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Eisbrenner Public Relations l 301 W. 4th Street, Suite 301 l Royal Oak, MI 48067
O 248.554-3500 l D 248.554-3526 l E asherbow @ eisbrenner.com
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Media Contact:
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Eisbrenner Public Relations
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The Battery Show sees success in metro Detroit, plans 2012 expansion

Advanced battery expo and conference coming next Nov. 13-15

Novi, Mich., November 22, 2011 – On the heels of a successful second year, The Battery Show announced today that it will return to metro Detroit Nov. 13-15, 2012, with double the exhibition hall space, and a brand new exhibition and conference on electric vehicle charging and infrastructure.

This year’s show, held October 25-27 at the Suburban Collection Showplace in Novi, Mich., gathered more than 2,700 industry leaders and stakeholders for a 170-booth exhibition and two-track conference on battery business models and advanced battery technologies. Attendance almost doubled last year’s inaugural show in San Jose, Calif. Given its success and the excitement surrounding the advanced battery industry, The Battery Show’s producer is planning for a much larger show next year. It also will launch the Charging Infrastructure Expo, a free-to-attend exhibition that will bring together utility companies, charging infrastructure suppliers, EV manufacturers and senior representatives from current and future charging station operators.

The Battery Show 2012 exhibition will again showcase the latest battery technologies for electric vehicles, utility storage, mobile power, personal electronics and healthcare applications, but will increase showroom space to 129,000 sq. feet, accommodating up to twice the number of exhibitors.  

“The success of the 2011 show proved that the battery industry is booming,” said Adam Moore, exhibition director. “Automotive OEM’s are demonstrating that the battery powered drivetrain is here for the long term; utility companies are touting that batteries are an effective solution for easing the natural intermittency of renewables; while portable device manufacturers are showcasing their ever-increasing power. Our exhibitors, delegates and visitors were amazed at the scale and value of the show; we see this as a reflection on the industry as a whole.” 

Given the burgeoning advanced battery industry and the show’s expansion plans, it’s producer anticipates a significant increase in attendance next year. Already, more than 60 companies have signed on to exhibit, including Samsung SDI, LG Chem, Johnson Controls, Dow Energy Materials and ICC Nexergy. Exhibitors gain unique access to current and potential clients, and in a rapidly evolving industry, face time can make or break a business.

“The  Battery Show was our most effective show all year, perhaps the best we’ve ever had,” said Laura Schacht, global marketing and strategic sales director, St. Louis, Mo.-based Bitrode, maker of battery formation and lab testing equipment. “The quality of the attendees, the professionalism of the exhibitors, and the overall program, including the top-notch industry experts, was exceptional.” 

For more information on The Battery Show, visit thebatteryshow.com. To secure 2012 sponsorships or booth space, email info@....

ABOUT THE BATTERY SHOW 
The Battery Show is North America’s largest free to attend exhibition for advanced batteries. The exhibition showcases the very latest battery technologies and solutions, ranging from electric vehicle applications to raw material suppliers. Its two-track business and technology conference examines battery market development and opportunities, including how technical advances are likely to impact performance, safety and cost.

Liquid Metal Battery Corporation Open House

LMBC World Headquarters

237 Putnam Ave

Cambridge, MA 02139
http://lmbcorporation.com

Host:

LMBC Team

Phone:

617-714-5723

When:

Monday, December 12 from 5:00 PM to 8:00 PM

Where:

LMBC World Headquarters237 Putnam Ave Cambridge, MA 02139

Dear LMBC Family and Friends,

Join us on December 12, between 5 and 8 pm, for an open house to celebrate the holiday season and meet the growing LMBC team.

Please RSVP so that we can provide appropriate food and beverage.

We look forward to welcoming you to the new LMBC World Headquarters!

Sincerely,

The LMBC Team
investors include Bill Gates and TOTAL

Gates-backed Liquid Metal Battery hires CEO

by Martin LaMonica November 15, 2011  
http://news.cnet.com/8301-11128_3-57324982-54/gates-backed-liquid-metal-battery-hires-ceo

This model of a prototype shows the makings of an all-liquid battery cell. The bottom red layer is the heavy liquid metal cathode, the yellow is the molten salt electrolyte, and the green above is the less dense anode. The container is surrounded by an insulator material.

(Credit: Martin LaMonica/CNET)

Liquid Metal Battery, a company formed to make cheap storage for wind and solar power, has hired its first CEO.

Phil Giudice, who was the third employee of demand-response company EnerNoc and the Massachusetts Department of Energy Resources Commissioner until earlier the year, announced his "new gig" on Twitter. One of his tasks as CEO is to raise more money to build up the company, he told The Boston Globe.

Liquid Metal Battery was spun out of the lab of Donald Sadoway, a professor of materials chemistry at the Massachusetts Institute of Technology. Funding for the company has come from France-based oil giant Total and software tycoon Bill Gates, who took an interest in the technology after watching Sadoway's lectures online. Sadoway's lab has also received funding from the Department of Energy's ARPA-E research program.

Liquid Metal Battery is taking a radically different approach from lithium ion or other conventional batteries in pursuit of a low-cost system for storing many hours of renewable energy.

The active components in the battery--the anode, the cathode, and electrolyte--are liquid metal alloys, an approach that promises to make the batteries durable for many years. To get to a liquid state, the metals will be held at high temperatures between 400 degrees and 700 degrees Celsius. Its first prototype system is about the size of four pizza boxes, is using abundant salts, and is expected to use metals such as antimony and magnesium. Rather than string thousands of small battery cells together, the company's storage systems will be much larger and able to reduce the number of cells by 50 to 100 times, according to Sadoway.

Using manufacturing techniques similar to aluminum smelting, the company's goal is to make the batteries cheap enough to be used with renewable-energy systems. Executives have said the goal is to get in the range of $250 per kilowatt-hour, which is substantially less than half the price of today's lithium ion batteries.

Martin LaMonica is a senior writer covering green tech and cutting-edge technologies. He joined CNET in 2002 to cover enterprise IT and Web development and was previously executive editor of IT publication InfoWorld.

Related stories

• Liquid Metal Battery snags funding from Gates firm
• Energy storage on grid heats up (photos)
• Grid storage gets updraft from auto batteries

http://www.advancedautobat.com/conferences/automotive-battery-conference-2012

AABC 2012

Orlando, Florida

February 6 -10, 2012

Keep pace with the technology and market development of advanced vehicles and the batteries that will power them! Advanced Automotive Batteries (AAB) hosts two conferences annually, AABC Europe and the International AABC. Join us to review the latest advances in battery technology and applications and learn how these will affect the market. Both the quality of the conference program and the networking opportunities at AABC are unrivaled in the advanced automotive battery industry!

AABC symposia, tutorials and workshops address the key issues affecting the technology and market of advanced vehicles and the batteries that will power them. AABC attracts professionals from the hybrid and electric vehicle world and the three tiers of the battery supply chain.

AABC 2012, February 6 – 10, 2012, in Orlando, Florida. AABC returns to Orlando in 2012, where 900 attendees and 95 exhibiting companies joined us in May 2010. With its outstanding agenda, exhibits and dynamic networking events, AABC 2012 is positioned to be the most significant EV-PHEV-HEV industry event of the year. Join us for fresh information on battery technologies and the advanced automotive battery market.

Advanced Automotive Batteries

Dr. Menahem Anderman, co-author of the 2000 California Air Resources Board Battery Report, founded Advanced Automotive Batteries to provide up-to-date technology and market assessments of the rapidly growing field of energy storage for advanced automotive applications. AAB, the key information source for the advanced automotive battery industry, offers conferences, industry reports and expert consulting.

For over a decade, the annual International Advanced Automotive Battery Conference (AABC) has attracted professionals from the hybrid and electric vehicle world and their battery system suppliers, to stimulate the sharing of experiences and opinions. Renowned as a global meeting place, AABC continues to ask, explore and answer the questions most relevant to the design and development of advanced vehicles and the batteries that will power them. To keep pace with the rapidly expanding market development of HEVs, EVs, and their batteries, AAB now hosts two conferences each year, an International AABC held in the U.S. and a European AABC held in Germany.

AAB’s most recent multi-client industry report, The 2011 EV-PHEV Opportunity Report, is an assessment of the technological and commercial challenges to electrifying vehicles, based on an in-depth analysis of advanced automotive battery technology. The Report includes forecasts for each significant automaker and battery producer, based on onsite interviews with all four tiers of the supply chain.

Dr. Anderman is well known in the industry as a battery expert, and unique among battery consultants for having both technical and business background. His clients over the last 11 years have ranged from Silicon Valley startups to some of the world's largest corporations.

The Vision

Reducing the harmful impact of vehicles on the environment is a vital task for the industrial world. With the introduction of advanced electric and hybrid vehicles, the automotive industry is now exploring cost-effective ways to reduce fuel consumption and emissions. Energy-storage technology is the key to the commercial success of these advanced vehicles.

The objective of the Advanced Automotive Batteries (AAB) is to make available to industry professionals around the world information that will help them focus their financial and human resources on the most technologically viable and economically affordable solutions to the future needs of automotive energy storage. AAB’s bi-annual conferences, industry reports and consulting services contribute to the development and mass commercialization of more eco-friendly vehicles, a cleaner environment and more responsible usage of our planet’s resources.

info @ advancedautobat.com
Tel. (530) 692-0140
Fax (530) 692-0142

Mailing Address:
Advanced Automotive Batteries
P.O. Box 1059
Oregon House, CA 95962

Shipping Address:
Advanced Automotive Batteries
9204 Citron Way
Oregon House, CA 95962

+++

For Obama's green-car revolution, fits and starts

December 7, 2011
Washington Post

The Obama administration has poured roughly $5 billion in taxpayer funds into the electric-car industry, offering incentives to manufacturers, their suppliers and even car buyers who might want to go green.

But analysts say the risk is rising that taxpayers in many cases will not see a return on their money soon, if ever. Instead, they warn that some federally subsidized companies could be forced to shut down in coming months.

For President Obama, who has made clean-technology investment a hallmark of his job creation efforts, troubles in the electric-car sector pose a potential new political problem after the collapse of solar-panel maker Solyndra, which recently defaulted on a half-billion-dollar federal loan after filing for bankruptcy. The administration has channeled an estimated $80 billion of the stimulus recovery effort into grants and loans to clean energy and energy efficiency programs, companies and research.

Obama predicted in 2008 that green cars would create thousands of new U.S. jobs as demand soared. But in recent months, production lines and sales expectations have been dramatically scaled back.

A123 Systems, a battery maker that received $380 million in government support, announced recently that declining orders had forced layoffs. Instead of up to 3,000 new Michigan jobs as Obama and the company had predicted, it now has 690 employees.

Battery maker EnerDel, recipient of a a $118 million federal grant, took a hit when its key customer, electric-car maker Think, declared bankruptcy this year. Johnson Controls, which received a $299 million stimulus grant, opted to build one factory instead of two because of lower-than-projected demand, a company official said, and that one is now operating at half capacity.

California electric-car maker Aptera announced it was shutting its doors because of problems raising capital. And General Motors — whose moderately priced Volt was supposed to drive Obama’s push for 1 million alternative vehicles by 2015 — revealed last week that it would fall roughly 38 percent shy of its goal of selling 10,000 Volts this year.

