Green Car Congress

JANUARY 10, 2014

Schematic of hybrid anode placed in a Li–S battery. Researchers at the Department of Energy’s Pacific Northwest National Laboratory (PNNL) have designed a lithium–sulfur battery using electrically connected graphite and lithium metal as a hybrid anode to control undesirable surface reactions on lithium.

Lithium Sulfur 225

Lithium Sulfur Li-ion Hybrid Batteries 225

Green Car Congress

NOVEMBER 12, 2015

nm, average) of iron pyrite (FeS 2 ) nanoparticles are advantageous to sustain reversible conversion reactions in sodium ion and lithium ion batteries. FeS 2 is particularly attractive for energy storage technology due to its earth abundance, low toxicity, and low raw material cost. …

Li-ion 150

Li-ion Sodium Lithium Sulfur Batteries 150

Green Car Congress

SEPTEMBER 18, 2016

UK-based materials company Ilika, also a developer of solid-state batteries, is taking part in a three-year project to develop protected anodes for lithium sulfur batteries, led by Johnson Matthey Plc and supported by Innovate UK and the Engineering and Physical Sciences Research Council (EPSRC). Click to enlarge.

Lithium Sulfur 150

Lithium Sulfur Batteries Battery Lithium Ion 150

Green Car Congress

OCTOBER 26, 2015

Gasteiger, Chair of Technical Electrochemistry, Technische Universität München; and Dr. Jens-Peter Suchsland, SolviCore GmbH, delve into the technological barriers for all-electric vehicles—battery-electric or PEM fuel cell vehicles. kWh name-plate /kg battery-system are not yet on the horizon. wind and solar).

Lithium Sulfur 150

Lithium Sulfur Electric Vehicles Li-ion Batteries 150

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. A paper on their work is published in the ACS journal Nano Letters. Credit: ACS, Chen et al. 7b00417.

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Li-ion Lithium Sulfur Polymer Energy Storage 150

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. Resources.

Li-ion 150

Li-ion Polymer Lithium Sulfur Energy 150

Green Car Congress

MAY 28, 2015

The US Department of Energy (DOE) has selected 162 projects to receive about $26.6 Of these, 16 are vehicle-related, encompassing projects developing batteries, power electronics and improved combustion engine technology including on-board reformers, and two are specifically hydrogen fuel cell-related. Earlier post.) 149,871.44.

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Li-ion Battery Powered Engine Lithium Ion 150

Green Car Congress

DECEMBER 31, 2012

Researchers at Cornell University are proposing a new scheme for cathodes for lithium-sulfide batteries ( earlier post ) to prevent lithium polysulfide dissolution and shuttling during electrochemical cycling. They evaluated the synthesized material as cathode materials in a half-cell lithium battery. Earlier post.)

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Li-ion Lithium Ion Batteries Battery 257

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

FEBRUARY 11, 2012

Vorbeck Materials , a startup company based in Jessup, Maryland, is using a Pacific Northwest National Laboratory (PNNL)-developed method for developing graphene for better lithium air and lithium sulfur batteries.

Hydrogen 279

Hydrogen Engine Energy Batteries 279

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. Better Batteries - Batteries for Electrical Energy Storage in Transportation (BEEST).

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Carbon Batteries Battery Li-ion 249

Green Car Congress

AUGUST 11, 2016

High cycling stability in the Li–S batteries, for practical applications, has been achieved with up to 3 mg·cm –2 sulfur loading. They also achieved Li–S electrodes with up to a 85% sulfur ratio. (a) a) Schematic illustration of the porous ant-nest structure Li−S electrode (CNT-nest-S) fabrication procedure. (d)

Li-ion 150

Li-ion Lithium Sulfur Transportation Batteries 150

Green Car Congress

MAY 16, 2016

Researchers from Hunan University and Changsha University in China have designed 3D hierarchical porous nitrogen-doped aligned carbon nanotubes (HPNACNTs) with well-directed 1D conductive electron paths as scaffold to load sulfur for use as a high-performance cathode in Li-S batteries. 2016.05.024.

Carbon 150

Carbon Li-ion Lithium Sulfur Transportation 150

Green Car Congress

AUGUST 10, 2011

This project will develop a new process that enables low-cost, domestic manufacturing of magnesium. This project will develop a novel low cost route to carbon fiber using a lignin/PAN hybrid precursor and carbon fiber conversion technologies leading to high performance, low-cost carbon fiber. Amprius, Inc.

Carbon Fiber 268

Carbon Fiber Lithium Ion Li-ion Vehicles 268

Green Car Congress

NOVEMBER 28, 2012

ARPA-E’s first funding opportunity, “OPEN 2009,” was issued three years ago and was similarly an open call for transformational energy technology solutions. sunlight through low-cost, plastic light-guiding sheets and then. expensive facilities that use significant amounts of energy. Turbo-POx For Ultra Low-Cost Gasoline.

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2012 Energy Lithium Sulfur Conversion 240