Green Car Congress

DECEMBER 25, 2020

FREYR AS and 24M Technologies signed a definitive License and Services Agreement to use 24M’s SemiSolid lithium-ion battery platform technology ( earlier post ) in FREYR’s planned facilities in Mo i Rana, Norway. 24M’s SemiSolid battery cell simplifies and enables stronger recycling opportunities.

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Li-ion Lithium Ion Batteries Battery 350

Green Car Congress

MAY 28, 2018

Researchers at the University of Akron have developed hierarchical porous Mn 3 O 4 /C nanospheres as anode materials for Li-ion batteries. mA/g), excellent ratability (425 mAh/g at 4 A/g), and extremely long cycle life (no significant capacity fading after 3000 cycles at 4A/g) as an anode in a Li-ion battery.

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Li-ion Ni-Li Batteries Battery 199

Green Car Congress

MARCH 27, 2023

Researchers from the Korea Electrotechnology Research Institute (KERI) and Kumoh National Institute of Technology (KIT), have developed a low-cost production technology for silicon disulfide (SiS 2 ) for solid-state electrolytes (argyrodite-type) that has potential to accelerate the commercialization of all-solid-state batteries (ASSBs).

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Li-ion Production Batteries Battery 243

Green Car Congress

NOVEMBER 25, 2019

The new funds will be used to scale-up manufacturing of a next-generation silicon-carbon composite anode material and advance into commercial production. Group14 Technologies—a 2016 spin-off from EnerG2—derives its name from the Periodic Table column listing both silicon and carbon (the carbon group).

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Financing Carbon Li-ion Lithium Ion 243

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

OCTOBER 20, 2022

billion to 21 projects to expand domestic manufacturing of batteries for electric vehicles (EVs) and the electrical grid and for materials and components currently imported from other countries. The US Department of Energy (DOE) is awarding a combined $2.8 Earlier post.) Of that, $1.6 Materials Separation & Processing (Cathode Minerals).

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Parts Batteries Battery Lithium Ion 459

Green Car Congress

JUNE 15, 2023

Prelithiation involves preloading the anode material with lithium prior to assembling the battery, as opposed to the conventional process of intercalating Li ions into the electrode material during the initial charge-discharge cycles of the assembled battery.

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Li-ion Lithium Ion Companies Low Cost 150

Green Car Congress

JUNE 24, 2020

The COBRA (CObalt-free Batteries for FutuRe Automotive Applications) project has been awarded a €11.8-million million grant to develop Next Generation Cobalt-free batteries. The project will result in a unique battery system that features superior energy density, low cost, increased cycles and reduced critical materials.

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Batteries Battery Li-ion 2000 360

Green Car Congress

DECEMBER 18, 2014

Korea) has developed a novel high-voltage electrolyte additive, di-(2,2,2 trifluoroethyl)carbonate (DFDEC), for use with the promising lithium-rich layered composite oxide high-energy cathode material xLi 2 MnO 3 ·(1-x)LiMO 2 (M = Mn, Ni, Co). O 2 (Li 1.2 V with 5 wt% of the fluorinated linear carbonate DFDEC as an additive.

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Li-ion Ni-Li Energy Lithium Ion 329

Green Car Congress

APRIL 23, 2017

Researchers at the University of California, Riverside’s Bourns College of Engineering have used waste glass bottles and a low-cost chemical process to fabricate nanosilicon anodes for high-performance lithium-ion batteries.

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Li-ion Waste Lithium Ion Batteries 150

Green Car Congress

MARCH 19, 2014

The nanocrystals possess high and similar Li-ion and Na-ion charge storage capacities of 580?640 85% of the low-rate value, indicating that rate capability of Sb nanostructures can be comparable to the best Li-ion intercalation anodes and is so far unprecedented for Na-ion storage. 640 mAh g ?1

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Li-ion Sodium Batteries Battery 220

Green Car Congress

SEPTEMBER 24, 2021

University of California San Diego nanoengineers, in collaboration with researchers at LG Energy Solution, have developed a battery that combines a solid-state electrolyte and an all-silicon anode. The initial rounds of tests show that the new battery is safe, long lasting, and energy dense. —Darren H. Tan, lead author.

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Li-ion San Diego Lithium Ion Batteries 284

Green Car Congress

JANUARY 24, 2014

EnerG2, a company manufacturing advanced nano-structured materials for next-generation energy storage, has introduced a carbon and silicon composite to boost lithium-ion battery capacity and power performance. The company says that it is working both with battery customers and silicon manufacturers. Earlier post.).