"Many in this industry have jumped the gun on how aggressive the growth of electric vehicles will be,” said Kevin C. See, an analyst at Lux Research.

Supporters of Obama’s green-car initiatives say that there are still industry bright spots and that this start-up sector will simply take longer to deliver results.

“Certainly, with electric-vehicle sales, we’re not on track to meet the president’s goal,” said Brendan Bell, clean-vehicle expert at the Union of Concerned Scientists. “But . . . these investments are good ones toward that goal.”

Alex Molinaroli, a Johnson Controls vice president, said the funds give U.S. factories the capacity to deliver when demand arrives and position them as industry players.

“Is it worth the premium?” Molinaroli said. “We’ll have to wait a long time to see if this was a good investment or not.”

Obama’s green-car goal

Obama started his alternative-vehicle push in the 2008 campaign, and his administration soon after put money behind the plan. Like Solyndra, several of the firms receiving support had investors who were also important Obama campaign donors.

Nissan, Tesla Motors and Fisker Automotive received $2.4 billion in loans to support building U.S. manufacturing plants for electric vehicles through an Energy Department program. In a stimulus push in August 2009, Obama announced $2.4 billion in more than 40 grants to car industry firms, much of it to advanced-battery manufacturers.

The president said the strategy would revive the country’s manufacturing base while nurturing a domestic green-car industry.

"If we want to reduce our dependence on oil, put Americans back to work and reassert our manufacturing sector as one of the greatest in the world, we must produce the advanced, efficient vehicles of the future,” Obama said.

At the time, many auto analysts questioned whether federal subsidies would create a glut of electric batteries and cars.

Obama reasserted his goal in his January State of the Union address, and the Energy Department made hopeful projections. In February, an agency report said U.S. car production “should be sufficient to achieve the goal of one million EVs by 2015,” with enough capacity to produce 44,000 of the top seven electric vehicles in 2011.

Actual sales of those models this year stand at 16,800 — roughly two-tenths of 1 percent of 2011 domestic auto sales. The vast majority were Chevrolet Volts or Nissan Leafs, which were in development long before Obama took office.

Some experts said the administration’s political goal — quickly announcing job creation in a recession — conflicted with the practical realities of expanding a complicated auto industry and wooing consumers.

"This is an investment that could have been planned better,” said Menahem Anderman, a leading auto battery expert and founder of Total Battery Consulting. “This has created a lot of publicity, but people have not bought many more cars as a result.”

White House officials say the electric-car emphasis has had a positive impact by accelerating the shift from foreign oil dependence.

"That effort continues to be successful as sales of advanced­ technology vehicles keep increasing and these technologies continue to support growth of American auto companies, reduce oil dependence and create jobs,” said White House spokesman Clark Stevens.

Ripple effects

Problems in one part of the electric-car sector tend to have ripple effects. A123, for example, is hampered by production delays at a primary customer — Fisker Automotive, which was two years behind on delivering its first model, the luxury sports car Karma.

A123 chief executive David Vieau said in an interview that his company will rebound from these temporary troubles and rehire workers next year to deliver on contracts with other companies, including BMW.

“We’re humbled but not beaten,” Vieau said. “It’s not surprising you’ve seen some bumps and challenges. These are things to be expected in a brand-new space.”

A123 received a $249 million Energy Department grant to build its battery plant in Livonia, Mich., plus $125 million in state incentives. Like Solyndra, the company won presidential praise for its business model. It was cited by Obama in a 2010 Rose Garden news conference and in a Michigan news conference. Obama used an audio conference to congratulate the company on its factory opening.

Some watchdog groups question the value taxpayers are getting for their clean-car investments. The administration devoted $257 million to helping spur Volt battery production, through a $106 million battery assembly grant to GM and another $151 million to its battery provider, LG Chem.

A key industry problem is that electric cars are generally far more expensive than gas guzzlers. That’s true even with up to $7,500 in stimulus tax credits offered for each vehicle.

Obama announced the $2.4 billion in advanced-battery grants at a recreational-vehicle assembly plant in Wakarusa, Ind., where Navistar said it planned to build the eStar, an electric truck for fleets.

“Just a few months ago, folks thought these factories might be closed for good, but now they’re coming back to life,” Obama said that day.

But a large Maryland truck dealership tried for a year to sell an eStar, then sold it back to Navistar. Sam Eitel, marketing manager for Beltway Cos., said customers liked the truck’s sleek looks but were stopped cold by its $150,000-plus list price.

“People are scratching their heads saying, ‘How will we pay this?’” Eitel said.

A Navistar spokeswoman said 100 have been sold so far.

Anderman, who advocates reducing U.S. fossil fuel consumption, said he warned early on that economics did not support the administration’s push. Now he fears failures may undermine industry support.

“Politicians with an ax to grind will say, ‘Here it is — we spent $10 billion, we had companies collapse,’” Anderman said. “‘Here. We tried it. It didn’t work.’”

Research director Alice Crites contributed to this report.

Written by Carol D. Leonnig and Joe Stephens

Chevy Spark Electric Getting Newer-Tech Battery Pack Than Volt

Written by: Christian SeabaughG+ on December 9 2011 2:30 PM

http://rumors.automobilemag.com/chevy-spark-electric-getting-newer-tech-battery-pack-than-volt-93757.html

While investigations are currently on-going regarding the safety of the Chevrolet Volt’s battery pack, Automotive News is reporting that General Motors is going to use a completely different battery technology in the 2013 Chevy Spark Electric that’s more stable, safer, and has a longer lifetime than the Volt’s current lithium-ion battery pack.

Currently, most electric cars and hybrids, including GM’s Chevy Volt and Buick LaCrosse E-Assist, use lithium metal oxide chemistry in their lithium-ion battery packs, sourced from LG Chem in South Korea.  According to AN, GM’s planning on using phosphate-based lithium-ion batteries on its Chevy Spark Electric, sourced from Massachusetts-based A123 Systems.

Lithium phosphate chemistry is being touted as the next big thing when it comes to battery technology. It has the advantage of having better heat management, longer battery life, and being safer than current lithium metal oxide chemistry. GM announced its deal with A123 Systems back in October, months after the May Volt fire at the NHSTA’s testing facility.

When GM was engineering the Volt, it accepted bids from multiple manufacturers to produce the Volt’s battery pack. Two of those manufacturers were LG Chem and A123 Systems. GM chose to go with LG Chem’s lithium metal oxide chemistry batteries because the technology was more proven at the time.

When GM was soliciting bids for batteries, A123 Systems couldn’t prove that they could manufacture its lithium phosphate chemistry batteries at the volume GM required for the Volt. At the same time, lithium phosphate technology was in its infancy and wasn’t yet proven. According to Automotive News, it is now.

With lithium phosphate chemistry ready for prime time and slated to be implemented in the Chevy Spark, the report says that other automakers are starting to use the new technology as well. Fisker is planning on using lithium phosphate batteries for the Karma, and BMW is using them for the ActiveHybrid 5 and ActiveHybrid 3.

With lithium phosphate making its way into the Spark, we see no reason why the new tech won’t find its way into the Chevy Volt in the near future.

Source: Automotive News (Subscription required)

Do Paper-Powered Batteries from Sony Have a Future?

Jaymi Heimbuch

December 19, 2011
http://www.treehugger.com/clean-technology/do-paper-powered-batteries-from-sony-have-a-future.html

© Sony

Sony has come up with an interesting way to power electronics that uses old cardboard and some enzymes. Calling it a bio battery, the company thinks the technology shows promise.

Bio Battery as Eco-Friendly?
PhysOrg reports, "As an environmental products fair opened in Tokyo, Sony invited children to put paper into a mixture of water and enzymes, shake it up and wait for a few minutes to see the liquid become a source of electricity, powering a small fan."

Chisato Kitsukawa, a public relations manager at Sony, says that while the research has been around for generating power in this way, demonstrating it is rare. Indeed, Sony has been working on their bio battery for years.

Sony states, "Because glucose is a clean energy source---produced by plants through photosynthesis (a process that involves the absorption of CO2)---Bio Battery is also an eco-battery."

Erm...well... using a bunch of paper to get a small amount of power may not really be a stellar solution for environmentally friendly batteries. Very little power actually comes out of the process, at least with the technology we have so far. Still, it's an interesting experiment.

How The Bio Battery Works
"Shredded paper or pieces of corrugated board were used at the fair to provide cellulose, a long chain of glucose sugar found in the walls of green plants. Enzymes are used to break the chain and the resulting sugar is then processed by another group of enzymes in a process that provides hydrogen ions and electrons. The electrons travel through an outer circuit to generate electricity, while the hydrogen ions combine with oxygen from the air to create water," reports PhysOrg.

Paper In Our Batteries
While this isn't a great solution for our every day batteries, it could be useful for powering small, low-energy devices. In fact, we've heard of paper-based batteries before, back in 2009 when researchers from Uppsala University in Sweden were testing a prototype for a new battery made of salt and paper, which could one day be an environmentally benign replacement for lithium batteries in things like smart cards, RFID tags, and other low power portable devices. They may not be the source of the energy, such as what Sony is getting at, but they would hold a charge.

Sony, on the other hand, wants these batteries to be a major commercial product in the near future. The company states, "Sony will continue to work toward the commercialization of this technology in the near future, initially for use in toys and other low-power products. The longer-term goal for R&D in this area is to further enhance performance to ultimately develop batteries suitable for notebook computers and other mobile devices."

Energy

Startup Promises a Revolutionary Grid Battery

Eos Energy Storage says its zinc-air battery can store energy to meet peak power needs for less.
http://www.technologyreview.com/computing/39425/?p1=A2

By Phil McKenna

Long life: This kilowatt-scale zinc-air battery prototype can be charged and discharged 2,700 times with no physical degradation, its maker claims.

Battery developer Eos Energy Storage claims to have solved key problems holding back a battery technology that could revolutionize grid energy storage. If the company is right, its zinc-air batteries will be able to store energy for half the cost of additional generation from natural gas—the method currently used to meet peak power demands.

Company officials say that current prototypes demonstrate twice the energy density of lithium-ion batteries. They claim their final product will last for 30 years in grid-scale applications with a cycle life that is orders of magnitude greater than that of lead-acid batteries, making it one of the longest-lasting battery types around. CEO Michael Oster says Eos will soon complete a $10 million round of funding from several investors.

"If they can get what they are claiming, it would be revolutionary," says Steve Minnihan, an analyst with Lux Research, who says the technology shows promise for both grid storage and electric vehicles.

Zinc-air technology has long attracted battery developers because it's safe, it's inexpensive, and it offers high energy densities. Unlike conventional batteries, in which all reactants are packaged within the battery, zinc-air cells draw in oxygen from the air to generate current. Drawing on outside air gives the batteries a higher capacity-to-volume ratio and lowers the material costs. The battery's water-based chemistry also means it isn't prone to catching fire, unlike lithium-ion batteries.

Until now, however, these batteries have had low efficiencies and short life cycles, limiting their use to small, nonrechargeable applications such as hearing aids. Eos officials say they have solved several problems that have confounded previous efforts.

