초록 ▼

Provided herein are materials that can achieve up to 14% hydrogen absorption by weight in ambient conditions, which is a marked improvement over the hydrogen absorption values found in the prior art. Further provided are experimental conditions necessary to produce these materials. In order to produ

Provided herein are materials that can achieve up to 14% hydrogen absorption by weight in ambient conditions, which is a marked improvement over the hydrogen absorption values found in the prior art. Further provided are experimental conditions necessary to produce these materials. In order to produce the hydrogen storage material, a transition metal (or Lithium) is vaporized in a pi bond gas in conditions that permit only a few bonding collisions to occur between the vaporized transition metal atoms and pi bond gas molecules before the resulting bonded material is collected.

대표청구항 ▼

1. A process for producing a hydrogen storage material comprising: Vaporizing a transition metal or lithium in a pi-bond gas such that 1 to 100 bonding collisions occur between the atoms of said transition metal or lithium and the pi-bond gas before resulting bonding product is collected. 2. The pro

1. A process for producing a hydrogen storage material comprising: Vaporizing a transition metal or lithium in a pi-bond gas such that 1 to 100 bonding collisions occur between the atoms of said transition metal or lithium and the pi-bond gas before resulting bonding product is collected. 2. The process for producing a hydrogen storage material of claim 1, wherein said material can exhibit a H2 uptake of greater than zero at any temperature up to desorption temperature. 3. The process for producing a hydrogen storage material of claim 1, wherein said transition metal is either Titanium, Scandium, Vanadium, Iron, or Nickel. 4. The process for producing a hydrogen storage material of claim 3, wherein said material can exhibit a H2 uptake of greater than zero at any temperature up to desorption temperature. 5. The process for producing a hydrogen storage material of claim 1, wherein said pi-bond gas is ethylene, benzene, or acetylene. 6. The process for producing a hydrogen storage material of claim 5, wherein said material can exhibit a H2 uptake of greater than zero at any temperature up to desorption temperature. 7. The process for producing a hydrogen storage material of claim 1, wherein said transition metal is either Titanium, Scandium, Vanadium, Iron, or Nickel and said pi-bond gas is ethylene, benzene, or acetylene. 8. The process for producing a hydrogen storage material of claim 7, wherein said material can exhibit a H2 uptake of greater than zero at any temperature up to desorption temperature. 9. The process for producing a hydrogen storage material of claim 1, wherein said transition metal is Titanium, Nickel, Niobium, Iron, or Vanadium and said pi-bond gas is ethylene. 10. The process for producing a hydrogen storage material of claim 9, wherein said pi-bond gas is supplied at a pressure is set between 0 and 760 Torr. 11. The process for producing a hydrogen storage material of claim 10 wherein distance from the titanium, nickel, niobium, iron or vanadium is approximately 2 inches away from where said resulting bonded product is collected. 12. The process for producing a hydrogen storage material of claim 11, wherein an incidental energy used to vaporize the titanium, nickel, niobium, iron, or vanadium ranges from the lowest possible vaporization power up to approximately 2.5 Watts. 13. The process for producing a hydrogen storage material of claim 12, wherein said material can exhibit a H2 uptake of greater than zero at any temperature up to desorption temperature. 14. The process for producing a hydrogen storage material of claim 1, wherein said transition metal is Titanium and said pi-bond gas is benzene. 15. The process for producing a hydrogen storage material of claim 14, wherein said pi-bond gas is supplied at a pressure is set between 0 and 760 Torr. 16. The process for producing a hydrogen storage material of claim 15, wherein distance from the titanium is approximately 2 inches away from where said resulting bonded product is collected. 17. The process for producing a hydrogen storage material of claim 16, wherein an incidental energy used to vaporize the titanium ranges from the lowest possible vaporization power up to approximately 2.5 Watts. 18. The process for producing a hydrogen storage material of claim 17, wherein said material can exhibit a H2 uptake of greater than zero at any temperature up to desorption temperature.