Batteries News

Engineers from the Korea Atomic Energy Research Institute (KAERI) say they have developed a new and safer lithium-ion battery technology. Lithium-ion is one of the most widely-used battery Samsung sb-lsm80 Battery technologies for most gadgets today because it has the capacity to store a lot of energy and last many charge-recharge cycles. Unfortunately, it's not without fault - lithium-ion batteries have been known to be inclined to explode upon exposure to heat Canon NB-2L battery or upon impact. Telecoms Korea reports that KAERI engineers have developed a special kind of "separator" that protects the lithium-ion battery from impact and extreme external heat.

Separators in lithium-ion batteries conduct lithium ions from the positive to Sony NP-F330 Battery the negative side of the battery. Normal separators inconventional lithium-ion batteries are only composed of porous polyethylene. The special separator, OlympusLI-12B battery however, is made from a mixture of polyethylene, nano-alumina and flourine-based resin, which is then subjected to radiation. The developers claim the new separator has the capacity to remove existing lithium-ion battery Sanyo DB-L20 Battery limitations. A press release from KAERI says, "Tests showed that the new separator maintains its ability to act as an electric insulator even if subject to heat of 150 degrees Celsius and considerable outside impact." When this new technology will be Fujifilm NP-40 Battery commercialized is still unknown as the developers have only just filed two patents for it.

A Switzerland-based company called ReVolt will soon be releasing a button cell battery for hearing aids in the market next year. But unlike other products available in the market, ReVolt's battery uses the zinc-air battery technology developed by Norwegian research institute SINTEF. ReVolt has raised 24 million Euros Sony NP-FH50 Battery in funding for the development of the technology, with the release of zinc-air based batteries for cell phones and electric bikes expected within a few years. ReVolt claims its technology overcomes the biggest hurdle in developing rechargeable zinc-air batteries - the inability to last as many charge-discharge cycles as lithium ion batteries ReVolt's battery can reportedly store three times more energy than lithium-ion by volume, and could incur just half the costs. Current prototypes of Canon BP-511 Battery the zinc-air battery last more than a hundred charge-discharge cycles, and the products to be released are expected to last a couple of hundred cycles. The company is currently improving the technology to last 300 to 500 cycles to be more apt for development as cell phone and electric bike batteries. Besides what was already mentioned, ReVolt has also already started working on a fuel cell-like, zinc-air battery for electric vehicles.Read more…

According to recent estimations, by 2050 we may need twice as much energy as we have available today. The pernicious impact of fossil fuels and the looming shortage of the same have launched a recent acceleration in the search for an environmentally friendly and sustainable energy policy.

According to the International Energy Agency (IEA) we are on the right path and technological innovation is crucial. Today there are massive investments in cleantech, such as renewable energy, efficiency, and less-polluting technologies. Analysts expect this area Dell inspiron 6000 Battery to experience a real investment boom over the next 20 to 30 years.

The IMEC-SiN-AlGaN-GaN double heterostructure FET has demonstrated breakdown voltages up to 1,000 V.

A transition is underway

In the 20th century, when fossil fuel was the driver of a first industrial revolution, our economy was characterized Dell inspiron 1520 Lithium Ion laptop battery by lots of manual labor, big factories, and the production of material goods. We acted as if the resources of the world were unlimited. Nowadays we are confronted with the depletion of our resources, the limits imposed by fossil fuels, and climate change problems that force us to reconsider our energy consumption and switch to more environmentally conscious methods.

Currently, our economy is driven by technological innovation, improving the quality of our lives through immaterial goods such as services and content. Technological innovation will also prove to be the key in tackling the energy challenges, where the only way to go is a dramatic switch to renewable energy inspiron 1520 laptop battery pack combined with energy saving in all conceivable ways.

The electronics industry will play a prominent role in this transition. Technologies to generate renewable energy such as photovoltaic systems, non-food-based biofuels, wind energy, and hybrid cars Dell Inspiron 1100 Battery have gained the interest of established chip companies.

Technological solutions

However, the introduction of renewable energy Dell Inspiron 9300 Battery resources for electricity generation creates new additional challenges on the existing electricity network infrastructure:

How to face the increasing number of loads. How to integrate the various delocalized energy sources onto the same grid.How to face the fluctuations between different sources (think about wind farms). How to transport the electricity more efficiently. How to ensure a high reliability and a high stability of the electrical supply.