Eos's key advances involve changes in electrolyte chemistry and cell design. Zinc-air batteries typically use potassium hydroxide, a basic solution that absorbs carbon dioxide from the air. That causes potassium carbonate to build up, slowly clogging the cell's air pores. Because Eos's batteries use a novel pH-neutral electrolyte, Oster says, they do not absorb carbon dioxide. The company also uses a unique horizontal cell configuration that relies on gravity rather than a physical membrane to separate the liquid electrolyte from the air. The change, he says, prevents buildups on the zinc electrode from rupturing the membrane and causing cell failure.

Oster says the company has achieved more than 2,700 cycles with no physical degradation in a one third kilowatt-scale battery. In comparison, ReVolt Technology, a leading competitor pursuing similar technology, hopes to reach 1,000 cycles by 2013. Minnihan, however, says Eos still has a long way to go to reach its goal of 10,000 cycles and megawatt-scale batteries.

Eos Energy Storage

3 East 80th Street, New York, NY 10075

+1.212.628.7191 ph

+1.212.628.7193 fax

3700 Glover Road, Easton, PA 18040

+1.610.258.7777 ph

+1.610.258.7099 fax

info @ eosenergystorage.com

http://www.ibm.com/smarterplanet/us/en/smart_grid/article/battery500.html

The Battery500 Project

A century ago, more automobiles were powered by electricity than by gasoline.

But the need for longer travel ranges, the availability of a more affordable fuel source and a reliable power infrastructure soon turned internal combustion engines into the predominant means of motor transportation.

Now drivers are considering a move away from gasoline and back to electricity as an ideal source for automotive power, but big challenges remain. IBM and partners are working on solving one of the biggest barriers to widespread electric vehicle adoption: limited battery range.

An antidote to 'range anxiety'
Most people consider switching to electric vehicles to save money on gas and contribute to a healthier environment. But “range anxiety,” the fear of being stranded with no power, was cited by 64 percent of consumers as a main detractor to buying an electric vehicle.

Electric cars today typically can travel only about 100 miles on current battery technology, called lithium-ion (LIB). LIB technology stands little chance of being light enough to travel 500 miles on a single charge and cheap enough to be practical for a typical family car. This problem is creating a significant barrier to electric vehicle adoption.

Recognizing this, IBM started the Battery 500 project in 2009 to develop a new type of lithium-air battery technology that is expected to improve energy density tenfold, dramatically increasing the amount of energy these batteries can generate and store. Today, IBM researchers have successfully demonstrated the fundamental chemistry of the charge-and-recharge process for lithium-air batteries.

Meet the team

The Battery 500 project was developed out of the Almaden Institute, an annual forum that brings together eminent, innovative thinkers from academia, government, industry, research labs and the media for an intellectually charged, stimulating and vigorous dialogue that addresses fundamental challenges at the very edge of science and technology. The partnerships born out of this event range from university and national laboratory collaborations to connections across IBM research labs and with industry experts, all forming a dynamic, multi-disciplinary team, focusing on unique aspects of the project.

Winfried Wilcke
Senior Manager, Nanoscale Science and Technology, Energy Storage, IBM Research – Almaden
Read more about Winfried

Chandrasekhar (Spike) Narayan
Functional Manager, Science and Technology IBM Research - Almaden Research Center
Read more about Spike

Don Bethune
Research Physicist, IBM Research - Almaden

Alessandro Curioni
Manager, Computational Sciences Group, IBM Research - Zurich

Scott Campbell
Research Scientist, Physics, IBM Research - Almaden

Mark Hart
Research Scientist, Physics, IBM Research - Almaden

Ho-Cheol Kim
Research Staff Member, Materials Science, IBM Research - Almaden
Read more about Ho-Cheol

Alan Luntz
Research Consultant, Battery 500, IBM Research - Almaden

Teodoro Laino
Research Staff Member, Computational Sciences, IBM Research - Zurich

Bryan McCloskey
Post-Doctoral Research Associate, Electrochemistry, IBM Research - Almaden
Read more about Bryan

Bob Shelby
Research Scientist, Physics, IBM Research - Almaden

Carl Larson
Manager, Nanoscale Fabrication, IBM Research - Almaden

Julia Rice
Research Scientists, Life Sciences Simulation and Information Management, IBM Research - Almaden

Phil Rice
Research Scientist, Materials Analysis and Characterization, IBM Research - Almaden

Mark Sherwood
Research Scientist, Chemistry, IBM Research - Almaden

Barton Smith
Manager, Collaboration Science, User Systems and Experience Research, IBM Research - Almaden

Sally Swanson
Research Staff Member, Nanoscale Science and Technology, IBM Research - Almaden
Read more about Sally

Qing Song
Research Staff member, Advanced Organic Materials, IBM Research - Almaden
Read more about Qing

Bill Swope
Research Scientist, Macromolecular simulation and modeling, IBM Research - Almaden

Kumar Virwani
Research Scientist, Materials Analysis and Characterization, IBM Research - Almaden

Greg Walraff
Research Scientist, Chemistry, IBM Research - Almaden

Hybrid Approach Stretches the Miles

Fuel cell/battery combo promises greater range for electric vehicles.

http://www.mdatechnology.net/update.aspx?id=a5764

Building on a research project done under MDA, Swift Enterprises (West Lafayette IN) has designed a fuel cell now being considered as a range extender for use in fully electric vehicles.

The solution’s design includes a Stratum Technologies, Inc., lithium-ion polymer battery.

Dubbed the eVia system, the combination of Swift’s fuel cell with Stratum’s thermally stable lithium polymer battery aims to use the battery as a power source for good acceleration, and the fuel cell as a source for energy during steadier driving conditions. Swift’s fuel cell confers more energy density to the fuel cell than more mainstream hydrogen gas-based fuel cells.

In addition to fuel-cell design, Swift’s strengths include development of new fuels. The company’s fuel-cell work has been supported in part through an MDA SBIR Phase I awarded in 2002.

Contact Information

Don Bower
(765) 464-8336
don.bower @ swiftenterprises.com
www.swiftenterprises.com

Swift Enterprises, Ltd.
1291 Cumberland Ave
Suite F
West Lafayette, IN 47906

http://www.swiftenterprises.com/eVia.html

eVia - Electric Vehicle System

Electric propulsion is currently not up to the level of development it needs to be to effectively power vehicles. The batteries of today have adequate power output for transportation applications, but the energy density associated with such units is simply not comparable to internal combustion engines. This means that while a battery can provide, for example, good acceleration for a car, that same car will not be able to go very far on one charge. The eVia system aims to solve this problem by integrating a Stratum lithium-ion polymer battery with a Swift fuel cell stack. The battery of course supplies the power, while the fuel cell stack supplies the endurance as a range extender. The above picture details a simplistic systems diagram of the proposed eVia project.

Note that both reactants have a loop whereby they travel from a higher concentration stock tank, into a dilution tank, move into the fuel cell stack and then the reactants either get filtered out or they make another pass in the loop. The purpose of the dilution tank is to take higher concentration reactants and dilute them as necessary to keep a roughly steady state concentration in the loop. As more reactants are needed to keep the concentration up, more stock solution is fed into the system. This allows for more energy to be stored without the necessary water weight and volume to keep it at a standard concentration. On the H2O2 side, water is collected and sent around the loop again or sent to the NaBH4 loop as it is losing water in the reaction. NaBO2 (sodium metaborate) is collected as a precipitate in the NaBH4 loop. The fuel cell stack’s purpose is to create power for the motor during low power applications, any residual energy being used to charge the battery. To show how effective this system potentially can be, we have put together a mathematical model with a Stemme S10. This case study shows the basic feasibility of the eVia system, in particularly with regard to how much range the aircraft can have with it.

MIT’s photonic crystals lead towards nuclear batteries everywhere

By Sebastian Anthony on February 3, 2012 at 8:19 am
http://www.extremetech.com/extreme/116853-mits-photonic-crystals-lead-towards-a-nuclear-reactor-in-every-gadget?utm_source=feedburner&utm_medium=feed&utm_campaign=Feed%3A+ziffdavis%2Fextremetech+%28Extremetech%29&utm_content=Google+Reader

Researchers at MIT have developed photonic crystals that, in as little as two years, could enable the use of hydrocarbon reactors in portable electronic devices, and nuclear power sources everywhere else.

Photonic crystals are optical nanostructures that are tuned to specific wavelengths of light. If you understand how semiconductors affect the motion of electrons (i.e. the bandgap only allows electrons with a certain energy level to pass through), photonic crystals are the optical equivalent. In this case, MIT has created infrared-absorbing photonic crystals using metals such as tungsten and titanium. Because of their metallic roots, these photonic crystals can operate at temperatures up to 1200C (2192F).

You can probably see where this is going. Basically, every object that is warmer than absolute zero emits electromagnetic radiation — and the hotter it gets, the higher the frequency of that radiation. Once an object becomes red or white hot, some 99% of the radiation produced is infrared. MIT’s photonic crystals are perfectly tuned to absorb infrared radiation, and they can survive high temperatures. This captured energy can then be converted into electricity.

As far as suitable heat sources go, they’re a dime a dozen. As it stands, many of NASA’s deep space missions — Pioneer, Viking, Cassini-Huygens, the Curiosity Mars rover — use radioisotope thermal generators, which generate heat from the decay of radioactive material (usually plutonium, pictured right). Currently, a thermocouple is used to create electricity from the heat, but thermocouples are incredibly inefficient (they max out at around 10%). These photonic crystals would be more efficient (and MIT is already talking to NASA about it).

Looking towards the future, MIT’s photonic crystals could offer an alternative to photovoltaic panels or fuel cells. Any source of heat could be turned into electricity, without the need for turbines or any other moving parts. According to MIT researcher Ivan Celanovic, for a given weight and size, a microreactor that burns butane and uses photonic crystals could last 10 times longer than existing battery technology.

If you’re not comfortable with having a reactor in your pocket, though, the photonic crystals could be used to simply capture waste heat, much like the University of Minnesota multiferroic alloy or German magnetic RAM that we covered last year.

The best bit, though, is that MIT is confident that this technology could be brought to market in as little as two years. Photonic crystals are actually quite mature tech; the actual meat of this discovery is that they’ve found a way to cheaply mass-produce rugged crystals that can operate at high temperatures. This technology is coming.

California Sets New Standards For Energy Efficient Battery Chargers

EarthTechling.com Staff

January 26, 2012

http://www.treehugger.com/clean-technology/california-sets-new-standard-energy-efficient-battery-chargers.html  

California has been buzzing with talk about vampires, but this has nothing to do with a certain porcelain-skinned heartthrob or HBO hit series. Instead, the vampires in question are the battery chargers that have been slowly draining electricity right under our noses.

But don’t fear, the California Energy Commission is putting a stop to it with the nation’s first energy efficiency standard regulating the battery chargers that increasingly accompany our on-the-go lifestyles. Starting in February 2013, consumer chargers for cell phones, laptops, toothbrushes – you-name-it – will have to comply with the new standard, followed by industrial chargers in 2014.

The estimated 170 million chargers in California households have been wasting some serious energy. They consume 8,000 gigawatt-hours (GWh) of electricity each year, and nearly two-thirds of that energy is wasted by inefficiency, often as heat. Battery chargers use energy in three different modes: when they are actively charging the battery; after the battery is fully charged, but the charger is still plugged in; and when disconnected from the device, but still plugged into an outlet. The new efficiency standards set limits to how much energy can be consumed during each of these modes, reducing wasted energy by 40 percent.

