Green Car Congress

MARCH 9, 2018

Researchers at Hasselt University in Belgium are proposing a new class of solid composite electrolytes (SCEs) for Li-ion batteries: deep eutectic solvent (DES)–silica composites. Structural schematic of a Li/LFP cell with the ETG as electrolyte. V versus Li, and unable to stop the growth of lithium dendrites.

Li-ion 218

Li-ion Belgium Batteries Battery 218

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.

Li-ion 199

Li-ion Ni-Li Batteries Battery 199

Green Car Congress

APRIL 11, 2021

Scientists from Tohoku University have developed a new fluorine-free calcium (Ca) electrolyte based on a hydrogen (monocarborane) cluster that could potentially realize rechargeable Ca batteries. High-energy-density and low-cost calcium (Ca) batteries have been proposed as ‘beyond-Li-ion’ electrochemical energy storage devices.

Recharge 418

Recharge Li-ion Batteries Battery 418

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.

Li-ion 150

Li-ion Waste Lithium Ion Batteries 150

Green Car Congress

JULY 24, 2020

Researchers from the University of California San Diego (UCSD) and the University of Texas at Austin, with colleagues at the US Army Research Laboratory and Lawrence Berkeley National Laboratory, have developed a thick cobalt-free high voltage spinel (LiNi 0.5 —Li et al. (a) —Li et al. Earlier post.).

Ni-Li 307

Ni-Li Li-ion San Diego Energy Storage 307

Green Car Congress

DECEMBER 18, 2014

A team led by researchers at Chungnam National University (S. 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 Pham et al.

Li-ion 329

Li-ion Ni-Li Energy Lithium Ion 329

Green Car Congress

NOVEMBER 7, 2014

The jury of representatives from BASF, Volkswagen and from academia selected Dr. Wood for her outstanding research results in the area of lithium-ion batteries. She and her colleagues have implemented techniques to quantify lithiation dynamics and tortuosity in lithium-ion batteries and their effects on cell performance and safety.

Li-ion 244

Li-ion Lithium Ion Batteries Battery 244

Green Car Congress

SEPTEMBER 5, 2019

This expanded portfolio has the dual aims of improving current generation lithium ion batteries as well as longer horizon materials discovery and optimisation projects to support the commercialisation of next-generation batteries. The project’s Principal Investigator is Professor Patrick Grant of the University of Oxford.

Energy Storage 223

Energy Storage Li-ion Lithium Ion Energy 223

Green Car Congress

APRIL 13, 2020

Researchers at Toyohashi University of Technology in Japan have developed an active sulfur material and carbon nanofiber (S-CNF) composite material for all-solid-state Li-sulfur batteries using a low-cost and straightforward liquid phase process. Copyright Toyohashi University Of Technology. —Phuc et al.

Carbon 243

Carbon Lithium Sulfur Li-ion Batteries 243

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.

Li-ion 186

Li-ion Emissions Lithium Sulfur Lithium Ion 186

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).

Parts 459

Parts Batteries Battery Lithium Ion 459

Green Car Congress

JANUARY 21, 2021

Critical materials are used in many products important to the US economy and energy technologies, such as rare-earth elements used to manufacture high-strength magnets for offshore wind-turbine generators and lithium and cobalt in lithium-ion batteries for electric vehicles. Partners: Harper International, Phillips66.

Li-ion 321

Li-ion Wyoming Lithium Ion Corporation 321

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.

Li-ion 150

Li-ion Polymer Lithium Ion Sodium 150

Green Car Congress

APRIL 30, 2022

The selected projects are: Advanced Manufacturing Process Innovations – Flex-Ion Battery Innovation Center. 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. Lead: Ventra Group Co.;

Canada 304

Canada Li-ion Emissions Vehicles 304

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

Li-ion 150

Li-ion Lithium Ion Batteries Battery 150

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. Isaacson, Michael S.

Li-ion 240

Li-ion Universal Batteries Battery 240

Green Car Congress

MAY 27, 2013

Researchers at Nankai University in China have assembled spinel-type LiNi 0.5 O 4 (LNMO) porous nanorods with nanoparticles that function as high-rate and long-life cathode materials for rechargeable lithium-ion batteries. O 4 (LNMO), which possesses fast three-dimensional Li + diffusion channels and high operational voltage (?4.7

Li-ion 186

Li-ion Lithium Ion Batteries Battery 186

Green Car Congress

DECEMBER 11, 2016

Even in the most optimistic scenario, when the cells are the largest (20720), electrodes the thickest (100 mm), and the production volume is 8 GWh per year, the cost per kWh for LMO cells is well above the DOE target. Historical prices and future cost predictions for lithium-ion batteries. —Ciez and Whitacre.

Li-ion 150

Li-ion Lithium Ion Price Batteries 150

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. During battery charging, positive Lithium ions move from the cathode to the anode, and a stable 2D interface is formed. (3)

Li-ion 284

Li-ion San Diego Lithium Ion Batteries 284

Green Car Congress

JUNE 4, 2014

For the near term, they have been working on a dual-battery combining a lithium-ion battery with a 12-volt lead-acid battery that could enable regenerative braking technology in non-hybrid vehicles for greater fuel savings. The research advances lithium-ion battery technology currently available on Ford’s electrified vehicles.

Li-ion 231

Li-ion Lead Acid Ford Batteries 231

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. CAEBAT has provided us with world-class capabilities to model the performance and safety of Lithium-ion batteries.

Li-ion 230

Li-ion Lithium Ion Batteries Battery 230

Green Car Congress

JANUARY 28, 2016

A team from Stanford University and the Department of Energy’s SLAC National Accelerator Laboratory has developed a new practical, high-energy-capacity lithium-ion battery anode out of silicon by encapsulating Si microparticles (∼1–3 µm) using conformally synthesized cages of multilayered graphene. —Li et al.

