Green Car Congress

FEBRUARY 21, 2012

Merck has more than 10 years experience in the production of electrolytes for Li-ion batteries and supercapacitors. Also included in the transaction is a variety of additives for electrolytes used to produce lithium-ion batteries (LIBs). Earlier post.) Earlier post.) Earlier post.).

Li-ion 225

Li-ion Lithium Sulfur Batteries Battery 225

Green Car Congress

MARCH 26, 2021

The electrolyte not only suppresses side reactions, stress-corrosion cracking, transition-metal dissolution and impedance growth on the cathode side, but also enables highly reversible Li metal stripping and plating on the lithium-metal anode (LMA), leading to a compact morphology and low pulverization.

Ni-Li 284

Ni-Li MIT Li-ion Batteries 284

Green Car Congress

FEBRUARY 20, 2019

PolyPlus Battery Company a privately-held company focused on the development of the first rechargeable Li metal battery with a ionically conductive glass separator, has entered into the first stage of a joint development agreement with SK Innovation Co. Korea’s first and largest energy and chemical company.

Li-ion 220

Li-ion Lithium Sulfur Batteries Battery 220

Green Car Congress

JUNE 24, 2009

General schematic of a lithium-air battery. The team plans to explore rechargeable Lithium-Air systems, which could offer 10 times the energy capacity of lithium-ion systems. Lithium-ion rechargeable (secondary) batteries are based on a pair of intercalation electrodes.

Lithium Air 150

Lithium Air Energy Storage Li-ion San Jose 150

Green Car Congress

JULY 27, 2014

are proposing a new sealed rechargeable battery system operating on a redox reaction between an oxide (O 2- ) and a peroxide (O 2 2- ) in the cathode. V)—about on par with Li-sulfur’s very high theoretical energy density of ~2,600 Wh kg -1 (based on lithium-sulfur redox couple, e.g., earlier post ). Wh kg -1 (897?mAh

Li-ion 225

Li-ion Recharge Batteries Battery 225

Green Car Congress

FEBRUARY 1, 2013

Researchers at startup Liox Power, a California-based company developing rechargeable Li-air batteries, have demonstrated for the first time the operation of a lithium-air battery with a Li anode in a straight-chain alkyl amide electrolyte solvent (N,N-dimethylacetamide (DMA)/lithium nitrate (LiNO 3 )).

Li-ion 353

Li-ion Lithium Air Batteries Battery 353

Green Car Congress

MARCH 16, 2014

Researchers at Mie University in Japan have developed a new protected lithium electrode for aqueous lithium/air rechargeable batteries. Lead researcher Nobuyuki Imanishi said that the system has a practical energy density of more than 300 Wh/kg, about twice that of many commercial lithium-ion batteries.

Universal 236

Universal Li-ion Lithium Air Batteries 236

Green Car Congress

MAY 1, 2017

Lithium-air (Li-O 2 ) batteries are among the nost energy-dense electrochemical platforms for mobile energy storage, and are thus considered promising for electrified transportation. the formation of a stable interphase with lithium, protecting the metal while promoting ion transport. —Choudhury et al.

Li-ion 170

Li-ion Batteries Battery Recharge 170

Green Car Congress

MARCH 12, 2012

In an open access paper published in the International Journal of Smart and Nano Materials , researchers from the Changchun Institute of Applied Chemistry, Chinese Academy of Sciences review significant developments and remaining challenges of practical Li–air batteries and the current understanding of their chemistry.

Li-ion 285

Li-ion Future Batteries Battery 285

Green Car Congress

MARCH 11, 2011

Scientists at the National Institute of Advanced Industrial Science and Technology in Japan have made an electrode for a lithium-air battery using a pencil. Haoshen Zhou and Yonggang Wang designed a battery in which the lithium is encapsulated by an organic electrolyte topped with a ceramic protection layer. Energy Environ.

Li-ion 210

Li-ion Lithium Air Lithium Ion Recharge 210

Green Car Congress

OCTOBER 24, 2013

Andrews in Scotland report in a paper in the journal Nature Materials that titanium carbide (TiC) may represent a viable, stable cathode for rechargeable lithium-air batteries. Li-air batteries are receiving intense interest because of their extremely high theoretical specific energy.

Li-ion 236

Li-ion Batteries Battery Lithium Air 236

Green Car Congress

DECEMBER 13, 2011

A study led by researchers from Argonne National Laboratory reinforced that electrolyte solvent stability plays a key role in the performance of Lithium-air batteries, and that making advances in new electrolytes will be a key factor in reducing the large overpotential and improving reversibility of Li-air batteries.

Li-ion 218

Li-ion Lithium Air Batteries Battery 218

Green Car Congress

JANUARY 23, 2014

Although lithium metal is a promising anode material for Li-ion rechargeable batteries due to its theoretical high capacity (3,860?mAh It is obvious that Li–S and Li–air batteries have the potential to considerably improve the driving ranges of EVs. 1 —i.e., ~10x 10x that of the 372?mAh

Li-ion 268

Li-ion South Korea Lithium Sulfur Batteries 268

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. Given the role of carbon as a possible porous positive electrode for nonaqueous Li?O

Carbon 240

Carbon Li-ion Batteries Battery 240

Green Car Congress

MARCH 7, 2018

Lithium-metal batteries are among the most promising candidates for high-density energy storage technology, but uncontrolled lithium dendrite growth, which results in poor recharging capability and safety hazards, currently is hindering their commercial potential. Source: Wang et al. Click to enlarge. —Hanqing Jiang.