The California Energy Commission says that once fully implemented, the efficient chargers will save an estimated 2,200 GWh each year – enough to power 350,000 homes – while trimming Californians' utility bills by a total of $300 million and sparing 1 million metric tons of carbon emissions.

As we have experienced before, innovation and efficiency often bumps up the initial price of the product, but the commission estimates that the energy savings should more than compensate. For example, a more efficient charger to your laptop could cost an additional 50 cents, but will save an estimated $9 in electricity bills over its lifetime.

"Our smart phones and other electronic devices are about to get a whole lot smarter by not wasting electricity and our money," said Bernadette Del Chiaro, director of clean energy programs at Environment California. "This is a good deal for consumers and the environment and a no-brainer for California to once again provide leadership on."

Indeed, California yet again proves itself to be the Wild West trail-blazer in energy efficiency standards, setting its own rules without waiting for the nod from a similar federal regulation currently under development. But the rest of the country may not have to wait for a federal regulation to enjoy efficient chargers.

While manufacturers bear the burden of innovating and redesigning their products to meet these standards, many consumer electronics manufacturers already meet the standards proposed. And even without a national regulation, California’s larger market is a powerful incentive for manufacturers to redesign and convert their chargers to meet the higher California standards.

Old Electric Car Batteries to Find Second Life on the Power Grid

Michael Graham Richard

January 20, 2012
http://www.treehugger.com/cars/electric-car-batteries-being-tested-grid-emergency-storage.html

© Nissan

Reincarnation for Lithium-Ion

It's not because a battery pack isn't good enough for an electric or hybrid car anymore that it should go directly to a recycling plant. There are lots of potential secondary uses for batteries that can still hold more than half of their original charge. I've already written about how they could be used to store wind power to reduce the intermittency problem, but a new partnership between Nissan North-America, ABB, 4R Energy, and Sumitomo Corporation of America believes that used electric car batteries (Nissan LEAF ones, in this case) could be used for residential and commercial energy storage, even acting as emergency back-up during natural disasters like last year's earthquake and tsunami in Japan.

Electric car batteries have up to 70% capacity remaining after 10 years of use. This allows them to be used beyond the lifetime of the vehicle for applications, and smart grids can take advantage of their capacity to store intermittent renewable energy.

Innovative energy storage solutions are expected to become a key component of the smart grid, contributing to greater efficiency, reliability and performance. They will facilitate further integration of renewable energy sources, such as wind and solar, into the grid. The evaluation of Nissan batteries, through the partnership, will help determine their suitability for the power industry as a cost-effective energy storage solution. (source)

The partners plan to develop a LEAF battery storage prototype with a capacity of at least 50 kilowatt hours (kWh), enough to supply 15 average homes with electricity for two hours. I assume that if that works out well, they'll scale it up, possibly even up to the multi-megawatt-hour scale, which would make it really useful in emergencies and to store solar or wind power.

Via ABB, GCC

http://www.youtube.com/watch?v=QgPZt7PDSCQ

Air battery to let electric cars outlast gas guzzlers

• 06 January 2012 by Duncan Graham-Rowe
• Magazine issue 2846.
  http://www.newscientist.com/article/mg21328466.200-air-battery-to-let-electric-cars-outlast-gas-guzzlers.html

ONE of the biggest drawbacks with owning an electric vehicle (EV) is range anxiety - a driver's nagging fear that the battery charge will not get them to their destination. Now IBM claims to have solved a fundamental problem that may lead to the creation of a battery with an 800-kilometre (500-mile) range - letting EVs potentially compete with most petrol engines for the first time.

Standard electric vehicles use lithium-ion (Li-ion) batteries, which are bulky and rarely provide 160 kilometres (100 miles) of driving before they run down.

A newer type, known as a lithium-air cell, is more attractive because it has theoretical energy densities more than 1000 times greater than the Li-ion type, putting it almost on a par with gasoline. Instead of using metal oxides in the positive electrode, lithium-air cells use carbon, which is lighter and reacts with oxygen from the air around it to produce an electrical current.

But there's a problem. Chemical instabilities limit their lifespan when recharging, making them impractical for use in cars, says physicist Winfried Wilcke at IBM's Almaden laboratories, based in San Jose, California.

So Wilcke studied the underlying electrochemistry of these cells using a form of mass spectrometry. What he found was that oxygen is reacting not just with the carbon electrode, as it was known to, but also with the electrolytic solvent - the conducting solution that carries the lithium ions between the electrodes.

However, if the electrolyte reacts with the oxygen when the car is in use it will eventually be depleted. So, working with his colleague Alessandro Curioni at IBM's Zurich research labs in Switzerland, Wilcke used a Blue Gene supercomputer to run extremely detailed models of the reactions to look for alternative electrolytes. This included a form of atomistic modelling right down to the quantum mechanics of the components, says Curioni.

"We now have one which looks very promising," says Wilcke. He won't reveal what material it is but says that several research prototypes have already been demonstrated. And as part of Battery 500, an IBM-led coalition involving four US national laboratories and commercial partners, the hope is to have a full-scale prototype ready by 2013, with commercial batteries to follow by around 2020.

If it works, this would solve a major obstacle with lithium-air batteries, says Phil Bartlett, head of electrochemistry at the University of Southampton, UK. There are other practical issues to address, such as enabling such batteries to cope with moist air. "Lithium in water spontaneously catches fire," he points out.

What Do We Need From the Battery of the Future? By David Biello

·         January 25th, 2012

·         By Txchnologist Guest

http://www.txchnologist.com/2012/what-do-we-need-from-the-battery-of-the-future-by-david-biello

Imagine a car that could go 300 miles – that’s Chicago to St. Louis – on battery power. That’s not possible today without either an assist from a gasoline-fueled engine functioning as a charger (the Chevy Volt solution) or an alternate drive provider (the Toyota Prius solution). The fact that such cars need, in effect, two engines, means that battery-powered options remain much more expensive than their purely gasoline-fueled peers, which require only a single powertrain.

“We need batteries that last longer, charge quickly and are inexpensive,” says ecologist Joe Fargione of The Nature Conservancy, an expert on the environmental impacts of biofuels, another transportation fuel alternative. “With that [electrification of cars] would be relatively simple. The rest of the technology is there.”

So the battery the future requires is cheap, more energy dense and less fragile. No car on the market can meet all of these requirements: the $35,200 all-electric Nissan Leaf has only 100 miles of advertised range, while Tesla’s new souped-up model S, with an advertised 300 miles of range, will be priced at $77,400 and have an actual range that is closer to 240 miles. Meanwhile, batteries all too often burst into flame — recall the Sony laptop lithium-ion batteries of several years ago or the recent controversy over the Chevy Volt’s batteries — or stop functioning because of degraded components. The question is: can such a battery be made?

What is a battery?

Alessandro Volta built the first modern battery around 1800, by piling discs of zinc and silver separated by cloth soaked in salt water. The salt water oxidized the zinc, freeing up electrons, which then migrated to the silver. By keeping those electrons flowing, Volta induced an electrical current from the battery and was the first to demonstrate the properties of properly configured electrolytes, anodes and cathodes.

This first battery had all kinds of limitations, incl

A Voltaic pile at the Musee des arts et Metiers, Paris. Courtesy Flickr user SSShupe

uding almost instant corrosion that would shut down the chemical reactions needed to generate electric current. Plus, Volta’s battery could never be too big because the weight of the discs began to squeeze the salt water out of the intervening cloth.

Batteries have improved immensely in the more than 200 years since, as carbon and various lithium-based compounds have supplanted the zinc and silver of Volta’s proto-batteries. But the same fundamental challenges remain: a battery that stores twice as much energy and can take you twice as far is going to be twice as large, which is to say, too big for a car. And that’s just one of the challenges.

“As a storage device for energy, a battery is notoriously inefficient,” notes Johan de Nysschen, the president of Audi of America, though the automaker is investing in battery-powered vehicles. Today’s lithium ion batteries hold roughly 0.72 megajoules per kilogram. The equivalent amount of gasoline holds 35 times more energy.

Better energy storage

The search is on for new materials to boost energy storage. One candidate is the same silicon that makes computer chips and photovoltaics possible. This semiconductor can also serve as a powerful anode, as much as 30 percent more powerful than the carbon anodes used today.

The problem is that silicon doesn’t hold its shape, swelling when charging before shrinking back as it discharges. As a result, much like Volta’s original long ago, batteries employing silicon don’t last very long. Other alternatives to improve on carbon include water and even air — the problem being that volatile lithium can spontaneously combust in both.

Argonne's microcapsules, just 10 microns across, burst to repair batteries. Image by Amanda Jones and Ben Blaiszik/Argonne National Laboratory

To combat this battery life problem, researchers at Argonne National Laboratory (ANL) and elsewhere are working on devices that could self-heal. The idea is to include microcapsules of liquid metal smaller than a cell of along the surface of the anode or cathode. When that surface becomes damaged the capsules burst and the liquid metal fills in the blemishes cutting off current.

Finally, batteries that could be refilled on the go, such as the “flow batteries” being developed at the Massachusetts Institute of Technology, might provide a solution to long-distance transport, though refueling stops would become more frequent. Think of it as a battery masquerading as a liquid fuel. Essentially, these batteries break up their anode and cathode materials into particles floating in the liquid electrolyte. Such electricity generating solutions could then be used until fully discharged, pumped out, and the battery refilled with fresh solution, though this poses the usual chemistry and infrastructure challenges facing all battery-powered vehicles. The company Better Place has a similar idea for swapping out more traditional batteries entirely and will begin rolling that system out in Denmark, where installing the infrastructure can be more manageable.

A better use?

In the end, however, even these futuristic batteries and schemes pale in comparison to the energy density and convenience of fossil fuels — a lithium air battery, the most energy dense battery on offer in the laboratory, might hold roughly one-fifth the energy of a similar amount of gasoline. Further, such batteries will be expensive. “We have solutions to all of our energy problems, but our solutions cost too much,” says physicist William Brinkman, director of the Office of Science at the U.S. Department of Energy (DoE).

The Tesla S: a maximum of 300 miles range with a big asterisk. Courtesy Tesla

But that doesn’t mean that such batteries won’t find a use, for example, in the military, which has partnered with the DoE to test large-scale batteries for microgrids. And renewable sources of electricity, such as the wind and sun, may also rely on large-scale battery storage to smooth out interruptions in the supply of power from such sources.

But it’s cars that really rev the motor of battery enthusiasts. As a result, the DoE will launch this year a new research center devoted to “dramatically improv[ing] battery and energy storage technologies for vehicle and grid applications,” announced Secretary of Energy Steven Chu at an event in Detroit on January 11. “Imagine a low-cost battery that allows you to drive a few hundred miles, recharge while you stop for lunch, and then drive on for another few hundred miles. Achieving this goal could be transformative.”