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Li-ion Carbon Lithium Ion Energy Storage 236

Green Car Congress

OCTOBER 8, 2018

Saratoga Energy has won a National Science Foundation grant to scale up its breakthrough process for generating low-cost, top quality carbon nanotubes from carbon dioxide for use in making high-performance Li-ion batteries, such as those used in electric vehicles, grid storage, and military and aerospace applications.

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Grant Carbon Energy Li-ion 191

Green Car Congress

SEPTEMBER 25, 2013

Researchers at Arizona State University have shown that paper-folding concepts can be applied to Li-ion batteries in order to realize a device with higher areal energy densities. Areal discharge capacities for Miura-folded versus unfolded cells. Credit: ACS, Cheng et al.Click to enlarge. —Cheng et al.

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Li-ion Concept Energy Batteries 331

Green Car Congress

JANUARY 1, 2014

Researchers from Shanghai University have synthesized Fe 2 O 3 -graphene sheet-on-sheet sandwich-like nanocomposites that, when used as an anode for Li-ion battery, shows a high reversible capacity of 662.4 These metal oxides electrodes have shown much higher Li-ion storage capacities than that of commercial graphite anodes.

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Li-ion Batteries Battery Carbon 240

Green Car Congress

MAY 14, 2014

Start-up Power Japan Plus announced plans to commercialize a dual-carbon battery technology, which it calls the Ryden dual carbon battery. Both electrodes are carbon (e.g., During discharge, both anions and lithium ions are released back into the electrolyte. Negative electrode: Li + + nC+e ?

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Carbon Commercial Batteries Battery 373

Green Car Congress

AUGUST 10, 2022

However, silicon nanomaterials come with certain demerits, such as a large demand and supply gap, difficult and expensive synthesis process, and, most important, a threat of fast battery dry-up. Over the years scientists have developed various advanced silicon-based negative electrodes or anode materials to overcome these problems.

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Lithium Ion Li-ion Batteries Battery 243

Green Car Congress

AUGUST 21, 2015

A team led by Dr. Stuart Licht at The George Washington University in Washington, DC has developed a low-cost, high-yield and scalable process for the electrolytic conversion of atmospheric CO 2 dissolved in molten carbonates into carbon nanofibers (CNFs.) Atmospheric air is added to an electrolytic cell.

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Low Cost Carbon Li-ion Carbon Fiber 150

Green Car Congress

JULY 8, 2013

The working concept of I3 – /I – redox reaction in the aqueous Li-I 2 battery. A team from Japan’s RIKEN, led by Hye Ryung Byon, has developed a lithium-iodine (Li-I 2 ) battery system with a significantly higher energy density than conventional lithium-ion batteries. Zhao et al.

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Li-ion Ni-Li Energy Batteries 255

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. Ford suggested the dual battery system might go into production soon. Lead-acid (left) and Li-ion battery (right).

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Li-ion Lead Acid Ford Batteries 231

Green Car Congress

JUNE 15, 2015

Researchers led by a team from Griffith University in Australia have developed a multifunctional polymer binder that not only maintains the outstanding binding capabilities of sodium alginate but also enhances the mechanical integrity and lithium-ion diffusion coefficient in a LiFePO 4 (LFP) electrode during the operation of the batteries.

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Li-ion Polymer Lithium Ion Sodium 150

Green Car Congress

OCTOBER 16, 2019

The batteries use a Li 6.4 The current state-of-the-art lithium-ion batteries (LIBs) have an energy density of less than 300 Wh kg -1 and 750 Wh L -1. Since the initial use of S and Se as electrodes in batteries, investigations of Li-S and Li-Se batteries have attracted substantial attention.

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Li-ion Batteries Battery Low Cost 220

Green Car Congress

DECEMBER 13, 2016

John Goodenough, known around the world for his pioneering work that led to the invention of the rechargeable lithium-ion battery, have devised a new strategy for a safe, low-cost, all-solid-state rechargeable sodium or lithium battery cell that has the required energy density and cycle life for a battery that powers an all-electric road vehicle.

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Low Cost Recharge Austin Li-ion 150

Green Car Congress

JULY 23, 2015

Nanoporous silicon is considered an attractive next-generation anode material in lithium-ion batteries due to its much higher theoretical capacity and lower operating voltage than the commonly used graphitic carbon materials. It does not even change during the reduction to the final carbonized silicon network.

