Awesome power of supermassive black holes revealed

April 17, 2010 By Leave a Comment

Washington, April 17 (ANI): Nottingham University researchers have shed new light on the super destructive capacity of black holes.

For the study, Asa Bluck in the School of Physics and Astronomy and colleagues, used images of unprecedented depth and resolution from the Hubble Space Telescope and the Chandra X-Ray Observatory to detect black holes in distant galaxies.

Scientists looked for galaxies emitting high levels of radiation and x-rays – a classic signature of black holes devouring gas and dust through accretion, or attracting matter gravitationally.

As this matter swirls around the event horizon of a black hole it heats up and radiates energy – as an accretion disc.

In supermassive black holes this radiation can reach huge proportions, emitting X-ray radiation in far greater quantities then is emitted by the rest of the objects in the galaxy combined – meaning that the black hole ”shines” far brighter than the entire galaxy it lies at the heart of.

In fact, the amount of energy released is sufficient to strip the galaxy of gas at least 25 times over.

Results have also demonstrated that the vast majority of the X-ray radiation present in the universe is produced in these accretion discs surrounding supermassive black holes, with a small proportion produced by all other objects, including galaxies and neutron stars.

The accretions discs surrounding supermassive black holes produce so much energy that they heat up the cold gases lying at the heart of massive galaxies.

The accretion disc shines across all wavelengths – from radio waves to gamma waves.

This speeds up the random motions of the gas, making it rise in temperature and pushing it away from the galactic centre, where it becomes less dense.

Gas needs to be cold and dense to collapse under gravity to form new stars, this resulting hot, low-density material must cool down before gravity will take effect – a process which would take longer than the age of the universe to achieve.

Old stars are therefore left to die out with no new stars replacing them, leaving the galaxy to grow dark and die.

And by pushing gas away from the galactic centre, the accretion disc starves the supermassive black hole of new material to devour, leading to its eventual demise.

Asa Bluck, a PhD student at the University and a Fellow of the Royal Astronomical Society, said: “It”s thought that black holes form inside their host galaxies and grow in proportion to them, forming an accretion disc which will eventually destroy the host. In this sense they can be described as viral in nature.

“Massive galaxies are in the minority in our visible universe – about one in a thousand galaxies is thought to be massive, but it may be much less. And at least a third of these have supermassive black holes at their centre. That”s why it”s so interesting that this type of black hole produces most of the X-ray light in the universe. They are the minority but they dominate energy output.”

The study, a collaboration between researchers at The University of Nottingham and Imperial College London, was presented at the Royal Astronomical Society National Astronomy Meeting in Glasgow. (ANI)

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Toyota’s faulty gas pedals may be a result of cosmic rays from space

March 27, 2010 By Leave a Comment

Washington, March 27 (ANI): A new research has come up with a surprising finding that Toyota’s faulty gas pedals could be a result of cosmic rays from space.

Toyota’s sticky gas pedals caused sudden and unintended acceleration in several of the automaker”s top-selling Toyota and Lexus-brand cars, which led to a massive recall of more than 9 million vehicles worldwide, beginning in November last year.

While ongoing inquiries attempt to locate the source of the problem and figure out a fix, investigators might find it useful to examine a far-out culprit, in the form of cosmic ray radiation from deep in the cosmos, which has been known to plague vulnerable data and memory chips in electronics.

Scientists now say that cosmic rays could be at least partially to blame for Toyota’s mechanical defects.

The problem could get worse in the future, as the increasing use of tiny computer chips — replacing mechanical parts — makes cars more and more vulnerable to space radiation.

Federal regulators were prompted to look into the possible role that cosmic rays played in Toyota’s product recall fiasco after an anonymous tipster suggested the design of Toyota’s microprocessors, software and memory chips could make them more vulnerable to interference from radiation compared with other automakers.

This is because Toyota has led the auto industry in its widespread inclusion of electronic controls in the manufacture of their various car models.

As electronic devices are made to perform more and more functions on smaller circuit chips, the systems become more sensitive and vulnerable to corruption, and thus more prone to interference from radiation, according to Ewart Blackmore, a senior researcher at TRIUMF, a cyclotron facility in Vancouver, Canada, that works with companies to test and analyze the effects of radiation on products.

“Radiation is certainly a potential cause of Toyota’s problems,” Blackmore told Live Science.

