Aluminum Battery to Outpace Li-ion (Video)

A team of Stanford University researchers have developed a high-performance aluminum battery.Image: YouTube/Stanford University

A research team from Standford University has developed a high-performance aluminum battery.
Image: YouTube/Stanford University

Researchers have been attempting to make a commercially viable aluminum-ion battery for years. Now, a team from Stanford University may have developed just the thing to outpace widely used lithium-ion and alkaline batteries.

The new aluminum-ion battery demonstrates high performance, a fast charging time, long-lasting cycles, and is of low cost to produce.

“We have developed a rechargeable aluminum battery that may replace existing storage devices, such as alkaline batteries, which are bad for the environment, and lithium-ion batteries, which occasionally burst into flames,” said Hongjie Dai, a professor of chemistry at Stanford.

The researchers were able to achieve this novel battery by applying graphite as the cathode material.

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They hybrid supercapacitor can store large amounts of energy, recharge quickly, and lost for more than 10,000 recharge cycles.Image: UCLA

The hybrid supercapacitor can store large amounts of energy, recharge quickly, and last for more than 10,000 recharge cycles.
Image: UCLA

Researchers from UCLA’s California NanoSystems Institute (CNSI) have developed a new generation of supercapacitors that not only emphasizes the best inherent properties of the supercapacitor itself, but also combines it with some of the best qualities of batteries to make a new energy storage medium.

The new supercapacitor is paper-thin and has an extremely fast recharge time. Additionally, it can last more than 10,000 recharge cycles.

Researchers believe this new development will yield real-world potential to address energy issues and improve personal electronics.

“The microsupercapacitor is a new evolving configuration, a very small rechargeable power source with a much higher capacity than previous lithium thin-film microbatteries,” said Maher El-Kady, co-author of the study and postdoctoral scholar.

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dahn-researchThe electric car industry is on the rise, but battery performance for these vehicles is still not where it needs to be to implement wide-scale usage. To address this issue, researchers from Dalhousie University have produced a ternary blend of electrolyte additives to improve the performance of the li-ion cell.

An open access paper recently published in the Journal of The Electrochemical Society (JES) details a novel development in electrolyte additives that, once applied to the li-ion cell, demonstrate a very high charge-discharge capacity.

The team began their study by investigating the performance of NMC pouch cells and electrolytes with various sulfur or phosphorus electrolyte additives.

They concluded that the new additive will improve the life cycle performance of the li-ion battery, as well as improve upon its safety.

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From Packing Peanuts to Energy Storage

The Electrochemical Society’s Vilas Pol has developed a new process to turn simple packing peanuts into energy-storing battery components.

Pol, an associate professor at Purdue University and active member of ECS, has thoroughly succeeded in turning one person’s trash into another person’s high-tech treasure. He and his team from Purdue University have developed a system that turns the puffy packing peanuts into nanoparticles and microsheets perfect for rechargeable batteries. Pol’s new generation of battery could even outperform the ones we currently use.

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Using Silk in Next-Generation Batteries

The integration of silk into the lithium-ion battery allowed the battery to work for over 10,000 cycles with only a nine percent loss in stability.

The integration of silk into the lithium-ion battery allowed the battery to work for over 10,000 cycles with only a nine percent loss in stability.
Image: ACS Nano

The words “lithium-ion” and “battery” have become almost synonymous recently. While the li-ion battery is used in a multitude of applications, it still does not have a long life without a recharge.

Now, researchers have developed an environmentally friendly way to boost the performance of the li-ion battery by focusing on a material derived from silk.

In the li-ion battery, carbon is the key component for storage. In most situations, graphite takes that role – but it has limited energy capacity. In order to improve the performance of the li-ion battery, researchers looked to replace graphite with a material developed using a sustainable source.

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Funding Opportunity: Li Batteries

ATL-Logo_144_144_sNingde Amperex Technology Ltd. (ATL, China) is announcing a funding opportunity for researchers actively engaged in rechargeable lithium battery technologies. They are offering $100,000-$500,000 to selected projects addressing current problems associated with lithium metal anodes and proposing viable solutions for the commercialization of long-life, high-performance lithium metal secondary batteries for high energy density applications.

