Thursday, August 21, 2008
Growing Organs through Cell Regeneration
Tree-Climbing Goats
Monday, August 04, 2008
World's tiniest snake found in Barbados
Friday, August 01, 2008
Rare Australian Snubfin Dolphin filmed
A camera crew has filmed a rare breed of dolphin that has only been known to scientists for three years near Broome, Western Australia.
The recent discovery of the Australian snubfin dolphin has led scientists to search the Australian coastline for the elusive animals.
According to the research team, the sighting is the best yet as the dolphins were playful and poked their heads above water. Scientists were also able to record underwater sounds the dolphins made while communicating.
Solar Power Breakthrough
Until now, solar power has been a daytime-only energy source, because storing extra solar energy for later use is too expensive and inefficient. Inspired by the photosynthesis performed by plants, the scientists have developed a process that will allow the sun's energy to be used to split water into hydrogen and oxygen gases. Later, the oxygen and hydrogen may be recombined inside a fuel cell, creating carbon-free electricity to power your house or your electric car, day or night.
The key component is a new catalyst that produces oxygen gas from water; another catalyst produces hydrogen gas. The new catalyst consists of cobalt metal, phosphate and an electrode, placed in water. When electricity -- whether from a photovoltaic cell, a wind turbine or any other source -- runs through the electrode, the cobalt and phosphate form a thin film on the electrode, and oxygen gas is produced. Combined with another catalyst, such as platinum, that can produce hydrogen gas from water, the system can duplicate the water splitting reaction that occurs during photosynthesis.
Sunlight has the greatest potential of any power source to solve the world's energy problems. In one hour, enough sunlight strikes the Earth to provide the entire planet's energy needs for one year.
Insects use trapped oxygen to breathe underwater
Hundreds of insect species spend much of their time underwater, where food may be more plentiful. MIT mathematicians have now figured out exactly how those insects breathe underwater.
By virtue of their rough, water-repellent coat, when submerged these insects trap a thin layer of air on their bodies. These bubbles not only serve as a finite oxygen store, but also allow the insects to absorb oxygen from the surrounding water. The insects use this bubble as a kind of external lung.
Thanks to those air bubbles, insects can stay below the surface indefinitely and dive as deep as about 100 feet. Some species, such as Neoplea striola, which are native to New England, hibernate underwater all winter long.
The air bubble's stability is maintained by hairs on the insects' abdomen, which help repel water from the surface. The hairs, along with a waxy surface coating, prevent water from flooding the spiracles--tiny breathing holes on the abdomen.
The spacing of these hairs is critically important: The closer together the hairs, the greater the mechanical stability and the more pressure the bubble can withstand before collapsing. However, mechanical stability comes at a cost. If the hairs are too close together, there is not enough surface area through which to breathe.