High surface area microporous carbon materials for cryogenic hydrogen storage synthesized using new template-based and activation-based approaches.

High surface area microporous carbon materials were synthesized using new, simple, and innovative approaches based on traditional template and chemical activation methods. The resulting surface area and porosity were characterized using Brunauer-Emmett-Teller (BET)-type measurements and analysis, and the hydrogen storage capacity was determined using excess hydrogen adsorption measurements at 77 K and up to 40 bar hydrogen pressure. For our direct one-step aerosol-assisted template-based synthesis method of mixing the template precursor and carbon precursor solutions, a specific surface area value of up to nearly 2000 m(2) g(-1) and an excess hydrogen storage capacity of 4.

Hydrogen desorption exceeding ten weight percent from the new quaternary hydride Li3BN2H8.

Mobile applications of hydrogen power have long demanded new solid hydride materials with large hydrogen storage capacities. We report synthesis of a new quaternary hydride having the approximate composition Li(3)BN(2)H(8) with 11.9 wt % theoretical hydrogen capacity.

Improved hydrogen release from LiB0.33N0.67H2.67 with noble metal additions.

The hydrogen release behavior of the quaternary hydride LiB(0.33)N(0.67)H(2.

Hydrogen release from mixtures of lithium borohydride and lithium amide: a phase diagram study.

We recently reported the synthesis of a new quaternary hydride in the lithium-boron-nitrogen-hydrogen quaternary phase diagram with the approximate composition LiB0.33N0.67H2.

On the composition and crystal structure of the new quaternary hydride phase Li4BN3H10.

X-ray data on single crystals of the quaternary metal hydride near the composition LiB(0.33)N(0.67)H(2.