The steep demand for improved rechargeable batteries for use in consumer electronics and electric vehicles is driving the search for new battery electrode materials that will achieve higher energy densities. This funding opportunity seeks to develop scalable technologies for improving the performance of lithium metal anodes.

Please submit technical proposals along with a budget justification, confidentiality disclaimer and a cover page identifying the principle investigator, contact information, affiliations, project duration, total funding requested and submission date to Dr. KaiFu Zhong.

The deadline for submissions is July 31, 2015.

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ECS Battery Division Awards

Battery icon

The ECS Battery Division is now accepting award nominations.

Please help recognize outstanding contributions of The Electrochemical Society members to the science and technology of primary and secondary batteries and fuel cells through the Battery Division Awards Program.

Nominations are now being accepted for:

These annual awards have been established by the Division to encourage excellence in battery and fuel cell R&D, recognize promising young engineers and scientists and encourage their publication in the publications of the Electrochemical Society.

The deadline for nominations is March 30, 2015.

Before applying, please review the award rules and complete the appropriate form.

I strongly encourage you to submit your nominations. Thank you.

With my best regards,

Robert Kostecki
ECS Battery Division, Chair

Glass Coating for Li-S Battery

Researchers have investigated a strategy to prevent this “polysulfide shuttling” phenomenon by creating nano-sized sulfur particles, and coating them in silica (SiO2), otherwise known as glass.Image: Nanoscale

Researchers have investigated a strategy to prevent this “polysulfide shuttling” phenomenon by creating nano-sized sulfur particles, and coating them in silica (SiO2), otherwise known as glass.
Image: Nanoscale

Lithium-sulfur has been a hot topic in battery technology recently. Because of its ability to produce 10 times the amount of energy as a conventional battery, we’ve seen novel innovations such as the all solid state lithium-sulfur battery. Now, the li-sulfur battery is getting a glass coating to further improve its performance.

Researchers at the University of California, Riverside have applied a glass cage-like coating, along with graphene oxide, to the li-sulfur battery. This innovation was developed in order to overcome one of the major issues in commercializing the battery – polysulfides, which cause the battery’s capacity to decrease over its lifetime.

The cathode material traps the polysulfides in a very thin glass cage. Researchers used an organic precursor to construct the trapping barrier.

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Old Battery Type to Compete with Li-ion

When it comes to battery research and technology, people are constantly looking toward the lithium-ion battery to see the next big breakthrough. However, researchers at the chemical company BASF are showcasing and older battery type as a strong competitor against the li-ion.

BASF researchers are taking the nickel-metal hydride battery (NiMH) and giving it a boost to lead to cheaper electric cars. The assumption for electric car makers it that improvements in the lithium-ion battery will make cars cheaper and extend their driving range. While that may be true, the NiMH may also be able to do this with a little improvement.

The chemical company has already been able to double the amount of energy these old battery types can store, thus making them comparable to the lithium-ion. Researchers also state that there is still much room for improvement – with the potential to increase energy storage by an additional eight times.

Further, the batteries are set to cost roughly half as much as the cheapest lithium-ion battery.

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Paper-like Material to Boost Li-ion Batteries

The newly developed silicon nanofiber structure allow the battery to be cycled hundreds of times without significant degradation.Image: Nature Scientific Reports

The newly developed silicon nanofiber structure allows the battery to be cycled hundreds of times without significant degradation.
Image: Nature Scientific Reports

Electric cars and personal electronics may get the battery boost they need with this new development in lithium-ion batteries.

Researchers from the University of California, Riverside have created silicon nanofibers that are 100 times thinner than human hair, which will provide the potential to boost the amount of energy that can be delivered per unit weight of the batteries.

The research has been detailed in the paper “Towards Scalable Binderless Electrodes: Carbon Coated Silicon Nanofiber Paper via Mg Reduction of Electrospun SiO₂ Nanofibers.”

This from University of California, Riverside:

The nanofibers were produced using a technique known as electrospinning, whereby 20,000 to 40,000 volts are applied between a rotating drum and a nozzle, which emits a solution composed mainly of tetraethyl orthosilicate (TEOS), a chemical compound frequently used in the semiconductor industry. The nanofibers are then exposed to magnesium vapor to produce the sponge-like silicon fiber structure.

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