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 million in cost-sharing by recipients for a total of $15.3 Murray, Jr.,

Energy Storage 218

Energy Storage New York Commercial Lithium Ion 218

Green Car Congress

APRIL 30, 2010

The US Department of Energy is awarding $106 million in funding for 37 research projects selected in the second round by the DOE’s Advanced Research Projects Agency-Energy (ARPA-E). Evaluations were based on scientific and technical merit and the potential for high impact on national energy and economic goals. Earlier post.).

Carbon 249

Carbon Batteries Battery Li-ion 249

Green Car Congress

DECEMBER 28, 2012

Carbon is seen as an attractive potential cathode material for aprotic (non-aqueous) Lithium-air batteries, which are themselves of great interest for applications such as in electric vehicles because of the cells’ high theoretical specific energy.

Carbon 240

Carbon Li-ion Batteries Battery 240

Driivz

NOVEMBER 2, 2023

All are counting on battery innovations to improve EV performance, drive down costs, and eliminate dependence on scarce materials. The ideal battery will be made of low-cost, plentiful materials that are lightweight and flexible enough to allow vehicle design innovations.

Batteries 52

Batteries Battery Lithium Ion Sodium 52

Green Car Congress

OCTOBER 26, 2015

They begin by observing that the EU’s goal of 95 gCO 2 /km fleet average emissions by 2020 can only be met by means of extended range electric vehicles or all-electric vehicles in combination with the integration of renewable energy (e.g., For a 100 mile-range BEV requiring ≈21 kWh net , complete recharge could be accomplished within ≈60 min.

Lithium Sulfur 150

Lithium Sulfur Electric Vehicles Li-ion Batteries 150

Green Car Congress

MARCH 18, 2013

The committee then analyzed the performance and cost impacts of the various options in different scenarios. Vehicle and fuel data were then used to forecast future LDV fleet energy use and GHG emissions using two models, as well comparing different policy-driven scenarios. Such a transition will be costly and require several decades.

Hydrogen 244

Hydrogen Oil Plug-in Fuel Economy 244