ON 12 October 2000, the destroyer USS Cole hove into port at Aden in Yemen for routine refuelling. As the vessel took on fuel oil, a small boat drew alongside it. Suicide bombers inside the boat detonated a cache of explosives, blasting a 20-metre hole in the destroyer's hull and killing 17 of its crew. The attack was a stark reminder of the risks the crews of naval ships face when they are forced to put in at potentially unfriendly ports. Now some members of Congress believe they have a way to keep ships out of harm's way and prevent similar incidents happening in the future. A bill recently passed by the House of Representatives aims to make many more of the ships in the US naval fleet nuclear powered, including amphibious assault ships that carry troops into combat. The benefit will be two-fold, argue proponents of the bill. Rocketing oil prices make nuclear power an economic way of funding naval expeditions, and thanks to the slow burn of the highly enriched nuclear fuel in marine reactors, ships will have no need to pull into potentially hostile ports to refuel. However, critics claim the presence of a nuclear reactor on a ship would make it a terrorist target. "It beggars belief in these days of heightened terrorism alerts that people are seriously suggesting building nuclear-powered assault ships," says Ben Ayliffe, head of anti-nuclear campaigns at Greenpeace in the UK. The new bill represents an escalation of recent efforts to get the navy to use more nuclear fuel. The rising cost of oil means it is getting close to the point at which it will be more economic for the navy to use nuclear power, says Representative Roscoe Bartlett, a Maryland Republican, who backs the proposed measures. "A 2007 study by the navy on alternative energy for ship propulsion indicated that the break-even price for nuclear propulsion for amphibious ships was an oil price of $178 dollars per barrel. We're now creeping up to that number - oil hit a new record of $133 a barrel today," he said in a statement on 21 May. There is also the question of securing the military's energy supply, says Bartlett. Ninety-six per cent of the world's oil reserves are owned by countries other than the US. "Many of these countries, such as Saudi Arabia, Venezuela, Russia, Iran and Nigeria, are unstable and ambivalent or outright hostile to America and our allies," he says, pointing again to nuclear propulsion as the answer. "It offers greater power and unparalleled safety and operational endurance without the vulnerabilities of fossil fuel refuelling," he says. The move towards a navy that relies more heavily on nuclear power is also being driven by the increasing use of ever more powerful radar and radio links. These are turning ships into energy guzzling data-processing centres, said a report by the US Defense Science Board task force on energy strategy in February. In its report, entitled "More Fight, Less Fuel", the task force said that a major reason nuclear power is being seen as an option for surface ships is because not enough is being done to ensure electronics and radar systems are energy efficient. This is forcing the navy to look for new power sources to ensure ships have a steady supply during combat, it says. Congress upped the ante on the use of nuclear power across the fleet last year, when it passed the National Defense Authorization Act for 2008, an annual piece of legislation that tells the Pentagon how it should spend its budget. Under the act all future aircraft carriers, submarines and battle cruisers have to be built with a nuclear power system at their heart. The risk of a nuclear disaster does not necessarily increase significantly because such ships do not tend to get close to combat zones. But the National Defense Authorization Bill for 2009, which the Senate has still to pass, aims to shift the process up a gear by adding various types of amphibious assault ships to the list of those that must be powered by nuclear reactors in the future. "We're dedicated to ensuring that the future forces of the navy are not hampered by access to, or the cost of, fossil fuels," says Representative Gene Taylor, the Mississippi Democrat who chairs the House subcommittee on sea power and expeditionary forces, which drafted the relevant section of the bill. Amphibious ships come in various forms, from those that incorporate a dock for landing craft, to undersized aircraft carriers for helicopters and vertical take-off aircraft - or a mixture of both. The vessels' position in combat can also vary - from a "stand-off" over-the-horizon location to being moored to a pier in a combat zone. A US navy website confirms that such ships "are designed to get in harm's way".US considers nuclear-powered assault ships
Solar Cells Solar cells (as the name implies) are designed to convert (at least a portion of) available light into electrical energy. They do this without the use of either chemical reactions or moving parts. History By 1927 another metalÐsemiconductor-junction solar cell, in this case made of copper and the semiconductor copper oxide, had been demonstrated. By the 1930s both the selenium cell and the copper oxide cell were being employed in light-sensitive devices, such as photometers, for use in photography. These early solar cells, however, still had energy-conversion efficiencies of less than 1 percent. This impasse was finally overcome with the development of the silicon solar cell by Russell Ohl in 1941. In 1954, three other American researchers, G.L. Pearson, Daryl Chapin, and Calvin Fuller, demonstrated a silicon solar cell capable of a 6-percent energy-conversion efficiency when used in direct sunlight. By