Beyond Nature

Intel has rolled out its first chip with six brains, unveiling a "multi-core" microprocessor that boosts computing muscle while cutting back on electricity use. The new Xeon 7400 series microprocessor has been designed by none other than Intel engineers at Bangalore from scratch.

The Bangalore design centre is the first Intel team outside the US to complete the design of a 45-nanometer processor.

Post its inception in 2001, the Xeon 7400 series is the first chip to come out of Intel's Bangalore design centre. The centre had previously worked on another Xeon server chip called Whitefield.

But that chip never made it to market. It was cancelled in 2005, when Intel revised its product road maps to better compete with Advanced Micro Devices, and the Indian design team soon put its focus on Dunnington.

The Dunnington chip design marks a technical milestone for Intel, as it uses a monolithic die, the term engineers use to describe putting all of the cores on a single piece of silicon.

Intel's existing quad-core processor lines use two pieces of silicon, each with two cores, packaged together. That approach made the older quad-core chips easier to produce and avoided the manufacturing difficulties that hampered the release of AMD's Barcelona chip, an x86 server chip with four cores on a single piece of silicon. Those difficulties were compounded by AMD's transition to a new 65-nanometer manufacturing process.


The giant chipmaker has clarified that they have no intention to create virtual bridge between Intel and AMD by introducing the first of it’s kind 6-core x86 microprocessor Xeon 7400 from it’s India’s off-shore unit. The newly introduced Intel microprocessor is powered with six processing cores with each of it’s chip. Designed by 1.9 billion transistors, the Xeon 7400 will support shared cache memory in the tune of 16 MB.

Dell, Hewlett Packard, IBM, Unisys and Fujitsu are among the computer
makers building the new Xeon 7400 chips into servers designed for
business networks, according to Intel.

With the introduction of Dunnington, and the upcoming Nehalem line of quad-core processors that also uses a monolithic design, Intel waited until its 45-nanometer process was in mass production, with any technical difficulties presumably ironed out, before making this transition.

After successful launching of the new chip, India has entered in the list of exclusive countries that have high expertise and infrastructure to design and fabricate such a complex microprocessor. Entire design operation of the chip, including it’s front-end and back-end design, pre-silicon logic validation etc., has been performed by about 300 people at the Bangalore unit of Intel. “The quality of available talent, technology ecosystem and business potential are factors which make India a strategic business site for Intel,” says Intel India president Mr. Praveen Vishakantaiah.

The new Intel processor, Xeon 7400 series, is highly compatible with the Intel Xeon 7300 series and the Intel 7300 chipset.

With availability of the new Intel Xeon 7400 processors, VMware customers will now be able to move freely between two servers running on different Intel chips. Earlier, people had to use same type of Intel chips on two servers to allow vMotion to work, but now no such limitation exists.

The Xeon 7400 series is priced between $856 (Rs39,279) and $2729 (about Rs1.09 lakh), the company said

Intel executives say the Xeon 7400 is part of an "incremental migration" toward chips with limitless numbers of "cores" that seamlessly and efficiently share demanding computer processing tasks.


Intel and rival Advanced Micro Devices have two-core and four-core chips on the market. The six-core chip delivers 50 per cent more performance than its quad-core predecessor while using 10 per cent less electric power, according to Intel enterprise group vice president Tom Kilroy.

Electricity and cooling expenses can account for nearly half the cost of running company computer servers.

"It isn't just performance and energy efficiency but the use models," Kilroy said of the boon promised by increasingly powerful chips. "One of the major ones is virtualisation."

Multi-core chips are boons to computing trends including high-definition video viewing online; businesses offering services applications on the Internet; and single servers running many "virtual" machines.

Product brief: Intel® Xeon® processor 7400 series (PDF 478KB)

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Intel executive VP, Pat Gelsinger announcing world record performance results for XEON 7400-series processors. Industry first 1.2 million database tranactions per minute on 8 slot IBM server.

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India has surprisingly broken into the Top Ten in a much-fancied twice-yearly list of the fastest supercomputers in the world, marking a giant leap in its push towards becoming a global IT power.

EKA (the Sanskrit name for number one) is a supercomputer ranked as the 8th fastest in the world and fastest in Asia as of June 2008, according to the Top 500 Supercomputer list built by Hewlett-Packard.

