Green Car Congress

FEBRUARY 17, 2020

CBMM’s market dominance will continue as the group will expand its production capacity by 50% in 2020 and is considering more capacity increases in coming years. The maximum power output and minimum charging time of a lithium-ion battery depend on both ionic and electronic transport. The paper (Griffith et al. ) Griffith et al.

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Li-ion Industrial Industry Lithium Ion 378

Green Car Congress

JULY 26, 2018

Researchers from the University of Cambridge, with colleagues from Argonne National Laboratory in the US and Diamond Light Source, Harwell Science and Innovation Campus, UK, have identified a group of materials—niobium tungsten oxides—that could be used to make even higher power batteries. Griffith et al.

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Li-ion Lithium Ion Charging Batteries 247

Green Car Congress

JANUARY 25, 2018

Engineers at the University of California San Diego and the University of California Los Angeles have developed an energy-efficient approach to regenerate Li-ion battery cathode materials (using LiCoO 2 as a model material) by hydrothermal treatment of cycled electrode particles followed by short annealing.

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Li-ion San Diego Lithium Ion Energy 225

Green Car Congress

OCTOBER 25, 2018

Australian advanced materials technology company Talga Resources Ltd announced positive initial test results from the development of its graphene silicon lithium-ion anode in the UK. The Safevolt project is an enabler for industry wanting higher Li-ion battery capacity above the level of standard graphite (exceeding maximum 372 mAh/g).

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Li-ion Batteries Battery Lithium Ion 268

Green Car Congress

MARCH 3, 2023

This is the first time that spherodized vein graphite materials were tested in a lithium-ion battery full cell. SEM image of spherodized material The tests were conducted at Warwick Manufacturing Group (WMG), part of University of Warwick’s Energy Innovation Centre.

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Li-ion Batteries Battery Lithium Ion 243

Green Car Congress

JUNE 2, 2021

In January, the California Energy Commission (CEC) released a competitive solicitation ( GFO-20-308 ) to fund applied research and development (ARD) projects that improve, scale-up, and increase the technology readiness of high-value direct recycling processes for lithium-ion batteries. e00152 (open access).

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Li-ion Lithium Ion California San Diego 243

Green Car Congress

AUGUST 22, 2022

Researchers at Nanjing University (China) have introduced a new layered C2/m oxide—Li 2 Ni 0.2 Compared with Li 2 MnO 3 (LMO), LNMR displays superior capacity, a more stable capacity retention rate, higher energy density and average discharge voltage. In such materials, 1/3 of the TM sites are occupied by Li phase.

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Ni-Li Li-ion Design Lithium Ion 365

Green Car Congress

MAY 10, 2019

A team of researchers led by a group from the University of Maryland has. volts versus Li/Li +. Combining this cathode with a passivated graphite anode, the team created a 4V-class aqueous Li-ion full cell with an energy density of 460 Wh kg -1 of total composite electrode and about 100% Coulombic efficiency.

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Li-ion Conversion Energy Batteries 271

Green Car Congress

AUGUST 26, 2021

Researchers at Chalmers University of Technology, Sweden, have developed a nanometric graphite-like anode for sodium ion (Na + storage), formed by stacked graphene sheets functionalized only on one side, termed Janus graphene. Na is comparable to graphite for standard lithium ion batteries. 100 to 150 mA h g ?

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Sodium Li-ion Lithium Ion Batteries 493

Green Car Congress

APRIL 2, 2019

The Rice University lab of materials scientist Pulickel Ajayan has used an environmentally friendly deep eutectic solvent to extract valuable elements from the metal oxides commonly used as cathodes in lithium-ion batteries. As a whole, recycling lithium-ion batteries is typically expensive and a risk to workers.

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Li-ion Lithium Ion Batteries Battery 230

Green Car Congress

NOVEMBER 27, 2021

Australia-based Li-S Energy has entered into an agreement with Janus Electric to develop and to test lithium sulfur and/or lithium-metal battery cells to suit the requirements of the Janus Electric exchangeable prime mover battery packs. MWh) by the end of 2023, with additional demand growth expected in future years.

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Lithium Sulfur Li-ion Lithium Ion Energy 243

Green Car Congress

DECEMBER 1, 2020

Magnesium batteries have long been considered a potentially safer and less expensive alternative to lithium-ion batteries, but previous versions have been severely limited in the power they delivered. Magnesium ions hold twice the charge of lithium, while having a similar ionic radius. —Dong et al.

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Li-ion Batteries Battery Power 373

Green Car Congress

DECEMBER 21, 2022

Rice University scientists led by chemist James Tour have used an ultrafast flash recycling method to regenerate the graphite anode from spent Li-ion batteries and recover valuable battery metal resources. The particles are recovered from lithium-ion batteries and treated through Rice’s flash Joule heating process.

