Batteries, Energy Storage, Lithium Air and MIT

Batteries

Energy Storage

Lithium Air

MIT

MIT, Toyota team clarifies role of iodide in Li-air batteries

Green Car Congress

AUGUST 15, 2017

Lithium-air (or lithium-oxygen) batteries potentially could offer three times the gravimetric energy of current Li-ion batteries (3500 Wh/kg at the cell level); as such, they are looked to a potential solution for long-range EVs. V), where Li 2 O 2 is formed directly through electrochemical steps. . …

MIT

MIT Li-ion Toyota Batteries

Researchers directly visualize formation and disappearance of Li-O2 reaction products; insights to support development of rechargeable lithium-air batteries

Green Car Congress

OCTOBER 8, 2012

air (Li-O 2 ) battery represents a conceptually attractive energy storage device for electric vehicle applications due to its high theoretical energy storage capacity ( earlier post ); however, among the obstacles to commercialization is a lack of fundamental understanding of the reactions involved.

Lithium Air

Lithium Air Li-ion Recharge Insight

MIT team synthesizes all carbon nanofiber electrodes for high-energy rechargeable Li-air batteries

Green Car Congress

JULY 25, 2011

A team at MIT, led by Carl V. The carbon nanofiber electrodes are substantially more porous than other carbon electrodes, and can therefore more efficiently store the solid oxidized lithium (Li 2 O 2 ) that fills the pores as the battery discharges. Energy Environ. Click to enlarge. —Mitchell et al. Gallant, Carl V.

MIT

MIT Recharge Carbon Lithium Air

MIT study adds more detail to understanding of the evolution of Li2O2 particles in Li-air batteries

Green Car Congress

MARCH 26, 2013

A new study by a team at MIT led by Dr. Yang Shao-Horn and Dr. Carl Thompson sheds more light on the morphological evolution of Li 2 O 2 particles in Lithium-air batteries. Lithium-air (Li?O In previous studies, it has been demonstrated that the first discharge in Li?

MIT

MIT Li-ion Lithium Air Batteries

Bio Batteries: Researchers Use Viruses To Improve Electric-Car Energy Storage (Video)

Green Car Reports

NOVEMBER 15, 2013

Researchers at MIT say that a benign virus could be the next step in improving lithium-air battery technology. In this.'

Energy Storage

Energy Storage Lithium Air MIT Batteries

MIT team discovers new family of materials with best performance yet for oxygen evolution reaction; implications for fuel cells and Li-air batteries

Green Car Congress

SEPTEMBER 19, 2013

MIT researchers have found a new family of highly active catalyst materials that provides the best performance yet in the oxygen evolution reaction (OER) in electrochemical water-splitting—a key requirement for energy storage and delivery systems such as advanced fuel cells and lithium-air batteries.

MIT

MIT Fuel Water Batteries

Nanocomposite of bio-templated manganese oxide and Pd as high-performance cathode for Li-air batteries

Green Car Congress

NOVEMBER 15, 2013

Synthesis step of the metal nanoparticle/M13 virus-templated manganese oxide nanowires (bio MO nanowires) and the operational reaction inside Li-O 2 battery cells. The increase in surface area produced by this method can provide a big advantage in lithium-air batteries’ rate of charging and discharging. Click to enlarge.

Li-ion

Li-ion Batteries Battery Lithium Air

ARPA-E Selects 37 Projects for $106M in Funding in Second Round; Electrofuels, Better Batteries and Carbon Capture

Green Car Congress

APRIL 30, 2010

ARPA-E’s first solicitation awarded $151 million to 37 projects aimed at transformational innovations in energy storage, biofuels, carbon capture, renewable power, building efficiency, vehicles, and other areas. Better Batteries - Batteries for Electrical Energy Storage in Transportation (BEEST).

Carbon

Carbon Batteries Battery Li-ion

Researchers find synergy between lithium polysulfide and lithium nitrate as electrolyte additives prevent dendrite growth on Li metal anodes

Green Car Congress

JUNE 17, 2015

Yet-Min Chiang (a co-founder of A123 Systems) at MIT, have discovered that a synergetic effect resulting from the addition of both lithium polysulfide and lithium nitrate to ether-based electrolyte prevents dendrite growth on Li-metal anodes and minimizes electrolyte decomposition. Researchers from SLAC and Stanford led by Prof.

Lithium Sulfur

Lithium Sulfur Lithium Air Energy Storage Batteries

EV Driven

MIT, Toyota team clarifies role of iodide in Li-air batteries

Researchers directly visualize formation and disappearance of Li-O2 reaction products; insights to support development of rechargeable lithium-air batteries

MIT team synthesizes all carbon nanofiber electrodes for high-energy rechargeable Li-air batteries

MIT study adds more detail to understanding of the evolution of Li2O2 particles in Li-air batteries

Bio Batteries: Researchers Use Viruses To Improve Electric-Car Energy Storage (Video)

MIT team discovers new family of materials with best performance yet for oxygen evolution reaction; implications for fuel cells and Li-air batteries

Nanocomposite of bio-templated manganese oxide and Pd as high-performance cathode for Li-air batteries

ARPA-E Selects 37 Projects for $106M in Funding in Second Round; Electrofuels, Better Batteries and Carbon Capture

Researchers find synergy between lithium polysulfide and lithium nitrate as electrolyte additives prevent dendrite growth on Li metal anodes

Stay Connected