Nevertheless, it is those working on batteries within the DoE who recognize the scale of the challenge — and the hurdles presented by basic physics. ANL developed lighter, safer and cheaper to manufacture lithium-ion batteries that also mix in manganese, which will soon be used in the Chevy Volt. But that doesn’t mean the battery will soon triumph. “Is the battery going to supplant or replace the internal combustion engine?” asked Jeffrey Chamberlain, leader of Argonne’s energy storage initiative, including advanced batteries, at a New America Foundation event this past October on energy in 2030. “That’s never going to happen: not in my lifetime, my children’s lifetime or my children’s children’s lifetime.”

Top image: Lithium-ion battery cells at Argonne’s Electrochemical Analysis and Diagnostics Laboratory. Courtesy Argonne National Laboratory

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David Biello is an associate editor at Scientific American. In December, he won a Silver Baton 2012 Alfred I. duPont-Columbia University award for hosting and co-writing the Detroit Public Television special Beyond the Light Switch. He has written for publications ranging from Good to Yale e360 and speaks on radio shows such as WNYC’s The Takeaway.

Comments

TJ Anderson 1 month ago

There are a lot of competing technological ‘breakthroughs’ currently in the advanced and early research stages that all hope to be the solution to the problem. In actuality I think it will take a combination of most of those

Bob Wallace 29 days ago

The Honda FiT will use the Toshiba SCiB lithium-ion battery. It will take a 95% recharge in less than 20 minutes. (It also is rated at 4,000 cycles which makes it a 400,000 mile battery.)

The ‘threshold”, I think, is a 175 mile range battery. That would allow a 500 mile driving day with only two 20 minute stops. We don’t actually need a 300 mile range.

—

This – “batteries all too often burst into flame”. Why do you make such a silly claim?

When’s the last time you heard of a laptop, digital camera, hearing aid, cell phone bursting into flame?

And the Volt battery fire, a severely crash-damaged battery that was not properly discharged burst into flames three weeks after the coolant evaporated and created a short. It’s common practice to drain gas tanks and disconnect starter batteries when wrecked gasmobiles are hauled to the wrecking/storage yard. All that’s needed is to put the wrecked EV battery electricity back into the grid.

abrahim sabir 29 days ago

eventually the concept must boil down to ‘storage’ and ‘production’ . storage shudnt necessarily means battery chemistry. Honda’s FCV (fuel cell vehicle) is one of the ways ahead. the permutations in case of battery chemicals are unlikely to get anywhere near the calorific density of gasoline or compressed hydrogen. Its important to have the objective in focus and avoid getting lost in the intermediates and the objective is to get rid of the IC engine as we know it. solution to little issues like ‘fast charging’ do exist in form of super-capacitor based charging units which can accept large amount of charge in a flash which can then be pushed into the battery by an efficient DC-DC converter. at the end of the day 300mile/top-up will not happen purely on the basis of battery capacity but on a combination of many different ideas.

1.     Bill Dale 26 days ago

Tsk, tsk! Such overwhelming lack of vision, and excessive pessimism! These are the kinds of doubters that the Wright brothers, and Robert Fulton, and Tesla (both the genius a hundred years ago, and the car company today that bears his name in homage), and countless others had to ignore to bring new technologies to market. There’s a perfectly good reason ships can’t be built of iron, of course– it’s heavier than water, and it will sink. Despite what seemed like perfect logic, ships have been built of metal, to the embarrassment of their critics.

The problem with air batteries is that lithium is highly volatile– it burns fiercely when in contact with water, or even the moisture in the air. To make an air battery work, the anode must have a membrane that separates it from the air, but that still allows ions in the atmosphere to pass through and interact with the charged plates. That’s a thorny problem, but I do not see it as any more substantial than, say, finding a way to make organic LEDs (OLEDs) that started out as very promising laboratory curiosities, but had useful lives measured in hours. Many people, thought they’d never make it to market, or be affordable. I’m typing this comment on an OLED smart phone right now, and its contrast, efficiency and other qualities make it far better than LED screens of the past. I am not willing to pay much attention to those that give reasons a thing cannot be done.

Air batteries, if they succeed, may be more expensive per pound than today’s batteries, but that is no excuse for not pursuing them– they may yield storage so dense that they only need to be a tenth the size to provide 300 miles range. If such a battery can he made, everything else in the car can be lighter as well, particularly the suspension system, electric motor and electronic controller.

Another technology that coats the charge plates with carbon nanotubes may similarly increase the battery’s energy density by ten times– then again, maybe neither approach succeeds beyond, say, 20%– but combined, the two technologies may give us greater range than we can achieve with gasoline. We wull never know unless we ignore the pessimists. And even if we don’t achieve anything more than modest gains with new batteries, they will still inevitably succeed in some proportion– petroleum will not last forever, what we do pump from below will continue to be more and more difficult and expensive to access. China and India are only now beginnng to use significant numbers of ICE cars, and if all the billions of Chinese want to drive automobiles, which is likely, gasoline will soon become unaffordable. EV use will inevitably become our best alternative even if battery technology does not advance as rapidly as we’d like– which I think is unlikely. I look forward to clean, quiet, smog-free highways, and running on electrons rather than fuel supplied by countries that would like nothing more than to use our petro dollars to finance weapons of mass destruction to annihilate us.

Klaus Beccu, Ph.D. 6 days ago

Air batteries are certainly the storage systems to pursue furthermore. As Bill Dale pointed out, the problems with Li-air are severe, not only the humidity problem but also the low performance of an air electrode in organic electrolytes is a restriction for high power applications. The comparison with electronic developments (OLED), that any problem can be solved follows however always the same error often announced: to compare electronics with electrochemistry. Both developments are based on completely different scientific principles.

A promising Air battery that avoids the problems of Li-air: is the Proton-Ion battery (metal hydride – air), now under development at Ovonic Battery Company [OBC] . The Proton-Ion system allows to reach energy densities up to 300 Wh/kg, works in aqueous electrolyte ast high performance and avoids the dendrite problem of Zinc-air. OBC is the leader in metal hydride batteries [NiMH] installed in over 3 million hybrid vehicles from Toyota, Honda, Ford, VW, BMW, Porsche, PSA etc. In the 2nd generation NiMH

Klaus Beccu, Ph.D. 6 days ago

Last comment shut down before finished!

In the 2nd generation NiMH shows comparable energy densities as LiFePO4 batteries, however at 1/3 of the cost of Li-ion and without any safety problem. The outstanding merits of this storage systems were recently recognized by the takeover of OBC by BASF-USA . While OBC has performed major improvements in the choice of the metal alloy and structure and especially has succeeded to license the NiMH-technology to 35 companies worldwide, the pioneer invention of electrochemically reversible hydrogen storage in metal hydrides came originally (1967) from the Battelle Geneva Research Center, where this technology was patented and developed for Daimler-Benz and VW over 20 years.

2.     Eyal (Fuel Freedom) 4 days ago

What a silly article. Its entire premise is wrong.
1. Need to compare the final weight of the electric car vs ICE car. With 60% less systems (engine, fuel injection system, transmission, etc.) the electric car has a lot less to carry around. Just comparing the battery weight to energy density of gasoline is unfair.
2. The article assumes that there is such as think as a family car. In the US at least there is no such thing anymore. We have a car per driver. In most households there are at least 2 cars. If one of your cars is electric and the other gasoline and you need to take a longer trip just switch cars with your spouse.
3. Even if both household cars are electric, you can always rent a car for those handful of trips to Vegas or to grandma.

With less than 20,000 electric cars sold in 2011 out of almost 50,000,000 cars that were made last year, the road is pretty long for electric mobility to rule the globe. But one thing is for sure, there will be plenty of innovation along the way, most of it might not even be imagined today.

http://www.mynewsdesk.com/se/pressroom/invest_sweden/pressrelease/view/sweden-invites-to-advanced-battery-innovation-567871

From: JHChao@...
Subject: Berkeley Lab Battery Team: Working to Drive Electric Vehicles From Niche to Mass Market

- Berkeley Lab News Center - http://newscenter.lbl.gov -

Copyright © 2008 Berkeley Lab News Center. All rights reserved.

Lauren Flynn
AH&M Marketing Communications
152 North Street, Suite 340
Pittsfield, MA 01201
Tel: +1 413.448.2260 ext. 140
Fax: +1 413.445.4026
E-mail: lflynn @ ahminc.com
 

Owens Corning Develops New Non-Woven Glass Fiber Veil to Improve Performance of Flooded Lead-Acid Batteries

for Stop-Start Engine Systems

New Veil Requires No Capital Investment,

Streamlines Production and Extends Battery Life and Capacity

PARIS, March 29, 2011 –Owens Corning (NYSE: OC), the leading global producer of glass fiber reinforcements for composite systems, today announced a new solution to help battery makers meet the challenges of stop-start engine technology.  The announcement was made in conjunction with the 2011 JEC Composites Show, the world’s largest composites exhibition, where Owens Corning is exhibiting in Booth R20.

Owens Corning’s new non-woven glass fiber veil using corrosion-resistant Advantex^® E-CR glass technology increases cycle lifetime of traditional flooded lead-acid batteries, in particular at partial state of discharge.  Other benefits include reduced acid stratification and the ability to operate in higher-temperature environments.

Working with several battery makers and a global leader in lead-acid battery chemistry, Owens Corning developed the non-woven glass fiber veil that is applied directly to the face of the positive electrode during production, and improves the battery’s capability to support the increased requirements of stop-start engine systems.  The new glass veil technology requires no capital investment by battery manufacturers and eliminates a component by replacing sacrificial pasting paper used only as a process carrier during the electrode pasting process.  

“Stop-start engine technology is a growing and very promising environmental initiative to conserve fuel and cut emissions, but it places heavy demands on a vehicle’s battery,” said Industrial Business Development Leader for OCV™ Non-Woven Technologies Ralph Jousten. “To help battery manufacturers improve the performance and lifespan of their products, we developed a solution that enhances existing flooded batteries. With our glass veil, customers can meet the performance challenges of new stop-start engines and compete successfully at a lower cost versus traditional batteries.” 

This solution also provides cost advantages over AGM (absorbed glass mat) battery types that produce more cycles but are priced about 2.5 times higher and are more sensitive to heat and overcharging than flooded lead-acid batteries.

Stop-start engine systems cut fuel consumption and CO₂ emissions by temporarily shutting off during idling, such as at stoplights and railroad crossings, and then restarting the engine upon acceleration. The technology is particularly beneficial in vehicles that make frequent stops, such as delivery or service vehicles.

About Owens Corning

Owens Corning (NYSE:OC) is a leading global producer of residential and commercial building materials, glass-fiber reinforcements and engineered materials for composite systems. A Fortune® 500 Company for 56 consecutive years, Owens Corning is committed to driving sustainability by delivering solutions, transforming markets and enhancing lives. Founded in 1938, Owens Corning is a market-leading innovator of glass-fiber technology with sales of $5 billion in 2010 and about 15,000 employees in 28 countries on five continents. Additional information is available at www.owenscorning.com.

Contact:

Beth Rettig                                           

Owens Corning                                     

1-419-248-6777 

Beth.Rettig @ owenscorning.com 

{~B914144911174430006419506261715~}

18 November 2011
http://www.bbc.co.uk/news/technology-15788735

World's 'lightest material' unveiled by US engineers

Engineers say the material is less dense than aerogels and metallic foams

A team of engineers claims to have created the world's lightest material.