Li-ion 150

Li-ion Arizona Lithium Ion Sodium 150

Green Car Congress

DECEMBER 19, 2013

Researchers at Lawrence Berkeley National Laboratory have shed new light on the formation of dendrites in high energy density rechargeable batteries with lithium metal anodes. The electrodes in today’s lithium ion batteries are porous, and about 30 vol% of the electrode is taken up by inactive phases. Energy Environ.

Li-ion 225

Li-ion Recharge Polymer Batteries 225

Green Car Congress

OCTOBER 26, 2015

Next, we will briefly review the current status and the expected future progress in lithium ion battery (LiB) technology, which is currently used to power BEVs. In some studies it has been noted that the adequate BEV range perceived by the customer could be lower if the recharging time would be sufficiently short. kgH 2 /min.

Lithium Sulfur 150

Lithium Sulfur Electric Vehicles Li-ion Batteries 150

Green Car Congress

JULY 9, 2010

Four different architectures of Li-air batteries, which all assume the use of lithium metal as the anode. IBM and its partners have launched a multi-year research initiative exploring rechargeable Li-air systems: The Battery 500 Project. Considerations for Li-air systems include: Power density and cost.

Li-ion 239

Li-ion Transportation Batteries Battery 239

Green Car Congress

NOVEMBER 18, 2017

A deeper understanding of the charging and discharging reactions is viewed as the key for the further development of this type of rechargeable battery to market maturity. The oxygen required for the reaction can be drawn from the surrounding air so that it does not need to be stored in the battery. —Weinrich et al.

Energy 170

Energy Batteries Battery Lithium Ion 170

Green Car Congress

APRIL 30, 2010

Electrofuels approaches will use organisms able to extract energy from other sources, such as solar-derived electricity or hydrogen or earth-abundant metal ions. Li-S Battery : Development of High Energy Li-S Cells for Electric Vehicles. This process is less than 1% efficient at converting sunlight to stored chemical energy.

Carbon 249

Carbon Batteries Battery Li-ion 249

Green Car Congress

MAY 14, 2010

On discharge, the metallic lithium (anode) is converted into lithium ions and the generated lithium ions diffuse from the organic solution across the LISICON film to the aqueous solution. Only lithium ions can pass across the LISICON film. Simultaneously, hydrogen gas is generated on the cathode.

Water 186

Water Lithium Ion Li-ion Hydrogen 186

Green Car Congress

APRIL 2, 2010

A team of researchers at MIT led by Professor Yang Shao-Horn have found that gold-carbon (Au/C) and platinum-carbon (Pt/C) catalysts have a strong influence on the charge and discharge voltages of rechargeable lithium-air (Li-O 2 ) batteries, and thus enable a higher efficiency than simple carbon electrodes in these batteries.

Lithium Air 218

Lithium Air MIT Li-ion Batteries 218

Green Car Congress

JUNE 21, 2013

A team of researchers in South Korea found that Li?air air battery performance is significantly altered by the presence of CO 2. Furthermore, they added, the possibility for a rechargeable Li–O 2 /CO 2 battery based on Li 2 CO 3 may have merits in enhancing cyclability by minimizing side reactions. To develop a Li?“air”

Li-ion 305

Li-ion CO2 Batteries Battery 305

Green Car Congress

AUGUST 24, 2020

For example, most reported structural batteries use Li-ion chemistries (238 Wh kg cell –1 ) that can experience thermal runaway if damaged by mechanical loads. Unfortunately, more energy-dense, li-based chemistries such as lithium-sulfur and lithium-air can also experience thermal runaway. Hopkins et al.

Zinc Air 243

Zinc Air Design Batteries Battery 243

Green Car Congress

OCTOBER 30, 2015

Researchers at the University of Cambridge have developed a working laboratory demonstrator of a lithium-oxygen battery which has very high energy density, is more than 90% efficient, and, to date, can be recharged more than 2000 times, showing how several of the problems holding back the development of these devices could be solved.

Li-ion 150

Li-ion Batteries Battery Lithium Air 150

Green Car Congress

DECEMBER 29, 2010

Also on the list of five is the arrival of advanced batteries, including air batteries (e.g., Lithium air), but targeted initially at small devices. If successful, the result will be a lightweight, powerful and rechargeable battery capable of powering for everything from electric cars to consumer devices. Earlier post.).

Personal 210

Personal Transportation Water Batteries 210

Green Car Congress

MAY 13, 2013

Researchers at MIT, the University of Pittsburgh, and Sandia National Laboratories have used transmission electron microscope (TEM) imaging to observe the electrochemical oxidation of Li 2 O 2 , providing insights into the rate-limiting processes that govern charge in Li–O 2 cells. Oxidation of Li 2 O particles. (a)

Transportation 186

Transportation Li-ion Charging Lithium Air 186

Green Car Congress

SEPTEMBER 13, 2013

Generalized form of the molten air battery. Researchers at George Washington University led by Dr. Stuart Licht have introduced the principles of a new class rechargeable molten air batteries that offer amongst the highest intrinsic electric energy storage capabilities. Licht et al. Click to enlarge. Earlier post.]

Energy 309

Energy Batteries Battery Recharge 309