Ni Jian ◽  
Yaxiong Yang ◽  
...  
Keyword(s):  
Hydrogen Storage ◽  
Mobile Applications ◽  
Hydrogen Storage Material ◽  
Storage Material ◽  
Sodium Alanate

scholarly journals Direct Synthesis of NaBH4 Nanoparticles from NaOCH3 for Hydrogen Storage

Energies ◽  
2019 ◽  
Vol 12 (23) ◽  
pp. 4428 ◽  
Author(s):  
Ting Wang ◽  
Kondo-Francois Aguey-Zinsou
Keyword(s):  
Thermodynamic Properties ◽  
Hydrogen Storage ◽  
Fossil Fuels ◽  
Direct Synthesis ◽  
Hydrogen Desorption ◽  
Effective Strategy ◽  
Hydrogen Storage Material ◽  
Storage Material ◽  
Experimental Conditions ◽  
Hydrogen Density

Hydrogen is regarded as a promising energy carrier to substitute fossil fuels. However, storing hydrogen with high density remains a challenge. NaBH4 is a potential hydrogen storage material due to its high gravimetric hydrogen density (10.8 mass%), but the hydrogen kinetic and thermodynamic properties of NaBH4 are poor against the application needs. Nanosizing is an effective strategy to improve the hydrogen properties of NaBH4. In this context, we report on the direct synthesis of NaBH4 nanoparticles (~6–260 nm) from the NaOCH3 precursor. The hydrogen desorption properties of such nanoparticles are reported as well as experimental conditions that lead to the synthesis of (Na2B12H12) free NaBH4 nanoparticles.

Ti decorated B8 as a potential hydrogen storage material: A DFT study with van der Waals corrections

2021 ◽  
Vol 765 ◽  
pp. 138277
Author(s):  
Pingping Liu ◽  
Yafei Zhang ◽  
Xiangjun Xu ◽  
Fangming Liu ◽  
Jibiao Li
Keyword(s):  
Hydrogen Storage ◽  
Van Der Waals ◽  
Dft Study ◽  
Hydrogen Storage Material ◽  
Storage Material

Recent Advances in Hydrogen Storage Materials

2012 ◽  
Vol 512-515 ◽  
pp. 1438-1441 ◽  
Author(s):  
Hong Min Kan ◽  
Ning Zhang ◽  
Xiao Yang Wang ◽  
Hong Sun
Keyword(s):  
Liquid Phase ◽  
Hydrogen Storage ◽  
Earth Metal ◽  
Solid Material ◽  
Hydrogen Energy ◽  
Hydrogen Storage Material ◽  
Ambient Conditions ◽  
Storage Material ◽  
Lithium Borohydride ◽  
Recent Advances

An overview of recent advances in hydrogen storage is presented in this review. The main focus is on metal hydrides, liquid-phase hydrogen storage material, alkaline earth metal NC/polymer composites and lithium borohydride ammoniate. Boron-nitrogen-based liquid-phase hydrogen storage material is a liquid under ambient conditions, air- and moisture-stable, recyclable and releases H2controllably and cleanly. It is not a solid material. It is easy storage and transport. The development of a liquid-phase hydrogen storage material has the potential to take advantage of the existing liquid-based distribution infrastructure. An air-stable composite material that consists of metallic Mg nanocrystals (NCs) in a gas-barrier polymer matrix that enables both the storage of a high density of hydrogen and rapid kinetics (loading in <30 min at 200°C). Moreover, nanostructuring of Mg provides rapid storage kinetics without using expensive heavy-metal catalysts. The Co-catalyzed lithium borohydride ammoniate, Li(NH3)4/3BH4 releases 17.8 wt% of hydrogen in the temperature range of 135 to 250 °C in a closed vessel. This is the maximum amount of dehydrogenation in all reports. These will reduce economy cost of the global transition from fossil fuels to hydrogen energy.

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