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Li-ion Lithium Ion Waste Batteries 243

Green Car Congress

MARCH 13, 2020

Commercial fast-charging stations subject electric car batteries to high temperatures and high resistance that can cause them to crack, leak, and lose their storage capacity, according to researchers at the University of California, Riverside (UCR) in a new open-access study published in the journal Energy Storage. Akhavi Yige Li Cengiz S.

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International Commercial Charging Li-ion 524

Green Car Congress

SEPTEMBER 14, 2014

A new study has found that rapid-charging a lithium-ion battery and using it to do high-power, rapidly draining work may not be as damaging as researchers had thought, and that the benefits of slow draining and charging may have been overestimated. For this study scientists looked at a lithium iron phosphate cathode material.

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Lithium Ion Li-ion Charging MIT 381

Green Car Congress

APRIL 30, 2022

The selected projects are: Advanced Manufacturing Process Innovations – Flex-Ion Battery Innovation Center. Lead: Ventra Group Co.; The Flex-Ion Battery Innovation Center, a division of Ventra Group Co., will establish a center of excellence for advanced Li-Ion battery manufacturing, in collaboration with partner eCAMION.

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Canada Li-ion Emissions Vehicles 304

Green Car Congress

AUGUST 16, 2023

Yaocai Bai and Yuzhang Li have received the 2023–2024 ECS Toyota Young Investigator Fellowships for projects in green energy technology. Dr. Bai received his BS in Materials Chemistry from the University of Science and Technology of China in 2010 and MS in Materials Science in 2012 from King Abdullah University of Science and Technology.

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Toyota Li-ion Los Angeles San Francisco 270

Green Car Congress

JUNE 10, 2021

Conventional Li-ion batteries work by cationic redox, when a metal ion changes its oxidation state as lithium is inserted or removed. Within this insertion framework, only one lithium-ion can be stored per metal ion. Lithium-rich cathodes, however, can store much more. —Li et al.

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Li-ion Batteries Battery Lithium Ion 221

Green Car Congress

AUGUST 15, 2016

In a 2014 paper exploring prospects for reducing the processing cost of Li-ion batteries, a team from Oak Ridge National Laboratory (ORNL) explained that formation cycling refers to the electrochemical side reactions involved with creating the solid electrolyte interface (SEI) layer. —Wood et al.

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Li-ion Lithium Ion Batteries Battery 150

Green Car Congress

AUGUST 5, 2019

With a new coating process, researchers of Karlsruhe Institute of Technology (KIT) have produced electrodes for lithium-ion batteries at record speed. Due to the high reject rate and the low throughput, lithium-ion batteries today are more expensive than actually necessary. Quicker coating requires shorter drying times.

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Kits Li-ion Lithium Ion Batteries 321

Green Car Congress

JULY 29, 2021

Awardees across 12 projects will focus on developing next-generation lithium batteries with improved lifespan, safety, and affordability; improving the performance and durability of electrolytes that carry ions within batteries; and increasing the power density of electric drive systems. SUNY University @ Stony Brook.

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Li-ion Emissions Lithium Sulfur Lithium Ion 186

Green Car Congress

DECEMBER 20, 2016

Garnet-type solid-state electrolytes (SSEs) for Li-ion batteries offer a range of attractive benefits, including high ionic conductivity (approaching 1 mS cm −1 at room temperature); excellent environmental stability with processing flexibility; and a wide electrochemical stability window. With the garnet composition Li 7 La 2.75

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Li-ion Lithium Ion Batteries Battery 150

Green Car Congress

MAY 13, 2017

Researchers at the University of Illinois, Xerion Advanced Battery Corporation and Nanjing University in China have developed a method for electroplating lithium-ion battery cathodes, yielding high-quality, high-performance battery materials that could also enable flexible and solid-state batteries. Click to enlarge.

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Li-ion Lithium Ion Molten Salt Illinois 170

Green Car Congress

JUNE 17, 2015

Researchers at the University of Tokyo and Tokyo Institute of Technology have discovered the structure and transport properties of an “intermediate state” in LiFePO 4 lithium-ion batteries. The group found a striped pattern of layers of densely and loosely packed electrons. The findings were contrary to expectations.

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Li-ion Lithium Ion Transportation Charging 150

Green Car Congress

OCTOBER 26, 2018

The Rice University lab of chemist James Tour has shown that thin nanotube films effectively stop dendrites that grow naturally from unprotected lithium metal anodes in batteries. Here, it is shown that lithiated multiwall carbon nanotubes (Li?MWCNTs) Courtesy of the Tour Group. —Salvatierra et al.

