Green Car Congress

JUNE 24, 2009

General schematic of a lithium-air battery. Leveraging expertise in materials science, nanotechnology, green chemistry and supercomputing, scientists at IBM Research’s Almaden lab in San Jose, California, are undertaking a multi-year research initiative around a grid-scale, efficient, affordable electrical energy storage network.

Lithium Air 150

Lithium Air Energy Storage Li-ion San Jose 150

Green Car Congress

MARCH 8, 2013

Schematic illustration of the aqueous rechargeable lithium battery (ARLB) using the coated lithium metal as anode, LiMn 2 O 4 as cathode and 0.5 If anode materials of lower redox potentials can be stable in aqueous electrolytes, high energy density systems will be feasible. Higher practical energy density.

Li-ion 281

Li-ion Low Cost Recharge Ni-Li 281

Green Car Congress

MARCH 11, 2010

The New York State Energy Research and Development Authority (NYSERDA) will award $8 million to help develop or commercialize 19 advanced energy storage projects. The 19 projects, which include two lithium-air efforts, will leverage $7.3 The 19 projects, which include two lithium-air efforts, will leverage $7.3

Energy Storage 218

Energy Storage New York Commercial Lithium Ion 218

Green Car Congress

MAY 14, 2010

Schematic representation and operating principles of the lithium–water electrochemical cell used for hydrogen generation: (1) external circuit and (2) inside of lithium–water electrochemical cell. Another attractive aspect of this technology is that lithium metal can be produced from salt solutions (e.g., Source: Wang et al.

Water 186

Water Lithium Ion Li-ion Hydrogen 186