“What’s not known is what direction Toyota and other automakers are taking in terms of finding and correcting these issues,” he said.

As a start, automakers and regulators need to understand the complex and sometimes mysterious ways cosmic rays affect electronics on Earth. (ANI)

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Structure of protein may lead to more effective chemotherapy drugs

March 29, 2009 By Leave a Comment

Washington, Mar 27 (ANI): Scientists at Scripps Research Institute have uncovered the structure of a protein that makes cancer cells resistant to chemotherapy.

The protein, called P-glycoprotein or P-gp makes cancer cells resistant to chemotherapy drugs. The research team believes that the structure would help them design more effective drugs.

“This structure is an important advance and we hope it is just the beginning of more breakthroughs for us,” said the study’s senior author Geoffrey Chang, an associate professor at Scripps Research.

“The structure is a nice tool for understanding how drugs are transported out of cells by P-gp and for designing drugs to evade P-gp preventing drug resistance. It’s very exciting,” he added.

“We’ve long known that P-glycoprotein plays a key role in multidrug resistance in cancer patients, and this work helps us understand how the protein can act on such a wide range of compounds,” said Jean Chin, Ph.D., of the National Institutes of Health’s (NIH) National Institute of General Medical Sciences (NIGMS).

During the study, the Scripps scientists along with colleagues from Texas Tech University Health Sciences Centre determined the structure of P-gp using a technique in structural biology known as x-ray crystallography, which involves making crystals of ordered arrays of protein and then blasting the frozen crystals with x-ray radiation.

“In the future, scientists may be able to use these crystal structures to design chemicals that block P-glycoprotein’s activity and restore sensitivity to chemotherapeutic agents.”

The protein has the shape of an upside down “v” or a tipi with a large cavity inside. The shape is strikingly similar to that of another protein, MsbA, that transports lipids out of bacteria.

It is believed that P-gp works by bringing the two dumbbell-shaped arms together on the inside of the cell and opening the closed end toward the outside of the cell, essentially reversing direction of the “v” or tipi so any substance caught inside the protein’s cavity is ejected from the cell.

The study appears in the journal Science. (ANI)

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Scientists find oldest isolated pulsar ever

February 27, 2009 By Leave a Comment

Washington, Feb 27 (ANI): With the help of NASA’s Chandra X-ray Observatory, scientists have found the oldest isolated pulsar ever detected in X-rays.

The pulsar, PSR J0108-1431 (J0108 for short), which is about 200 million years old, turns out to be surprisingly active.

Among isolated pulsars, ones that have not been spun-up in a binary system, it is over 10 times older than the previous record holder with an X-ray detection.

At a distance of 770 light years, it is one of the nearest pulsars known.

Pulsars are born when stars that are much more massive than the Sun collapse in supernova explosions, leaving behind a small, incredibly weighty core, known as a neutron star.

At birth, these neutron stars, which contain the densest material known in the Universe, are spinning rapidly, up to a hundred revolutions per second.

As the rotating beams of their radiation are seen as pulses by distant observers, similar to a lighthouse beam, astronomers call them “pulsars”.

Astronomers observe a gradual slowing of the rotation of the pulsars as they radiate energy away.

Radio observations of J0108 show it to be one of the oldest and faintest pulsars known, spinning only slightly faster than one revolution per second.

The surprise came when a team of astronomers led by George Pavlov of Penn State University observed J0108 in X-rays with Chandra.

They found that it glows much brighter in X-rays than was expected for a pulsar of such advanced years.

Some of the energy that J0108 is losing as it spins more slowly is converted into X-ray radiation. The efficiency of this process for J0108 is found to be higher than for any other known pulsar.

“This pulsar is pumping out high-energy radiation much more efficiently than its younger cousins,” said Pavlov. “So, although it’s clearly fading as it ages, it is still more than holding its own with the younger generations,” he added.

At its advanced age, J0108 is close to the so-called “pulsar death line,” where its pulsed radiation is expected to switch off and it will become much harder, if not impossible, to observe.

“We can now explore the properties of this pulsar in a regime where no other pulsar has been detected outside the radio range,” said co-author Oleg Kargaltsev of the University of Florida.

“To understand the properties of ‘dying pulsars,’ it is important to study their radiation in X-rays. Our finding that a very old pulsar can be such an efficient X-ray emitter gives us hope to discover new nearby pulsars of this class via their X-ray emission,” he added. (ANI)

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