These challenges are pushing the Dell Inspiron 6400 Battery development of the “smart grid.” The smart-grid network will help enable efficient integration of renewable and traditional energy resources, managing electricity distribution as a function of the availability of the resources and on the needs of the user. The deployment of the smart grid, like most of the new energy-efficient technologies that will appear, will be driven by advances in power conversion systems and more particularly in power electronics components. The result would be improved efficiency and reliability of the energy supply and a reduction in energy consumption.

Apart from a change in behavior and a call for energy-saving improvements in houses and office buildings, technological solutions such as efficient intelligent sensor-based ICT (information and communication technology) systems, more-efficient power conversion, and solid-state lighting will contribute to limiting energy consumption.

The role of power electronics

Power electronics for generating and converting energy is covering a large range of applications ranging from power supplies for ICT, to motor drives, solar converters, or hybrid electrical vehicles. Today, more than 60% of electrical energy passes through Si! Improving the performance of power Dell Inspiron 630m Battery electronics systems appears more and more as a key lever to significant electrical power consumption reduction.

More-efficient, faster, and more-reliable solid-state devices capable of operating at high-voltage, higher current density, and high temperatures must be developed. It’s a very challenging story for semiconductor developers. Power electronics components are reaching the intrinsic limits of the Si material.

Further innovation and improvement of energy-generating devices will require the use of wide-bandgap semiconductors that allow the production of devices with higher breakdown voltage. Among those, the best candidates appear to be the III-nitride wide bandgap materials, as they offer a combination of high voltage and high electron velocity, which significantly reduce the switching and conduction losses, at high voltages.

These wide-bandgap semiconductors will be enablersfor newer cleaner technologies, such as in the hybrid automotive industry or solar converters. Indeed, although they only represent about 10% of the total semiconductor market, the power Dell Vostro1000 Battery electronics industry has a higher combined aggregate growth rate (>11%) than the total semiconductor industry (~7%).

But a new technology for power electronics will only gain market acceptance as replacement of existing technologies or as enabler of new technology when its cost is competitive with existing solutions. It is therefore of key importance to find materials and processes that offer an optimal mix of performance and cost. Gallium nitride (GaN) has proven to be such a material.

At Imec, we have demonstrated GaN-on-Si switching devices with a breakdown voltage above 1,000 V and an order of magnitude less conduction loss, as compared to best Si power electronic component available. Higher switching frequency also allows us to dramatically reduce the size of the power converters, opening extremely interesting perspectives in terms of higher integration of power electronics Dell Inspiron 8000 Battery. And, GaN has very promising cost-reduction perspectives.

Wide-bandgap semiconductors such as GaN are today being epitaxially grown on expensive and small-diameter substrates, such as sapphire and SiC. The use of Si (111) as a substrate for III-Nitride components offers not only a cheaper but also an excellent prospect for cost reduction through wafer diameter increase.

III-Nitrides are the sole wide-bandgap semiconductors that can be grown today on a 6-in. wafer diameter, with a very good perspective in a short time for larger wafer diameters. GaN growth on 200-mm silicon wafers has been demonstrated.

Last but not least, cost reduction in GaN-on-Si technology could be achieved by leveraging on the Si scale of economics, if processes inspiron 9300 laptop battery pack compatible with standard Si process flow are being developed. These are today the key drivers of Imec research on GaN-on-Si technology.

And recently, imec combined high-breakdown voltage with low on-resistance and obtained e-mode device operation by growing a GaN-on-Si double heterostructure FET architecture. e-mode operation is typically required in applications for safety reasons. These results hold the promise of a huge market opportunity for GaN-on-Si power devices.Read more…

One energy source that could serve as an option for devices which are expected to run continuously for years is nuclear batteries. Also called betavoltaics, nuclear batteries run by harvesting electrons from the natural decay of radioactive sources. The nuclear battery made by Widetronix can supposedly last up to 25 years because of its ability to withstand radioactive damage Acer Aspire 3610 Battery. The company has developed a silicon carbide semiconductor technology that comes in the form of a small chip. CEO Jonathan Greene says, "It is our professional opinion that the higher the efficiency, the lower the device cost, [and the] smaller the unit volume."

Current prototype of the device can merely generate nanowatts of power, and is far from being a source of energy for gadgets. Widetronix is planning to stack several chips together that results in a Acer Aspire 3020 battery able to generate 1 microwatt of power. According to LiveScience, the stack of chips will be able to power small devices, and the company is looking to develop one that could be used for devices implanted on the human body fo Acer BTP-AHD1 physicians to be able to monitor their patients. While Widetronix plans its first commercial release by 2011, the company continues its search for nuclear isotopes that could provide more power for its batteries in the future.