The substance is made out of tiny hollow metallic tubes arranged into a micro-lattice - a criss-crossing diagonal pattern with small open spaces between the tubes.

The researchers say the material is 100 times lighter than Styrofoam and has "extraordinarily high energy absorption" properties.

Potential uses include next-generation batteries and shock absorbers.

The research was carried out at the University of California, Irvine, HRL Laboratories and the California Institute of Technology and is published in the latest edition of Science.

"The trick is to fabricate a lattice of interconnected hollow tubes with a wall thickness 1,000 times thinner than a human hair," said lead author Dr Tobias Schaedler.

Low-density

The resulting material has a density of 0.9 milligrams per cubic centimetre.

By comparison the density of silica aerogels - the world's lightest solid materials - is only as low as 1.0mg per cubic cm.

The metallic micro-lattices have the edge because they consist of 99.99% air and of 0.01% solids.

The engineers say the material's strength derives from the ordered nature of its lattice design.

By contrast, other ultralight substances, including aerogels and metallic foams, have random cellular structures. This means they are less stiff, strong, energy absorptive or conductive than the bulk of the raw materials that they are made out of.

William Carter, manager of architected materials at HRL, compared the new material to larger low-density structures.

"Modern buildings, exemplified by the Eiffel Tower or the Golden Gate Bridge are incredibly light and weight-efficient by virtue of their architecture," he said.

"We are revolutionising lightweight materials by bringing this concept to the nano and micro scales."

Robust

To study the strength of the metallic micro-lattices the team compressed them until they were half as thick.

After removing the load the substance recovered 98% of its original height and resumed its original shape.

The first time the stress test was carried out and repeated the material became less stiff and strong, but the team says that further compressions made very little difference.

"Materials actually get stronger as the dimensions are reduced to the nanoscale," said team member Lorenzo Valdevit.

"Combine this with the possibility of tailoring the architecture of the micro-lattice and you have a unique cellular material."

The engineers suggest practical uses for the substance include thermal insulation, battery electrodes and products that need to dampen sound, vibration and shock energy.

More on This Story

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• Engineers promise battery boost 15 NOVEMBER 2011, TECHNOLOGY
• UK invests in graphene technology 03 OCTOBER 2011, SCIENCE & ENVIRONMENT
• Tiny wires are big news for chips 10 FEBRUARY 2011, SCIENCE & ENVIRONMENT

Pastos Grandes, Lithium Brine Project, Bolivia

http://www.newworldresource.com/s/PastosGrandes.asp

Introduction

The Pastos Grandes project is located in the Sud Lipez province within the Department of Potosi, Bolivia, at an elevation of approximately 4,200 metres. The Pastos Grandes salar is part of the Bolivian Altiplano which is host to many alkaline and saline lakes and salars. Salars are composed of brines and salts rich in many minerals including lithium, potassium and boron. Bolivia is known to host the world's largest undeveloped lithium brine resource.

The Pastos Grandes salar is approximately 120 km2 and is located in a basin surrounded predominantly by mountainous terrain with intermittent rivers and thermal springs that discharge waters into a central lake. New World's total land position at Pastos Grandes is 75.12 km2, which represents approximately 62% of the entire Pastos Grandes salar. The area is accessible via numerous roads, with services available at the nearby town of Uyuni, 161 kilometres to the northeast. This town of approximately 21,400 people is an important transport hub, accessed via a network of packed dirt roads, or by commercial airport.

Geological Setting

Pastos Grandes is one of some 200 alkaline, saline lakes and salars in the area. It covers approximately 120 square kilometres trending northwest-southeast, composed of a thick sequence of sediments with a late Miocene pyroclastic basement.

Chemical analysis of the brine show that Pastos Grandes fits the alkaline type salar based on the concentrations of (Na-Ca-SO4-Cl), with high concentrations of lithium (Li), boron (B), and potassium(K), average totaling: 1,033 parts per million (ppm), Li, 378 ppm B, 7,766 ppm K.

The size of other major brine deposits range globally from 200 million to 1.3 billion metric tons with grades ranging from 0.015% to 0.125% lithium.

Pastos Grandes as seen from space. Note the central
lake and several streams, photo courtesy of NASA
click to enlarge

Project Exploration

The Company commissioned Dr. Teresita Kullberg to evaluate historical Pastos Grande brine samples and to compare the results to known lithium brine deposits of South America. Dr. Kullberg holds a PhD in Inorganic/Physical Chemistry and has extensive background in lithium chemistry, having worked for FMC Lithium and Chemetall Foote Corporation for a total of 26 years. Her experience ranges from laboratory research and development to pilot plant to production. She worked directly on the Atacama Salar of Chile through Chemetall Foote's subsidiary company Sociedad Chilena de Litio (SCL).

Excerpt from the Report entitled, 'Salar de Pastos Grandes -- Evaluation of Brine Samples' dated April 12, 2009;
"Preliminary conclusion from the data shows that the low Mg/Li ratio of 2.2 in the Pastos Grandes brine is very promising for a viable, profitable and economical Li recovery. Its brine composition mix with Li content > 1,000 ppm is competitive against the currently processed brines in Chile and Argentina. Additional investigation of this valuable lithium and potassium resource is recommended."

Historical brine chemical data of Pastos Grandes*

* The accuracy and validity of data were reviewed as received without other assumptions.
Li = lithium, K = potassium, Mg = Magnesium, Ca = Calcium, SO4 = sulphate, ppm = parts per million

As a quick estimate for assessing the feasibility of extraction, higher K/Mg and SO4/Mg ratios enhance the potash recovery from the preferred production method utilizing solar evaporation ponds. Moreover, lower Mg/Li and SO₄/Li ratios facilitate lithium recovery.

Below is a table comparing the historical brine samples of Pastos Grandes to other brine deposits in production in South America:

*Source: Salar de Rincon, Summary Report by Pedro Pavlovic

In conclusion the report states:

"The Salar de Pastos Grandes represents brine of excellent quality for lithium and potassium recovery. While it is much smaller in size compared with the Salar de Uyuni, its composition mixture of Li, Mg, Ca, K, SO4, may be easier to process economically. The Mg/Li ratio of 2.2 is less than the Atacama ratio of 6.4. Additional studies are recommended for the Salar de Pastos Grandes."

The historical results and the work that generated them pre-date the enactment of NI 43-101, and accordingly may not meet the requirements of the policy.

During 2009, the Company completed a brine sampling program to expand and confirm the historical data. The Company mobilized a highly experienced brine sampling team that collected brine and water samples on a modified grid covering the entire Pastos Grandes salar. The results are consistent with historical sampling conducted by the US Geologica Survey and the University of La Paz and continue to return significant lithium values and consistently low magnesium to lithium ratios.

Current Exploration Program

New World began a 1,500 metre drill program on the Pastos Grandes project. The drill program is over 50 percent complete and has delivered strong lithium content results. An abnormally severe rainy season has hampered the efficiency of the program; however, management continues to be encouraged with the high grade lithium and overall chemistry of the salar.

The drill program consisted of an initial pilot hole at each site to identify the depth and thicknesses of the aquifers present, followed by the drilling of a cluster of holes within a radius of approximately 15 metres from the pilot hole. Each hole within the grouping independently tested one of the aquifers as identified by the pilot hole. Four out of the six drill sites completed thus far have returned excellent lithium grades and attractively low magnesium to lithium ratios and sulphate to lithium ratios.

Pastos Grandes Current Drill Program Results

m = metres, ppm = parts per million
(1) Released - August 24, 2011
*Previously released - January 18, 2011

Subsequent to the aquifer identification drilling program, several sites will be selected for hydrologic assessment. This process will involve completing a series of monitoring wells around each pump well. Controlled pumping will be carried out within the centrally located pump hole, and the monitoring wells will determine the drawdown rates for each aquifer. This data is a portion of an ongoing comprehensive hydrological assessment of the Pastos Grandes aquifer system and will be essential as the Company develops its resource estimate. The hydrological assessment implementation and guidelines are under the direction of Dr. Richard Martin. Dr. Martin joined the Company as a consultant in February 2011 and holds a PhD in Hydrogeology. He is highly regarded as an expert in the field of solution mining and exploration.

Drilling is currently on hold while the next phase of work is being planned. The Company has also completed the expansion and construction of the onsite laboratory, offices and accommodations.

Agreement

In February 2009, the Company through a wholly owned subsidiary, New World Resource Bolivia S.A. ("New World Bolivia") signed a joint venture agreement (the "Agreement") with Gonzalo Miranda Salles and Mar�a Elena Gumucio Salles (together, "Salles") whereby the Company was granted the option to acquire a 99% interest in the concession holding within the Pastos Grandes salars. The remaining 1% interest in the project will be held by Salles as a free carried interest, although Salles's share of the net proceeds from production may be purchased by New World Bolivia at any time for US$250,000. The Agreement does not provide for any minimum work commitment, and will have a term of 20 years.

In October 2009, the Company through New World Bolivia, signed a joint venture agreement with Mr. Alberto Sivila whereby the Company was granted the option to acquire a 97% free carried interest of the concession holding within the Pastos Grandes salars. The remaining 3% interest in the project will be held by Mr. Sivila. At any time during the term of the joint venture agreement, US$500,000 can be paid to acquire an additional 2% interest in the joint venture. The joint venture agreement does not provide for any minimum work commitments, and will have a term of 15 years.

Effective May 1, 2010, the Company entered into a joint venture agreement with Kellguani whereby the Company was granted the option to acquire a 99% interest in Kellguani's 711 hectares within the Pastos Grandes salars. The agreement stipulates that Kellguani will have exclusive rights to the exploitation of the Ulexite within the 711 hectares. The joint venture agreement does not provide for any minimum work commitments, and will have a term of 20 years.

http://issuu.com/apella/docs/resource_world_vanadium_article-march_2011

http://www.proactiveinvestors.com/companies/news/25481/lithium-americas-3d-brine-model-confirms-size-capacity-of-cauchari-olaroz-resource-25481.html

Lithium Americas
www.lithiumamericas.com

Lithium Americas (TSX: LAC) has identified the 3rd largest known lithium brine resource in the world, and the results of a National Instrument 43-101 compliant Preliminary Economic Assessment identify that the Company's flagship property in Argentina has the potential to become one of the lowest cost lithium operations in the world. Mitsubishi Corporation and Magna International are strategic shareholders in the Company, in addition to both having off-take arrangements with Lithium Americas.

Full Lithium Americas profile here

inShare10

Lithium Americas 3D brine model confirms size, capacity of Cauchari-Olaroz resource

Mon 3:38 pm by Deborah Sterescu

Lithium Americas Corp. (TSE:LAC) (OTCQX:LHMAF) said Monday it has completed a 3D brine numerical model, used to simulate brine extraction from its Cauchari-Olaroz lithium-potash project in Argentina, which confirmed the size and production capacity of the resource.

The model allows the prediction of brine flow within the salar, or salt lake, as well as of the mine life, the lithium grade depletion over time and reserves.

The company said the modeling is supported by geological, hydrogeological and geochemical data collected through field programs at the site.

"A 3D brine numerical model is the ultimate tool to fine tune the mine plan in a brine development resource," said president and CEO, Dr. Waldo A. Perez.