The supercomputer built at the Computational Research Laboratories (CRL) by Hewlett-Packard facility at Pune, India, marked a milestone in the Tata Group's effort to build an indigenous high-performance computing solution. CRL built the supercomputer facility using dense data centre layout and novel network routing and parallel processing library technologies developed by its scientists. It was reported to have cost $30 million dollars to build.

Ashwin Nanda, who heads the CRL, told the conference that its supercomputer had been built with HP servers using Intel chips with a total of 14,240 processor cores. The system went operational last month and achieved a performance of 117.9 teraflops.

It is the first supercomputer to have been developed totally by a corporation without any government help, now shares the rarefied heights of supercomputing with two American and one German supercomputer.


Eka is an important milestone because it almost restarts the train of supercomputing in India, which stalled after the PARAM supercomputers developed by the C-DAC. “It is a team effort rather than an individual’s effort. This has put India on the world map and brought a national sense of pride,” said S Ramadorai, chairman, CRL, and also the CEO of India’s largest software firm, TCS. TCS is a key partner in the entire supercomputer project.

The project was also important because it was done with a small work-force and with global partners like Hewlett Packard, Intel and Mellanox. But the most noteworthy achievement of the team was that it finished the project in time even after CRL lost its technical spearhead, Dr Narendra Karmarkar.

Details:

• System Name: EKA
• Site: Computational Research Laboratories, TATA SONS
• System Family: HP Cluster Platform 3000BL
• System Model: Cluster Platform 3000 BL460c
• Computer: Cluster Platform 3000 BL460c, Xeon 53xx 3GHz, Infiniband
• Vendor: Hewlett-Packard
• Application area: Not Specified
• Installation Year: 2007
• Operating System: Linux
• Interconnect: Infiniband DDR
• Processor: Intel EM64T Xeon 53xx (Clovertown) 3000 MHz (12 GFlops)

For more comprehensive details click here


Proposed Applications:

Supercomputers are typically used for highly calculation problem solving in quantum mechanical physics, molecular modeling, weather forecasting and climate research, and physical simulation including that of nuclear tests.

The term supercomputer is quite relative. It was first used in 1929 to refer to large custom-built tabulators IBM made for Columbia University. The supercomputers of the 1970s are today's desktops.

"The supercomputer system will have a direct effect on the lives of Indians, espcially in areas such as earthquake and Tsunami modelling, modellings of the economy and potential for drug design," said Mr S. Ramadorai, chairman of the Computational Research Laboratories, which is a subsidiary of Indian firm Tata.


Having developed the machine, the Tata group is busy developing a marketing strategy for it. “In another six-nine months, we would be able to build applications and a software library, following which we would take the offering to commercial use,” Raju Bhinge, chief executive, Tata Strategic Management Group — a Tata Group company involved in the development of the facility in Pune told ET. CRL’s capabilities are currently being used by another Tata Group company, Tata Elixsi for high speed animation rendering work. CRL is also looking at newer opportunities in the weather forecasting, automotive crash simulation, computational fluid dynamics in aerospace sector, gaming and animation and drug discovery among many others.

According to company officials, CRL has already been in touch with the likes of Boeing and Airbus for its aerospace applications and there is also interest from Tata Motors for its crash testing application. S Ramadorai, CEO & MD of TCS one of the partners for CRL and chairman of CRL said that the company was also in discussion with a host of government agencies as well, for the use of its new computing prowess.

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The world's fastest supercomputer will probably never be known as the world's fastest supercomputer. RIKEN's MDGrape-3 is the first machine to break the petaflop barrier -- that's 1 quadrillion calculations (floating-point operations, to be specific) per second -- and it's three times faster than the currently ranked fastest computer in the world, IBM's BlueGene/L. But MDGrape-3 is so specialized that it can't run the software used to officially rank computing speed. What it can do is determine the effect of any chemical compound on one of the most intricate systems in the human body in a couple of seconds.


MDGrape-3 is designed for pharmaceutical research, specifically molecular dynamics simulation. In developing drugs, pharmaceutical companies have to analyze thousands on thousands of chemical compounds to find out how they'll affect the protein-bonding structures in the human body. Protein structures called enzymes are the building blocks that do all of the work within a cell, and the way these proteins bond with any drug compound introduced into the human body determines the body's response to that drug.

