ScienceIQ.com

How Much Coffee Will Kill You?

With the spread of Starbucks franchises all the way from Portland to Poughkeepsie, Americans are getting used to paying $3 or more for a proverbial ten-cent beverage. Of course, you get a bigger cup, and what's inside tastes better than sock juice. But it's not just the price, size, and quality of a cup of coffee that are going up. The caffeine ...

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HowMuchCoffeeWillYou
Biology

Giant Cloned Monster Loose In Mediterranean Sea

Native Caulerpa taxifolia is found in and around the waters of Florida and the Caribbean. It is a smallish, yet hardy saltwater plant that grows rapidly and is ideal for use in aquariums with diverse ... Continue reading

Caulerpa
Biology

The Touching Brain

Our brain and skin are initially part of the same primitive formation during prenatal development, but they are separated during the process of neurogenesis (the embroyo's production of brain cells). ... Continue reading

TheTouchingBrain
Astronomy

Mercury

The small and rocky planet Mercury is the closest planet to the Sun; it speeds around the Sun in a wildly elliptical (non-circular) orbit that takes it as close as 47 million km and as far as 70 ... Continue reading

Mercury
Medicine

The Neurological Complications Of Lyme Disease

Lyme disease is caused by a bacterial organism that is transmitted to humans via the bite of an infected tick. Most people bitten by an infected tick develop a characteristic skin rash around the area ... Continue reading

LymeDisease

It's a Supernova

ItsaSupernovaScientists have discovered that one of the brightest gamma ray bursts on record is also a supernova. It's the first direct evidence linking these two types of explosions, both triggered by the death of a massive star. NASA's High-Energy Transient Explorer satellite (HETE) initially detected the burst on March 29, 2003, in the constellation Leo. For more than 30 seconds, the burst outshone the entire universe in gamma rays. Two hours later, the explosion's optical afterglow remained a trillion times more luminous than the Sun. Although the fireball was about two billion light-years away, it was nevertheless bright enough to be detected by small telescopes on Earth. Sky watchers in Japan, for instance, had no trouble photographing the fading afterglow using a 12' telescope at the Tokyo Institute of Technology.

In Arizona, astronomers turned the Multiple Mirror Telescope (MMT) at Mount Hopkins toward the gamma ray burst afterglow and soon spotted the telltale signs of a supernova. Scientists cannot yet determine which came first, the burst or the supernova, but the same event, a star explosion, was certainly the trigger for both. Gamma ray bursts are the most powerful explosions in the universe, and they likely signal the birth of black holes. Bursts occur at random locations scattered across the sky. Few last more than a minute, making them hard to study. A supernova is the explosion of a star at least eight times as massive as the sun. When such stars deplete their nuclear fuel, they no longer have the energy to support their mass. Their cores implode, forming either a neutron star or, if there is enough mass, a black hole. The surface layers of the star blast outward, forming the colorful patterns typical of supernova remnants.

Previous observations, particularly from NASA's Chandra X-ray Observatory, have provided convincing indirect evidence of the gamma ray burst/supernova connection. The Chandra Observatory detected iron and other heavy elements, which are formed in supernovas, in the vicinity of gamma ray bursts. But this latest burst has provided a direct link: light from the afterglow itself exhibits the same patterns as light from a supernova. Namely, the scientists see changes in light absorbed by silicon and iron atoms, forged in the supernova, as the afterglow slowly fades away. The March 29 burst, named GRB 030329, was one of the closest to Earth. It was approximately two billion light-years away, as opposed to other bursts located more than 10 billion light-years away. Because the burst was both relatively close to Earth and bright, the supernova was detectable ... and the long-sought missing link was finally found.