"The model has also supported many of the critical assumptions in our Preliminary Economic Assessment (PEA) including the size, quality and estimated productive life of the Cauchari-Olaroz resource estimate – one of the largest lithium brine resource in the world.

"We are very pleased that the model also indicates that due to the exceptional geological characteristics of our salar, we are expected to require approximately 50% of the production wells originally estimated in the PEA to put phase 1 of the project into production."

Results of the model will be displayed at the company’s booth at the Prospectors and Developers Association of Canada Convention (PDAC) in Toronto, Ontario.

"We continue to add value to our project and to demonstrate the technical capability of our team. We expect to deliver the definitive Feasibility Study with reserves and a mine plan in Q2 2012," added Perez.

The company's Cauchari-Olaroz lithium project comprises a significant portion of two adjacent Argentinean salt lakes, Cauchari and Olaroz, covering 82,498 hectares located in the "Lithium Triangle" region of South America.

Cauchari-Olaroz is considered the third-largest deposit of lithium in the world. The property has a total lithium and potash resource of 8.0 million tonnes and 25.4 million tonnes, respectively.

Major automotive players Mitsubishi Corp and Magna International are shareholders of the company, in addition to them both having off-take arrangements with Lithium Americas.

In late 2011, Mackie Research said that the company was "on track to becoming a leading player in the lithium market".

Indeed, an April 2011 preliminary economic assessment (PEA) completed by ARA Worley Parsons defined an operation with an eventual operating capacity of 40,000 tonnes of lithium carbonate per year, having an operating cost of $1,434 per tonne - considered to be among the most competitive costs of any lithium operation in the world.

Looking forward, Lithium Americas said the planned milestones for this year include an NI 43-101 reserves estimation calculated by AquaResource Inc. in the first quarter of 2012, which will include the 3D model reported today.

The 3D model was developed by AquaResource, with the involvement of Dr. Mark King, the Independent Qualified Person for Lithium Americas.

The model included additional data collected since the previous resource estimate filed in December 2010, including geology, hydraulic testing and brine results from five pumping well arrays and four sets of salt lake boundary tests, as well as a water balance analysis, completed in 2011.

The upcoming reserve estimate will be derived from the simulation of a conceptual production well system. The model predicts that the grade of the pumped brine will remain above 600 milligrams per litre lithium for a period of at least 50 years.

The model also shows that an annual production rate of 40,000 tonnes of lithium carbonate can be achieved over a period of 40 years, without extracting brine from outside of the property boundary. The predicted duration for which it can maintain a production rate of 40,000 tonnes of lithium carbonate per year within the model exceeds 50 years, the company added.

Using data from the upcoming reserves study, ARA WorleyParsons is expected to deliver a definitive feasibility study in the second calendar quarter of 2012.

After the feasibility study, Lithium Americas expects to start detailed engineering in the third quarter, which is expected to be complete in nine to 12 months.

During the second half of the year, the company also expects the approval of an environmental impact statement - a type of permit necessary to begin construction and mining at Cauchari-Olaroz.

Other near-term milestones include the completion of a certification and qualification process for its battery-grade lithium carbonate, the re-assembling of a pilot plant at the project, and the closing of financing and off-take agreements with strategic parties, Lithium Americas said.

February 16, 2012

BASF Acquires NiMH Battery Producer

http://www.powerpulse.net/story.php?src=r4;storyID=25318

BASF has acquired Ovonic Battery Co., a wholly owned subsidiary of Energy Conversion Devices Inc.. No financial details were provided.

Ovonic’s principal activities have been licensing its advanced battery technologies - including nickel-metal-hydride (NiMH) and lithium-ion (Li-ion) technologies – participating in joint development programs to support application of advanced battery technologies and and manufacturing mixed-metal hydroxide cathode materials for sale to its licensees for use in battery production. Ovonic has developed NiMH rechargeable battery technology that is used globally in many hybrid-electric vehicles.

Ovonic will be managed under BASF’s new Battery Materials global business unit, which was launched January 1st. The single operating unit will be managed by BASF’s Catalysts division, based in Iselin, New Jersey. In addition to BASF’s current activities in electrolyte formulations and Li-ion cathode materials development, it said it is exploring next-generation battery materials concepts, including lithium-sulfur technologies. It is now in early stage development with partner Sion Power, in which BASF recently invested $50 million to take an equity ownership stake.

"We are very pleased to join BASF’s Battery Materials business," said Michael Fetcenko, president of Ovonic Battery Co. "BASF’s expertise in materials science and processing technology is a tremendous resource and these synergies will accelerate Ovonic’s development of advanced NiMH solutions for consumer, vehicle and smart grid energy storage."

March 1, 2012
http://ir.a123systems.com/releasedetail.cfm?ReleaseID=653121

A123 Systems to Supply Lithium Ion Battery Packs to Tata Motors for Hybrid Electric Transit Busses and Other Commercial Vehicles

A123's Advanced Nanophosphate Battery Systems Designed to Provide Tata With a Cost-Effective Solution for Meeting Performance, Safety and Durability Requirements

WALTHAM, Mass., March 1, 2012 (GLOBE NEWSWIRE) -- A123 Systems (Nasdaq:AONE), a developer and manufacturer of advanced Nanophosphate® lithium iron phosphate batteries and systems, announced today that it will supply complete lithium ion battery packs to Tata Motors, India's largest automaker, for Tata's hybrid electric systems for commercial vehicle applications. A123's highly scalable battery packs are designed to fit into multiple powertrain architectures that can be implemented into a wide variety of commercial vehicles, providing Tata with a cost-effective solution for meeting its performance, range and durability requirements.

"We consider hybridization to be an integral component of Tata Motor's overall strategy, and hybridization of our commercial vehicles is particularly important to our global customers for reducing the emissions and increasing fuel efficiency of their fleets," said Dr. Timothy Leverton, Head - Advanced and Product Engineering at Tata Motors. "A123 Systems' core lithium ion technology has a proven track record of success in the hybrid truck and bus segment, which we believe represents a very significant market opportunity. In addition, the modularity of A123's pack design enables us to develop a uniform hybrid powertrain architecture that can be deployed across multiple vehicle platforms."

Initially expected to be deployed on city transit buses during the second half of 2012, A123's lithium iron phosphate battery packs will be built using the company's prismatic cell technology, which offers high power capabilities, increased usable energy over a wide state-of-charge (SOC) range, excellent safety and long cycle and calendar life. A123 will deliver complete systems that include robust battery management electronics, and the compact form factor of the prismatic cells enables A123 to design highly-scalable battery packs that are intended to seamlessly configure to Tata's hybrid electric powertrain architecture.

"The addition of Tata Motors to our growing portfolio of blue-chip customers reinforces our position as the leading provider of lithium ion battery technology for the truck and bus segment," said Jason Forcier, vice president of the Automotive Solutions Group at A123. "We believe that this announcement further validates the performance attributes of our Nanophosphate lithium iron phosphate technology and underscores our systems integration expertise. A123 understands the value proposition for commercial fleet hybridization, and we believe we can help Tata cost-effectively expand its portfolio of hybrid electric vehicle offerings to allow its customers to take advantage of the long-term benefits of fleet electrification."

About A123 Systems

A123 Systems, Inc. (Nasdaq:AONE) is a leading developer and manufacturer of advanced lithium ion batteries and energy storage systems for transportation, electric grid and commercial applications. The company's proprietary Nanophosphate® lithium iron phosphate technology is built on novel nanoscale materials initially developed at the Massachusetts Institute of Technology and is designed to deliver high power and energy density, increased safety and extended life. A123 leverages breakthrough technology, high-quality manufacturing and expert systems integration capabilities to deliver innovative solutions that enable customers to bring next-generation products to market. For additional information please visit www.a123systems.com.

The A123 Systems, Inc. logo is available at http://www.globenewswire.com/newsroom/prs/?pkgid=6600

Safe Harbor Disclosure

This press release includes forward-looking statements within the meaning of the Private Securities Litigation Reform Act of 1995 that are subject to risks, uncertainties and other factors, including statements with respect to the expected launch date of Tata's hybrid electric commercial vehicles, the anticipated benefits and features of hybridization, Tata's ability to develop and deploy a uniform hybrid powertrain architecture across multiple vehicle platforms, the ability of A123's pack design to integrate with Tata's powertrain architecture, the expected demand for battery modules to be supplied to Tata, and the market for hybrid electric energy transportation in heavy-duty and commercial transportation applications . Among the factors that could cause actual results to differ materially from those indicated by such forward-looking statements are: delays in customer and market demand for and adoption of Tata's hybrid electric commercial vehicles, delays in the development and delivery of A123's battery pack products, adverse economic conditions in general and adverse economic conditions specifically affecting the markets in which A123 and Tata operate and other risks detailed in A123 Systems' 10-Q for the quarter ended September 30, 2011 and other publicly available filings with the Securities and Exchange Commission. All forward-looking statements reflect A123's expectations only as of the date of this release and should not be relied upon as reflecting A123's views, expectations or beliefs at any date subsequent to the date of this release.

A123 Systems PR Contact:
A123 Systems
Dan Borgasano
617-972-3471
dborgasano @ a123systems.com

A123 Systems IR Contact:                
ICR, LLC
Garo Toomajanian
617-972-3450
ir @ a123systems.com   

Edelman
Courtney Kessler
212-277-3720
courtney.kessler @ edelman.com

March 1, 2012
http://ir.a123systems.com/releasedetail.cfm?ReleaseID=653121

A123 Systems to Supply Lithium Ion Battery Packs to Tata Motors for Hybrid Electric Transit Busses and Other Commercial Vehicles

A123's Advanced Nanophosphate Battery Systems Designed to Provide Tata With a Cost-Effective Solution for Meeting Performance, Safety and Durability Requirements

WALTHAM, Mass., March 1, 2012 (GLOBE NEWSWIRE) -- A123 Systems (Nasdaq:AONE), a developer and manufacturer of advanced Nanophosphate® lithium iron phosphate batteries and systems, announced today that it will supply complete lithium ion battery packs to Tata Motors, India's largest automaker, for Tata's hybrid electric systems for commercial vehicle applications. A123's highly scalable battery packs are designed to fit into multiple powertrain architectures that can be implemented into a wide variety of commercial vehicles, providing Tata with a cost-effective solution for meeting its performance, range and durability requirements.

"We consider hybridization to be an integral component of Tata Motor's overall strategy, and hybridization of our commercial vehicles is particularly important to our global customers for reducing the emissions and increasing fuel efficiency of their fleets," said Dr. Timothy Leverton, Head - Advanced and Product Engineering at Tata Motors. "A123 Systems' core lithium ion technology has a proven track record of success in the hybrid truck and bus segment, which we believe represents a very significant market opportunity. In addition, the modularity of A123's pack design enables us to develop a uniform hybrid powertrain architecture that can be deployed across multiple vehicle platforms."

Initially expected to be deployed on city transit buses during the second half of 2012, A123's lithium iron phosphate battery packs will be built using the company's prismatic cell technology, which offers high power capabilities, increased usable energy over a wide state-of-charge (SOC) range, excellent safety and long cycle and calendar life. A123 will deliver complete systems that include robust battery management electronics, and the compact form factor of the prismatic cells enables A123 to design highly-scalable battery packs that are intended to seamlessly configure to Tata's hybrid electric powertrain architecture.

