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

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 Earlier post.)

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Li-ion Batteries Battery 2014 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.

Li-ion 210

Li-ion Lithium Ion Batteries Battery 210

Green Car Congress

APRIL 13, 2015

A team of researchers in South Korea and Italy has demonstrated a highly reliable lithium–sulfur battery showing cycle performance comparable to that of commercially available lithium-ion batteries while offering more than double the energy density. The cathode consists of an activated carbon?sulfur Credit: ACS, Lee et al. 1300 mAh g

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Li-ion Lithium Sulfur Batteries Battery 150

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?

Carbon 240

Carbon Li-ion Batteries Battery 240

Green Car Congress

AUGUST 5, 2015

A team of researchers at MIT and Tsinghua University has developed a high-rate, high-capacity and long-lived anode for Li-ion batteries comprising a yolk-shell nanocomposite of aluminum core (30 nm in diameter) and TiO 2 shell (~3 nm in thickness), with a tunable interspace (Al@TiO 2 , or ATO). —Li et al.

Li-ion 150

Li-ion MIT Batteries Battery 150

Green Car Congress

NOVEMBER 25, 2012

The project aims at demonstrating power supply stabilization in the region by introducing cargo container-type large capacity energy storage system using a lithium-ion rechargeable battery, which has a maximum power output capacity of 2MW. Each battery container houses more than 2,000 units of lithium-ion rechargeable batteries.

Energy Storage 271

Energy Storage Power Grid Mitsubishi Li-ion 271

Green Car Congress

DECEMBER 10, 2009

The aim of the project was to develop an alternative Li-ion cell chemistry that could be integrated within an HEV using a bespoke battery management system. QinetiQ has also been working on lithium-ion/iron sulphide cells for a number of years. Scattergood (2004) Lithium-ion/iron sulphide rechargeable batteries.

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Li-ion Lithium Ion PHEV 2004 218

Green Car Congress

MARCH 1, 2017

The cells use a solid glass electrolyte having a Li + or Na + conductivity >10 -2 S cm -1 at 25 ˚C with a motional enthalpy ≈ 0.06 lithium, sodium or potassium) on a copper–carbon cathode current collector at a voltage of more than 3.0 eV, which promises to offer acceptable operation at lower temperatures.

Li-ion 150

Li-ion Sodium Austin Batteries 150

Green Car Congress

APRIL 18, 2017

The coating layer can generate better control of the lithium ion flow and suppress the lithium dendrite growth and therefore form a uniform and stable solid electrolyte interphase. High capacity lithium (Li) ion batteries are highly desirable now for applications in consumer electronics, electrical vehicles, and grid storage.

Li-ion 150

Li-ion Lithium Ion Recharge Re-Charge 150

Green Car Congress

JUNE 16, 2014

A123 Systems LLC, a developer and manufacturer of advanced lithium-ion batteries and systems, has acquired Leyden Energy’s intellectual property in battery materials covering lithium titanate (LTO) and non-flammable electrolyte (Li-imide) developments for an undisclosed amount.

Lithium Titanate 319

Lithium Titanate Li-ion Energy Hybrid 319

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. Novel Biological Conversion of Hydrogen and Carbon Dioxide Directly into Biodiesel. Earlier post.) Electrofuels. per gallon.

Carbon 249

Carbon Batteries Battery Li-ion 249

Green Car Congress

MAY 29, 2017

has successfully developed a high-voltage cathode material for lithium iron phosphate rechargeable batteries. —the highest among those of all Fe-based phosphate materials and pyrophosphate materials reported so far, including LiFePO 4 , Li 3 Fe 2 (PO 4 ) 3 , LiFeP 2 O 7 , Li 2 FeP 2 O 7 and LiFe 1.5 Fe 5.33 (P 2 O 7 ) 4 ).

Li-ion 186

Li-ion Lithium Ion Recharge Charging 186

Green Car Congress

MAY 2, 2017

Li-sulfur batteries are looked to as a likely next-generation higher energy density energy storage system due to the high theoretical capacity, low cost and high earth abundance of sulfur. In addition, when a Li-S cell operates under a lean electrolyte condition, its charge/discharge behavior, cell failure model, etc.

