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Archive for the ‘Advanced Battery Technology’ Category

UPI.com, March 9, 2010

Nanotube filaments

A team of Massachusetts Institute of Technology scientists say they’ve discovered a phenomenon that might lead to a new way of producing electricity.

The researchers, led by Associate Professor Michael Strano, said their discovery of the phenomenon that causes waves of energy to shoot through carbon nanotubes — described as thermopower waves — is similar to flotsam being propelled along the ocean’s surface by waves.

The scientists said a thermal wave — a moving pulse of heat — traveling along a submicroscopic nanotube can drive electrons along with it, creating an electrical current.

Because it is such a new discovery, Strano said it’s difficult to predict what the practical applications will be. But he suggests it might enable new kinds of ultra-small electronic devices — for example, devices the size of grains of rice, or perhaps a sensor or treatment device that could be injected into the body.

In theory, he said, such devices could maintain their power indefinitely until used, unlike batteries nicwhose charge gradually diminishes as they remain unused.

The research that included doctoral student Wonjoon Choi is reported in the journal Nature Materials.

From the peswiki @ MIT, here’s how they describe it works:

Rechargable and disposable batteries use a chemical reaction to produce energy. The problem is that after many charges and discharges the battery loses capacity to the point where the user has to discard it.

However, capacitors contain energy as an electric field of charged particles created by two metal electrodes. Capacitors charge faster and last longer than normal batteries.

The problem is that storage capacity is proportional to the surface area of the battery’s electrodes, so even today’s most powerful capacitors hold 25 times less energy than similarly sized standard chemical batteries.

MIT researchers have solved this by covering the electrodes with millions of nanotubes, which are essentially tiny filaments. The nanotube filaments increase the surface area of the electrodes and allow the capacitor to store more energy.

The MIT capacitor thus combines the strength of today’s batteries with the longevity and speed of capacitors.

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DAVID TOW, Future Planet, January 16, 2010

By 2015 India and China will both have outstripped the US in energy consumption by a large margin. Cap and Trade carbon markets will have been established by major developed economies, including India and China, as the most effective way to limit carbon emissions and encourage investment in renewable energy, reforestation projects etc.

There will have been a significant shift by consumers and industry to renewable energy technologies- around 25%, powered primarily by the new generation adaptive wind and solar energy mega-plants, combined with the rapid depletion of the most easily accessible oil fields. Coal and gas will continue to play a major role at around 60% useage, with clean coal and gas technologies still very expensive. Nuclear technology will remain static at 10% and hydro at 5%.

Most new vehicles and local transport systems will utilise advanced battery or hydrogen electric power technology, which will continue to improve energy density outputs.

Efficiency and recycling savings of the order of 30% on today’s levels will be available from the application of smart adaptive technologies in power grids, communication, distribution and transport networks, manufacturing plants and consumer households. This will be particularly critical for the sustainability of cities across the planet. Cities will also play a critical role in not only supporting the energy needs of at least 60% of the planet’s population through solar, wind, water and waste energy capture but will feed excess capacity to the major power grids, providing a constant re-balancing of energy supply across the world.

By 2025 a global Cap and Trade regime will be mandatory and operational worldwide. Current oil sources will be largely exhausted but the remaining new fields will be exploited in the Arctic, Antarctic and deep ocean locations.  Renewable energy will account for 40% of useage, including baseload power generation. Solar and wind power will dominate in the form of huge desert solar and coastal and inland wind farms; but all alternate forms- wave, geothermal, secondary biomass, algael etc will begin to play a significant role.

Safer helium-cooled and fast breeder fourth generation modular nuclear power reactors will replace many of the older water-cooled and risk-prone plants, eventually  accounting for around 15% of energy production; with significant advances in the storage of existing waste in stable ceramic materials.

By 2035 global warming will reach a critical threshold with energy useage tripling from levels in 2015, despite conservation and efficiency advances. Renewables will account for 60% of the world’s power supply, nuclear 15% and fossils 25%. Technologies to convert CO2 to hydocarbon fuel together with more efficient recycling and sequestration, will allow coal and gas to continue to play a significant role.

By 2045-50 renewables will be at 75-80% levels, nuclear 12% and clean fossil fuels 10-15%. The first Hydrogen and Helium3 pilot fusion energy plants will be commissioned, with large-scale generators expected to come on stream in the latter part of the century, eventually reducing carbon emissions to close to zero.

However the above advances will still be insufficient to prevent the runaway effects of global warming. These long-term impacts will raise temperatures well beyond the additional two-three degrees centigrade critical limit.

Despite reduction in emissions by up to 85%, irreversible and chaotic feedback impacts on the global biosphere will be apparent. These will be triggered by massive releases of methane from permafrost and ocean deposits, fresh water flows from melting ice causing disruptions to ocean currents and weather patterns.

These will affect populations beyond the levels of ferocity of the recent Arctic freeze, causing chaos in the northern hemisphere and reaching into India and China and the droughts and heat waves of Africa, the Middle East and Australia.

The cycle of extreme weather events and rising oceans that threaten to destroy many major coastal cities will continue to increase, compounded by major loss of ecosystems, biodiversity and food capacity. This will force a major rethink of the management of energy and climate change as global catastrophe threatens.

Increasingly desperate measures will be canvassed and tested, including the design of major geo-engineering projects aimed at reducing the amount of sunlight reaching earth and reversal of the acidity of the oceans. These massive infrastructure projects would have potentially enormous ripple-on effects on all social, industrial and economic systems. They are eventually assessed to be largely ineffective, unpredictable and unsustainable.

As forecasts confirm that carbon levels in the atmosphere will remain high for the next 1,000 years, regardless of mitigating measures, priorities shift urgently to the need to minimise risk to life on a global scale, while protecting civilisation’s core infrastructure, social, knowledge and cultural assets.

Preserving the surviving natural ecosystem environment and the critical infrastructure of the built environment, particularly the Internet and Web, will now be vital. The sustainability of human life on planet Earth, in the face of overwhelming catastrophe, will be dependent to a critical degree on the power of the intelligent Web 4.0, combining human and artificial intelligence to manage food, water, energy and human resources.

Only the enormous problem-solving capacity of this human-engineered entity, will be capable of ensuring the continuing survival of civilisation as we know it.

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