"The addition of Tata Motors to our growing portfolio of blue-chip customers reinforces our position as the leading provider of lithium ion battery technology for the truck and bus segment," said Jason Forcier, vice president of the Automotive Solutions Group at A123. "We believe that this announcement further validates the performance attributes of our Nanophosphate lithium iron phosphate technology and underscores our systems integration expertise. A123 understands the value proposition for commercial fleet hybridization, and we believe we can help Tata cost-effectively expand its portfolio of hybrid electric vehicle offerings to allow its customers to take advantage of the long-term benefits of fleet electrification."

About A123 Systems

A123 Systems, Inc. (Nasdaq:AONE) is a leading developer and manufacturer of advanced lithium ion batteries and energy storage systems for transportation, electric grid and commercial applications. The company's proprietary Nanophosphate® lithium iron phosphate technology is built on novel nanoscale materials initially developed at the Massachusetts Institute of Technology and is designed to deliver high power and energy density, increased safety and extended life. A123 leverages breakthrough technology, high-quality manufacturing and expert systems integration capabilities to deliver innovative solutions that enable customers to bring next-generation products to market. For additional information please visit www.a123systems.com.

The A123 Systems, Inc. logo is available at http://www.globenewswire.com/newsroom/prs/?pkgid=6600

Safe Harbor Disclosure

This press release includes forward-looking statements within the meaning of the Private Securities Litigation Reform Act of 1995 that are subject to risks, uncertainties and other factors, including statements with respect to the expected launch date of Tata's hybrid electric commercial vehicles, the anticipated benefits and features of hybridization, Tata's ability to develop and deploy a uniform hybrid powertrain architecture across multiple vehicle platforms, the ability of A123's pack design to integrate with Tata's powertrain architecture, the expected demand for battery modules to be supplied to Tata, and the market for hybrid electric energy transportation in heavy-duty and commercial transportation applications . Among the factors that could cause actual results to differ materially from those indicated by such forward-looking statements are: delays in customer and market demand for and adoption of Tata's hybrid electric commercial vehicles, delays in the development and delivery of A123's battery pack products, adverse economic conditions in general and adverse economic conditions specifically affecting the markets in which A123 and Tata operate and other risks detailed in A123 Systems' 10-Q for the quarter ended September 30, 2011 and other publicly available filings with the Securities and Exchange Commission. All forward-looking statements reflect A123's expectations only as of the date of this release and should not be relied upon as reflecting A123's views, expectations or beliefs at any date subsequent to the date of this release.

A123 Systems PR Contact:
A123 Systems
Dan Borgasano
617-972-3471
dborgasano @ a123systems.com

A123 Systems IR Contact:                
ICR, LLC
Garo Toomajanian
617-972-3450
ir @ a123systems.com   

Edelman
Courtney Kessler
212-277-3720
courtney.kessler @ edelman.com

http://www.treehugger.com/clean-technology/world-record-energy-density-rechargeable-lithium-ion-batteries.html

Breakthrough World Record Energy Density For Rechargeable Lithium-Ion Battery

John Laumer
Technology / Clean Technology
March 1, 2012

© Envia Systems

You'll find more than one post here on Treehugger describing a 'lithium battery breakthrough.' Given that many non-hydrocarbon based energy breakthroughs we wrote about were destined to become fall-throughs, a healthy amount of skepticism is always appropriate when you see a headline like the above.

Successful new technologies often start out small.
Let's frame the 400Wh/kg breakthrough announcement with an analogy or two.

Four years ago I'd never have imagined that I'd own a cheap, light, highly-effective standup vacuum cleaner that runs on one small lithium battery. I have one of those now and it's amazing.

Anyone remember how sucky laptops were back in the early 1990s? PC magazines had ongoing debates as to whether laptops should be called "transportables" because they were so hot and heavy no one wanted one on their lap. Twenty years later, few consumers buy "desktops" anymore and laptop makers are tripping over themselves to emulate the super-thin Apple design -- a design enabled specifically because battery power density, form, and cost became favorable! (The choice of thin, aircraft grade aluminum shell by Apple is the other reason the design works out so well.)

The Holy Grail of Electric Vehicles: High battery power density and low OEM manufacturing cost
Will the Chevy Volt turn out, Apple-like, to have the energy storage system other car makers want to copy? Perhaps. Not giving it any odds, but the just-announced high power density lithium battery cell by Envia Systems looks like it has the potential to make Republican bailout-whiners and astroturf Volt-mockers eat their words.

From the press release of General Motors.

DETROIT -- General Motors Ventures LLC invested $7 million in Newark, Calif.-based Envia Systems to provide GM’s battery engineering team with access to advanced lithium-ion cathode technology that delivers higher cell energy density and lower cost. In a separate agreement, GM has secured the right to use Envia’s advanced cathode material for future GM electrically driven vehicles.

“Skeptics have suggested it would probably be many years before lithium-ion batteries with significantly lower cost and higher capability are available, potentially limiting sales of electric vehicles for the foreseeable future,” said Jon Lauckner, president of GM Ventures. “In fact, our announcement today demonstrates that major improvements are already on the horizon.”

Other participating investors in Envia are Asahi Kasei and Asahi Glass; as well as current investors Bay Partners, Redpoint and Panagea Ventures. The funding of the investor group totaled $17 million.

“With our high-capacity manganese rich cathode material, Envia is addressing two key issues in the next-generation battery cells – higher capability and lower cost,” said Atul Kapadia, founding investor, chairman and CEO of Envia Systems. “The investments announced today from GM and the two new strategic investors, demonstrate the excitement around our technology, as well as the importance of the challenge.

Outstanding issues and questions.
Looks like Envia makes their cells in China. Could that be in-sourced at the insistence of a major customer?

Is the lithium battery recyclable? It's already fairly obvious that Envia has made their cells intrinsically safe (see below).

© Envia Systems

By isolating and insulating so effectively, do the lithium salts in the electrolyte become more difficult to liberate for reclamation? Which is more important: recyclability or fire safety under crash conditions? How can journalists get voters and politicians to stop thinking of each such variable in isolation and think instead about design tradeoffs?

© Envia Systems

Can members of the US Congress no longer invest in such ventures, after making laws that affect them ...really?

FOR IMMEDIATE RELEASE

3M Invests in Novel Silicon Anode for Lithium Ion Batteries

3M Research to Pioneer the Future; Company Expands Manufacturing

3M has a number of product solutions and a broad based technology portfolio targeting lithium ion batteries including 3M(TM) Battery Anode, 3M(TM) Battery Cathode and 3M(TM) Battery Electrolyte.  

ST. PAUL, Minn. – March 15, 2012 – 3M, the leading United States (U.S.) battery materials supplier, is investing in research and manufacturing of novel Silicon (Si) based 3M anode materials. The technology enables advanced batteries for reliable power that is required to keep up with the global increase of mobile societies and electric vehicles.

3M was recently granted another U.S. patent, 8,071,238 for its Silicon anode compositions that can increase cell capacity by over 40 percent when matched with high-energy battery cathodes. The company has invested resources and expertise toward commercialization of battery technology for the past 15 years.

3M’s investments into the high-energy metal based anode for lithium ion batteries include matching a recent U.S. Department of Energy (DOE) grant for $4.6 million as part of efforts to build more energy-efficient vehicles. The research will help to develop and integrate new cell materials that will make a transformative change in energy density and in cost in lithium ion batteries used in electric vehicles. Especially critical to the project success is 3M’s Si based anode material. The 3M investment in research and development includes putting in 3M’s best battery materials technology for cathode, anode and battery electrolyte additives into the project.

“3M has a proven track record of being an innovator in battery materials, and we are committed to supporting the growing U.S. and global lithium ion battery industry,” said Chris Milker, business development manager for 3M Electronic Markets Materials Division. “Our investment into research and development, coupled with our experience and portfolio of more than 40 core technologies – including nanotechnology, adhesives, precision coating, fluoromaterials – give us the tools and confidence in our ability to develop next-generation materials for better cells.”

The new research efforts deepen 3M’s rich history of sustainability and in making a global impact through innovation. The research expands upon the company’s long-standing initiatives in the battery market to commercialize battery technology for electric vehicles and consumer electronics.

In addition to its investment in robust research and development, 3M recently completed the first phase of Silicon anode manufacturing capacity expansion in early 2012 in its Cottage Grove, Minn., facility. The expansion included the installation of large-scale manufacturing equipment specialized to 3M and its proprietary anode chemistry. The U.S.-based facility will provide Si anode material to 3M’s global battery customers.

3M is well ahead of its time in pioneering research for lithium ion battery materials, which began in the 1990s for early auto market applications. Lithium ion batteries are a common source of power for laptop computers and electronic handheld devices and emerged as a power source for battery powered hand tools. In addition, 3M lithium ion technology is emerging for transport applications including the hybrid vehicles market. Because of the company’s consistent investment into the industry, 3M has uniquely developed three critical battery materials used in lithium ion batteries. These include silicon anode chemistry, novel cathode technologies (nickel, manganese, cobalt) and electrolyte (salts and additives). 

Besides battery cathode, anode and electrolyte technologies, 3M also offers tapes and adhesives for assembly of consumer electronics and fluids to manage heat during the manufacture of electronic devices. Using its broad portfolio of battery materials, 3M has the unique capability to integrate these materials to solve customers’ battery problems.

For more information about 3M battery materials, visit www.3m.com/batterymaterials

About 3M

3M captures the spark of new ideas and transforms them into thousands of ingenious products. Our culture of creative collaboration inspires a never-ending stream of powerful technologies that make life better. 3M is the innovation company that never stops inventing. With $30 billion in sales, 3M employs 84,000 people worldwide and has operations in more than 65 countries. For more information, visit www.3M.com or follow @3MNews on Twitter.

# # #

Contacts:

Colleen Harris

3M

651-733-1566

Stephani Simon

Orange Communications

(612) 677-2021

ssimon @ orange77.com

From:

3M Public Relations and Corporate Communications

3M Center, Building 225-1S-15

St. Paul, MN 55144-1000

http://www.idtechex.com/electric-vehicles-usa-12

ELECTRIC VEHICLES LAND, SEA & AIR USA 2012

The only event covering all forms of EVs and their parts for land, sea and air

27-28 March, 2012

DoubleTree Hilton Hotel

2050 Gateway Place

San Jose, CA 95110

USA

Most major breakthroughs in design and technology appear in other electric vehicles before they appear in cars. Whether by land, sea or air, electric vehicles need motors, controls, batteries and often supercapacitors plus advanced structural composites. Just over 1.6 million electric cars will be sold worldwide this year, including hybrids. But the total number of all types of EVs sold will be much greater - reaching over 39 million. In terms of units sold, that will mostly be e-bikes and vehicles for the disabled, but industrial/commercial vehicles will have four times their market value. Serious players must look at all of this - and IDTechEx now makes this possible.

Toyota Motor, Mr Greg Glander, Government Sales & Advanced Technology Vehicle Manager

Tuesday March 27, 2012
10:45 - 11:10 "Toyota Sustainable Mobility - Toyota's 2012 line-up of advanced technology vehicles"
Toyota's 2012 line-up of advanced technology vehicles

LiTHIUM BALANCE, Mr Tunji Adebusuyi, Research & Development