the late 1980s silicon cells, as well as those made of gallium arsenide, with efficiencies of more than 20 percent had been fabricated. In 1989 a concentrator solar cell, a type of device in which sunlight is concentrated onto the cell surface by means of lenses, achieved an efficiency of 37 percent due to the increased intensity of the collected energy. In general, solar cells of widely varying efficiencies and cost are now available. Structure The first of these three layers necessary for energy conversion in a solar cell is the top junction layer (made of N-type semiconductor ). The next layer in the structure is the core of the device; this is the absorber layer (the P-N junction). The last of the energy-conversion layers is the back junction layer (made of P-type semiconductor). As may be seen in the above diagram, there are two additional layers that must be present in a solar cell. These are the electrical contact layers. There must obviously be two such layers to allow electric current to flow out of and into the cell. The electrical contact layer on the face of the cell where light enters is generally present in some grid pattern and is composed of a good conductor such as a metal. The grid pattern does not cover the entire face of the cell since grid materials, though good electrical conductors, are generally not transparent to light. Hence, the grid pattern must be widely spaced to allow light to enter the solar cell but not to the extent that the electrical contact layer will have difficulty collecting the current produced by the cell. The back electrical contact layer has no such diametrically opposed restrictions. It need simply function as an electrical contact and thus covers the entire back surface of the cell structure. Because the back layer must be a very good electrical conductor, it is always made of metal. Operation Then with one term at zero these conditions (V = Voc / I = 0, V = 0 / I = Isc ) also represent zero power. As you might then expect, a combination of less than maximum current and voltage can be found that maximizes the power produced (called, not surprisingly, the "maximum power point"). Many BEAM designs (and, in particular, solar engines) attempt to stay at (or near) this point. The tricky part is building a design that can find the maximum power point regardless of lighting conditions. For solar cell selection and comparison information, see the solar cell section of the BEAM Reference Library's BEAM Pieces collection. Also see the Starting Block article on solar cells.
The development of the solar cell stems from the work of the French physicist Antoine-César Becquerel in 1839. Becquerel discovered the photovoltaic effect while experimenting with a solid electrode in an electrolyte solution; he observed that voltage developed when light fell upon the electrode. About 50 years later, Charles Fritts constructed the first true solar cells using junctions formed by coating the semiconductor selenium with an ultrathin, nearly transparent layer of gold. Fritts's devices were very inefficient, transforming less than 1 percent of the absorbed light into electrical energy.
Modern solar cells are based on semiconductor physics -- they are basically just P-N junction photodiodes with a very large light-sensitive area. The photovoltaic effect, which causes the cell to convert light directly into electrical energy, occurs in the three energy-conversion layers.
Diagram courtesy U.S. Department of Energy
Solar cells are characterized by a maximum Open Circuit Voltage (Voc) at zero output current and a Short Circuit Current (Isc) at zero output voltage. Since power can be computed via this equation:
EPA's engine research focuses on developing engines that are simultaneously clean, efficient, and cost effective, and which have high potential to produce real-world benefits. Clean Diesel Combustion technology is one example of these innovative engine concepts. EPA's testing suggests the potential for a diesel engine design, using innovative air, fuel, and combustion management and conventional particulate matter aftertreatment, to achieve lower NOx levels without the need for NOx aftertreatment. EPA is developing this technology as a potential alternative with other diesel emissions control approaches (e.g., NOx adsorbers, urea selective catalytic reduction (SCR), etc.). Clean Diesel Combustion technology shows the potential to meet NOx levels "engine-out" over the entire engine operating range, to a level required for future diesel emissions standards. EPA has partnered with several automotive and engine manufacturers to evaluate the production feasibility of this technology. Using clean diesel combustion technology in conjunction with the full hydraulic drive is projected to improve fuel economy more than using either technology alone.Engine Research
Hydrogen-powered fuel cells hold enormous promise as a power source for future generations. Hydrogen is the simplest element known to humans. Each atom of hydrogen has only one proton. It is also the most abundant gas in the universe. Hydrogen has a unique property. It carries the highest energy content of any common fuel by weight (about three times more than gasoline), but interestingly it has the lowest energy content by volume (about four times less than gasoline). Hydrogen is the lightest element, and it is a gas at normal temperature and pressure. Hydrogen is not a widely used fuel today but it has great potential as an energy carrier in the future. Hydrogen can be produced from a variety of sources (water, fossil fuels, and biomass) and is a byproduct of other chemical processes.(www.alternative-energy-news.info/)