Li-ion 150

Li-ion Lithium Ion Energy Batteries 150

Green Car Congress

APRIL 6, 2010

Keio University spin-out ELIIY Power Co., has begun operations at its new Li-ion battery manufacturing plant in Kawasaki. Built at a cost of roughly 5 billion yen, the plant can make lithium ion battery cells with a charge capacity of 150 watt-hours at a rate of 200,000 cells a year. Earlier post.).

Li-ion 186

Li-ion Lithium Ion Batteries Battery 186

Green Car Congress

JUNE 14, 2019

Natron Energy, a developer of new battery cell technology based on Prussian Blue analogue electrodes and a sodium-ion electrolyte, has ( earlier post ), has been awarded a $3-million grant by the California Energy Commission (CEC) for “Advanced Energy Storage for Electric Vehicle Charging Support.”

Energy Storage 191

Energy Storage Energy California 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. These initial results showed that the Li-ion batteries can still exhibit good electrochemical performance even after multiple folds, they said.

Li-ion 331

Li-ion Concept Energy Batteries 331

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. Even after 4,000 cycles and at a rate of 10C, the anode achieved a specific capacity of 420 mAhg -1.

Li-ion 150

Li-ion Batteries Battery Lithium Ion 150

Green Car Congress

JULY 17, 2020

Area of Interest (AOI) 01a: Lithium Ion Batteries using Silicon-based Anodes-Research. The Research Foundation for The SUNY Stony Brook University. University of Delaware. University of Maryland. Rational Electrolyte Design for Li-ion Batteries with Micro-Sized Silicon Anodes. Marquette University.

Lithium Ion 236

Lithium Ion Vehicles Li-ion Universal 236

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.

Li-ion 150

Li-ion Polymer Lithium Sulfur Energy 150

Green Car Congress

SEPTEMBER 3, 2021

Echion Technologies, a spin-off from the University of Cambridge developing niobium oxide-based materials for anodes, has closed a £10-million (US$13.8 million) Series A funding round. Twice the volumetric capacity of LTO anodes. Safe operating voltage. 1000’s of cycles demonstrated.

Li-ion 259

Li-ion Lithium Ion Universal Batteries 259

Green Car Congress

JUNE 4, 2013

A team at Stanford University has developed stable silicon Li-ion battery anodes by incorporating a conducting polymer hydrogel into the Si-based material. V versus Li/Li + ), (3) the natural abundance of elemental Si, and (4) its safety and environmental benignity. Click to enlarge. —Yi Cui. —Wu et al.

Li-ion 236

Li-ion Manufacturer Polymer Deep Cycle 236

Green Car Congress

SEPTEMBER 16, 2016

As part of its new IONICS (Integration and Optimization of Novel Ion Conducting Solids) program awards ( earlier post ), the US Department of Energy’s Advanced Research Projects Agency-Energy (ARPA-E) awarded $3.5 million in funding to a team that includes 24M, Sepion Technologies , Berkeley Lab, and Carnegie Mellon University.

Li-ion 150

Li-ion Lithium Ion Energy Polymer 150

Green Car Congress

DECEMBER 13, 2016

Researchers at the University of Texas at Austin, including Prof. As reported in their paper in the RSC journal Energy & Environmental Science , the cells use a solid glass electrolyte having a Li + or Na + conductivity σ i > 10 -2 S cm -1 at 25°C with a motional enthalpy ΔH m ≈ 0.06 Click to enlarge.

Low Cost 150

Low Cost Recharge Austin Li-ion 150

Green Car Congress

AUGUST 4, 2015

3M and LG Chem have entered into a patent license agreement to further expand the use of nickel manganese cobalt oxide (NMC) cathode materials in lithium-ion batteries. 3M’s battery laboratory collaborated with Professor Jeff Dahn and students at Dalhousie University on the NMC technology. Earlier post.) Earlier post.)

Li-ion 150

Li-ion Batteries Battery Taiwan 150

Green Car Congress

MAY 2, 2011

A team from Nanyang Technological University (China) has developed a scalable self-assembly strategy to create bio-inspired honeycomb-like hierarchical structures composed of functionalized graphene sheets to work as anodes in lithium-ion batteries. Credit: ACS, Yin et al. Click to enlarge. Credit: ACS, Yin et al.

Li-ion 210

Li-ion Lithium Ion Batteries Battery 210

Green Car Congress

OCTOBER 16, 2019

The batteries use a Li 6.4 LLZTO) ceramic tube as electrolyte and work at temperatures higher than the melting point of lithium. 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. La 3 Zr 1.4

Li-ion 220

Li-ion Batteries Battery Low Cost 220

Green Car Congress

FEBRUARY 2, 2015

A team from University of Science and Technology of China and Max Planck Institute in Germany has synthesized 3D V 6 O 13 nanotextiles from interconnected 1D nanogrooves with diameter of 20–50 nm. Energy density comparison of the 3D nanotextile electrode and conventional LiMn 2 O 4 , LiCoO 2 , LiFePO 4 , and LiNi 0.5 O 4 electrodes.

Li-ion 150

Li-ion Energy Lithium Ion Building 150

Green Car Congress

AUGUST 16, 2017

University of Sydney team advances rechargeable zinc-air batteries with bimetallic oxide–graphene hybrid electrocatalyst. Cheaper to produce than lithium-ion batteries, they can also store more energy (theoretically five times more than that of lithium-ion batteries), are much safer, and are more environmentally friendly.

Zinc Air 150

Zinc Air Recharge Universal Ni-Li 150