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Li-ion Lithium Ion Carbon Universal 207

Green Car Congress

DECEMBER 19, 2011

A team from Hanyang University (S. Korea), Northwestern University, Samsung Electronics Co. and the University of Illinois at Urbana – Champaign has developed a double-layered silicon-germanium nanotube array as an anode material for high-capacity lithium-ion batteries. Credit: ACS, Song et al. Click to enlarge.

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Li-ion Lithium Ion Universal Illinois 225

Green Car Congress

SEPTEMBER 14, 2021

One such technology could be lithium-sulfur batteries (Li-S): which theoretically store as much as five times the energy of Li-ion and have a realizable specific energy of 400–600?Wh?kg In theory, lithium-sulfur batteries could store two to five times more energy than lithium-ion batteries of the same weight.

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Lithium Sulfur Li-ion Batteries Battery 327

Green Car Congress

JULY 7, 2016

Silatronix, a developer of unique organosilicon (OS) electrolytes for use in lithium-ion batteries (LIBs) ( earlier post ), has raised US$8 million in new equity capital, and secured partnerships for distribution and joint technological development. Current Li-ion electrolytes are unstable above 60 °C and at charge voltages above 4.3

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Li-ion Batteries Battery Wisconsin 150

Green Car Congress

JUNE 26, 2018

A international team of researchers, led by Lancaster University in the UK and Jilin University in China, reports the first organically synthesized sp?sp The new carbon shows electron conductivity, high porosity, the highest uptake of lithium ions of any carbon material to?date sp 3 hybridized porous carbon, OSPC?1.

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Li-ion Carbon Lithium Ion Store 170

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 mol l -1 Li 2 SO 4 aqueous solution as electrolyte. Here we introduce a coating layer on lithium metal. The coated lithium metal is stable in aqueous electrolytes.

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Li-ion Low Cost Recharge Ni-Li 281

Green Car Congress

JUNE 4, 2014

In an event in San Francisco, Ford Motor Company and Samsung SDI, an affiliate of Samsung Group, outlined several collaborative research efforts on next-generation battery technology for non-hybrid vehicles. The research advances lithium-ion battery technology currently available on Ford’s electrified vehicles. Click to enlarge.

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Li-ion Lead Acid Ford Batteries 231

Green Car Congress

JUNE 10, 2019

Because of their high energy-storage density, materials such as metal oxides, sulfides, and fluorides are promising electrode materials for lithium-ion batteries in electric vehicles and other technologies. —Sooyeon Hwang, a staff scientist in the CFN Electron Microscopy Group. However, their capacity fades very rapidly.

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Lithium Ion Li-ion Batteries Battery 236

Green Car Congress

AUGUST 4, 2014

CD-adapco announced the successful completion of a project to develop advanced Li-ion battery stimulation tools to enable faster design and development of advanced electric drive vehicle power systems. —Ahmad Pesaran, Energy Storage Group Manager in NREL’s Transportation and Hydrogen Systems Center. Earlier post.).

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Li-ion Lithium Ion Batteries Battery 230

Green Car Congress

JULY 17, 2012

Researchers at Rice University and Lockheed Martin have developed a method for creating macroporous silicon thin films (MPSF) for use as cost-effective and high-performance anode materials in Li-ion batteries. lithium atoms per silicon atom, Li 22 Si 5. Credit: ACS, Thankur et al. Click to enlarge.

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Li-ion Universal Lithium Ion Batteries 231

Green Car Congress

SEPTEMBER 9, 2011

Reversible Li extraction capacity of nanoSi electrodes with alginate, CMC and PVDF binders vs. cycle number collected for the current density of 4200 mA g –1 for cells cycled in the potential window of 0.01-1 1 V vs. Li/Li +. Click to enlarge. —Kovalenko et al.

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Li-ion Lithium Ion Batteries Battery 301

Green Car Congress

JANUARY 23, 2017

Researchers at Northwestern University, with a colleague from the University of Wisconsin, Madison, have developed a new computational design framework that can pinpoint optimal materials with which to coat the cathode in lithium-ion batteries. —Christopher Wolverton. Muratahan Aykol, Soo Kim, Vinay I.

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Li-ion Design Wisconsin Lithium Ion 150

Green Car Congress

OCTOBER 20, 2022

Anovion, with its partners, collaborators and stakeholders, will build 35,000 tons per annum of new synthetic graphite anode material capacity for lithium-ion batteries used in electric vehicles and critical energy storage applications. Li 2 O spodumene concentrate. Materials Separation & Processing (Cathode Minerals).

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Parts Batteries Battery Lithium Ion 459