Li-ion 150

Li-ion Lithium Sulfur Polymer Energy Storage 150

Green Car Congress

MARCH 25, 2016

A team from the Shenzhen Institutes of Advanced Technology (SIAT) of the Chinese Academy of Sciences has developed a novel, environmentally friendly low-cost battery. Compared with conventional LIBs, this battery (AGDIB) shows an advantage in production cost (~ 50% lower), specific density (~1.3-2.0

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Chinese Li-ion Batteries Battery 150

Green Car Congress

OCTOBER 9, 2014

The following Stanford faculty members received funding for advanced research on photovoltaics, battery technologies and new catalysts for sustainable fuels: Self-healing polymers for high energy density lithium-ion batteries. Photo-electrochemically rechargeable zinc-air batteries. efficiency, low-cost silicon solar cells.

Renewable 225

Renewable Solar Zinc Air Energy 225

Green Car Congress

MAY 15, 2015

E-bike powered by Faradion prototype Na-ion battery pack. For the proof-of-concept, the cells were manufactured to be larger than necessary to avoid unnecessary costs and lengthy manufacturing processes at this early stage. Sodium-ion intercalation batteries—i.e., Faradion Na-ion technology. Click to enlarge.

Sodium 150

Sodium Concept Li-ion Lithium Ion 150

Green Car Congress

MAY 28, 2015

Developing Robust all-Solid-State Li Battery with a Ceramic Electrolyte and Interfacially Engineered Lithium Metal Anode A next generation of a low cost and high energy density advanced solid state rechargeable lithium battery will be developed through the proposed project for use in the next generation of PHEV and EV rechargeable batteries.

Li-ion 150

Li-ion Battery Powered Engine Lithium Ion 150

Green Car Congress

APRIL 1, 2011

Example of a lithium-water rechargeable battery. Researchers at the University of Texas, including Dr. John Goodenough, are proposing a strategy for high-capacity next-generation alkali (lithium or sodium)-ion batteries using water-soluble redox couples as the cathode. A typical Li-air battery discharges at 2.5-2.7

Sodium 218

Sodium Water Li-ion Texas 218

Green Car Congress

MAY 25, 2017

Polysulfide-Blocking Polymer Membrane Separators for Rechargeable Lithium-Sulfur Batteries The advanced energy economy will be a dominant market force in the 21st century, one driven by US demand but asymmetrically low domestic supply without immediate action. NanoSonic, Inc. Tetramer Technologies, LLC.

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Grant Li-ion Waste Lithium Sulfur 150

Green Car Congress

NOVEMBER 2, 2011

This approach enabled them to obtain a uniform and thin (around tens of nanometers) sulfur coating on graphene oxide sheets and address some of the challenges retarding the commercialization of Li/S batteries. However, there are a number of challenges in Li/S batteries, Ji et al. Earlier post.). —Ji et al.

Lithium Sulfur 186

Lithium Sulfur Li-ion Batteries Battery 186

Green Car Congress

APRIL 11, 2016

Researchers at Kansas State University have developed a new high-performance Li-ion battery anode material combining silicon oxycarbide (SiOC) glass and graphene. low capacity per volume, poor cycling efficiency and chemical-mechanical instability. The self-standing (i.e., David et al. Click to enlarge.

Li-ion 150

Li-ion Lithium Ion Carbon Kansas 150

Green Car Congress

DECEMBER 29, 2013

Zinc-air technology, although offering high energy density—about twice the gravimetric density (Wh/kg) and three times the volumetric density (Wh/L) of Li-ion technology—has been generally limited to low-power, non-rechargeable applications.

Zinc Air 231

Zinc Air Fuel Power Powered 231

Green Car Congress

OCTOBER 26, 2015

Since vehicle cost and range largely control market penetration, we will first provide a rough estimate of the cost/range projected for BEVs and FCEVs. 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. Click to enlarge.