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Li-ion Batteries Battery Lithium Ion 150

Green Car Congress

FEBRUARY 8, 2011

The researchers are proposing a shift from carbon to much higher capacity silicon-based anodes; from cobalt-based to iron and/or manganese/nickel-based cathodes; and to use novel electrolyte salts. The research consortium includes universities and knowledge institutes; a SME battery producer and the car industry as end-users.

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Li-ion Low Cost F-150 Energy 199

Green Car Congress

JANUARY 7, 2015

A team from the University of Rome Sapienza has developed a rechargeable lithium-ion polymer battery based on the combination of a high capacity sulfur-carbon cathode, nanostructured Li x Sn-C anode and polysulfide-added PEO-based gel membrane. Moreover, the addition of a dissolved polysulfide (i.e.

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Li-ion Polymer Lithium Sulfur Energy 150

Green Car Congress

JUNE 19, 2014

The US Department of Energy (DOE) has six recently launched applied battery research (ABR) projects as part of its Vehicle Technologies portfolio. TIAX proposes that using a blended Si/hard carbon anode will allow the design of cells capable of delivering high energy during EV operation and high power during HEV mode of the battery.

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Li-ion PHEV Ni-Li Batteries 316

Green Car Congress

AUGUST 2, 2017

Researchers at Oak Ridge National Laboratory (ORNL) have discovered a way to achieve the promise of bronze-phase vanadium dioxide [VO 2 (B)] as an electrode material for Li-ion batteries. Thus, VO2(B) has been expected to exhibit both high capacity and rapid Li ion diffusion. Wh/g), LiFePO 4 (165 mAh/g at 3.5

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Li-ion Lithium Ion Energy Storage Connect 170

Green Car Congress

MARCH 13, 2015

Researchers at the Beijing Institute of Technology have found a way to process biomass-derived natural silk to create carbon-based nanosheets that could potentially be used in Li-ion batteries and other energy storage devices. Electrochemical performances of HPNC-NS as a Li-ion battery anode.

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Li-ion Energy Storage Energy Batteries 150

Green Car Congress

DECEMBER 11, 2016

Historical prices and future cost predictions for lithium-ion batteries. Estimates include both cell- and pack-level cost assessments, which is reflected in the significant variability in the cost estimates. Electric vehicle sales and pack sizes also impact the most commonly used lithium-ion chemistries.

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Li-ion Lithium Ion Price Batteries 150

Green Car Congress

FEBRUARY 13, 2015

Researchers at A*STAR in Singapore are proposing the use of monolayer phosphorene—a 2D material isolated from black phosphorus—as an anode material for high charging voltage, high rate capability Li-ion batteries. —Li et al. The average voltage of the Li intercalation is estimated to be 2.9

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Li-ion Batteries Battery 2014 150

Green Car Congress

JULY 2, 2011

In a paper published in the ACS journal Nano Letters , they suggest that this material represents a promising cathode material for rechargeable Li-ion batteries with high energy density. Sulfur also possesses other advantages such as low cost and environmental benignity. Earlier post.) Nevertheless, Wang et al.

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Li-ion Energy Batteries Battery 239

Green Car Congress

NOVEMBER 2, 2012

Researchers at Rice University have created an inexpensive silicon-based anode material for Li-ion batteries consisting of macroporous silicon particulates (MPSPs) created by crushing porous silicon films they had earlier developed. Thakur et al. Click to enlarge. Earlier post.) —Lisa Biswal.

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Li-ion Universal Batteries Battery 240

Green Car Congress

APRIL 30, 2022

In 2021, Next Generation Manufacturing Canada (NGen) launched a call for proposals to support R&D projects for zero-emission vehicle (ZEV) manufacturing, systems, components, and batteries in Canada. The selected projects are: Advanced Manufacturing Process Innovations – Flex-Ion Battery Innovation Center. Lead: Ventra Group Co.;

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Canada Li-ion Emissions Vehicles 304

Green Car Congress

JUNE 6, 2010

GMP40 (60:40 weight ratio of mixed mesophase pitch carbon and phenolic resin) produced the best results. However, carbon remains the predominant commercial anode material solution at this point. Some studies have demonstrated that carbon coating of graphite improves the anode performance in LIBs. Credit: ACS, Lin et al.

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Li-ion Carbon Lithium Ion Charging 186

Green Car Congress

AUGUST 23, 2012

For comparison, activated carbon control has also been plotted. Although activated carbon lies well within the Li-ion battery region for lower C rates (1 C), its performance drastically reduces at higher power rates. largely governed by Li + diffusivity and electron conductivity. Click to enlarge.

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Li-ion Lithium Ion Carbon Charging 240