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Lithium Sulfur Electric Vehicles Li-ion Batteries 150

Green Car Congress

AUGUST 1, 2010

BATT is funded by the Department of Energy’s Office of Vehicle Technologies and is managed by the Lawrence Berkeley National Laboratory as part of its Carbon Cycle 2.0 The selected projects are: BATT Li-ion Anode Project Awards. Metal-Based High-Capacity Li-Ion Anodes. initiative. The total requested funds are $8.54

Li-ion 186

Li-ion Batteries Battery Lithium Ion 186

Green Car Congress

MAY 20, 2016

Researchers from Hanyang University in Korea and the BMW Group have developed a new fully operational, practical Li-ion rechargeable battery combining high energy density with excellent cycle life. g cm -3 ; a two-sloped full concentration gradient (TSFCG) Li[Ni 0.85 O 2 , Li[Ni 0.85 O 2 (NCM) and Li[Ni 0.8

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Li-ion Ni-Li Carbon BMW 210

Green Car Congress

FEBRUARY 2, 2013

Advanced Electrolytes for Next-Generation Lithium Ion Chemistries. Further, alloying or coating pathways towards low-cost, effective passive films, have not been sufficiently explored in a sound and scientific way. Carbon Fiber Polymer Composite. Recharge Rate. Lubricant Formulations to Enhance Fuel Efficiency.

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Li-ion Fuel Vehicles Lithium Ion 240

Green Car Congress

OCTOBER 15, 2020

The solicitation was designed as a call for early-stage clean energy innovations that fall within five defined technology areas: energy efficiency; energy storage; AI/machine learning; advanced power electronics/power conditioning; and zero- and negative-carbon emission generation. rechargeable battery?technology?that is developing a?rechargeable

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Clean Cleaning Energy Solar 371

Green Car Congress

DECEMBER 29, 2014

Researchers from Nanyang Technical University (NTU) in Singapore have shown high-capacity, high-rate, and durable lithium- and sodium-ion battery (LIB and NIB) performance using single-crystalline long-range-ordered bilayered VO 2 nanoarray electrodes. VO 2 nanobelts are beneficial to fast ion diffusion.

Li-ion 186

Li-ion Ni-Li Sodium Batteries 186

Green Car Congress

JUNE 7, 2011

The resulting improved electrical capacity and recharging lifetime of the nanowires. low-cost Na-ion battery system for upcoming power and energy. Lithium-ion rechargeable batteries perform well, but are too expensive for widespread use on the grid. Sodium-ion batteries have been discussed in the literature.

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Sodium Recharge Li-ion Batteries 218

Green Car Congress

OCTOBER 26, 2012

Tin (Sn) shows promise as a robust electrode material for rechargeable sodium-ion (Na-ion) batteries, according to a new study by a team from the University of Pittsburgh and Sandia National Laboratory. Rechargeable Na-ion batteries work on the same basic principle as Li-ion batteries—i.e.,

Sodium 210

Sodium Li-ion Ni-Li Batteries 210

Green Car Congress

JUNE 25, 2012

In April, Axion Power International Inc received an order from Norfolk Southern Corp (NS) for PbC lead-carbon batteries for use in an all-battery-powered switcher locomotive. PbC batteries are multi-celled asymmetrically supercapacitive lead-acid-carbon hybrid batteries. The battery-electric NS-999, “under the long hood”. Source: NS.

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Lead Acid Hybrid Batteries Battery 225

Tony Karrer Delicious EVdriven

APRIL 16, 2009

MidAmericans David Sokol, BYDs Wang, and company advisor Li Lu flew with Sokol from Detroit to Omaha so that Wang could meet Buffett in person. One way or another, Sokol says, energy companies will need to produce more energy while emitting less carbon dioxide. The E6 will hit the Chinese market later this year.

BYD 62

BYD 2009 Companies Electric Cars 62

Green Car Congress

JUNE 23, 2015

Electrochemical/photoelectrochemical water splitting is widely considered to be a critical step for efficient renewable energy production, storage and usage such as sustainable hydrogen production, rechargeable metal-air batteries and fuel cells. V to reach 10 mA cm −2 current (for integrated solar water splitting). —Wang et al.

Water 150

Water Hydrogen Production Li-ion 150

Tony Karrer Delicious EVdriven

APRIL 16, 2009

There are companies that are reinventing the lead-acid battery to make it more competitive with lithium-ion and nickel metal hydride in terms of storage capacity versus weight, durability, and cold weather performance. In most conversions cost is about the same because of needless weight.

Oregon 58

Oregon Green Electric Cars Lead Acid 58