MDGrape-3 produces simulations of these molecular interactions. What takes most computers hours or days to analyze takes MDGrape-3 a few seconds. This functionality is invaluable in drug research, and it could drastically cut the research time involved in the development of new cures. A subsidiary of pharmaceutical giant Merck has already booked time on the machine.

Structurally speaking, MDGrape-3 is a parallel computing system consisting of two main sections: a primary server unit and a specialized-engines unit. The latter component is a cluster of 201 engines running proprietary chips developed by Riken specifically for MDGrape-3. It's this huge set of engines, running 24 MDGrape-3 chips each, that does the heavy protein-analysis lifting. Each chip has a maximum processing speed of 230 gigaflops (one billion operations per second).

The primary server unit manages the engine cluster. This parallel server setup runs two different types of processors: 65 servers run dual-core Intel 5000-series Xeon processors, 256 per server; and 37 servers run 3.3-GHz Intel Xeon processors, each with 2 MB of level 1 cache, at 74 processors per server. This hardware structure enables the 1-petaflop speed, which is the machine's theoretical maximum for certain processes.

MDGrape-3 took $9 million and about four years to build. And it's actually very efficient -- a total cost of $9 million breaks down to about $15 per gigaflop. The slower BlueGene/L cost about $140 per gigaflop to build.

BlueGene/L, which tops out at a theoretical 360 teraflops (trillion calculations per second), is also a biotechnology-specific machine. The advances in speed marked by these two supercomputers is indicative of a general trend in technology toward biologically-slanted systems. Some say the trend really started with the successful mapping of the human genome in 2000.

Regardless of what spurred the current biotechnology race, most experts agree that the logical end of the surge is a state of DNA-based medicine. In several decades, we could make an appointment with our doctor for a quick DNA analysis to find out what diseases we're at risk for and pop a single, gene-targeting pill that eliminates all of those foreseeable risks.

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SuperComputer @ Wikipedia

Top500 SuperComputing Sites - This project ranks and details the 500 most powerful known computer systems in the world

SuperComputing Online

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Using the strongest materials known to man, scientists are building the most powerful electromagnet in the world -- one that won't blow up a split second after it's turned on.

The entire magnet will be a combination of coil sets weighing nearly 18,000 pounds and powered by jolts from a massive 1,200-megajoules motor generator. Once activated, the new magnet should be about two million times more powerful than the average refrigerator magnet.

"The new magnet at the High Field Lab is a fantastic leap forwards in terms of our capability as a scientific community to explore materials under extreme conditions," said Ian Fisher, a scientist at Stanford University.

"In several cases one needs to go to these sorts of extremes to fundamentally understand materials" used in high-temperature superconductors and other applications, said Fisher.

The electromagnet consists of two parts. The outer section, or outsert, will be a cylinder, 1.5 meters (4.9 feet) in diameter and 1.5 meters tall, and solid except for a small hole, less than 8 inches wide, bored through the middle.

Inside that hole rests the insert, nine coils made of copper and strengthened with silver wire as thin as 100 atoms across. Together, the copper and silver create the strongest material known to man, according to Greg Boebinger, Director of the National High Magnetic Field Laboratory in Florida. The magnet is being built at the Los Alamos National Laboratory.

The pressures generated inside the insert will be equivalent to 200 sticks of dynamite going off together, or about 30 times the pressure at the bottom of the ocean.

Very few things can survive those kinds of forces for long -- including the new magnet.

The scientists expect each $20,000 insert to survive about 100 pulses. The $8 million outsert should last about 10,000 pulses. Each time the magnet pulses it bends the copper and silver wires, creating tiny cracks in the metal. The cracks in the copper run into the silver wires, which stops the cracks from spreading.

"It's like reinforced concrete," said Boebinger.

The copper acts like like the concrete, strong and tough. The silver acts like the steel rebars running through the concrete, providing flexibility.

Together the inner and outer magnets can already create 90 teslas.

Teslas measure the pull of a magnetic field. Even one tesla is quite powerful. The Earth's magnetic field is about 50 microteslas. An average MRI (magnetic resonance imaging) machine ranges from 0.5 to 1.5 teslas.

The scientists hope that within months they can develop the new electromagnet to reach their target goal of 100 teslas.

This won't be the first 100-tesla electromagnet. Technically it won't even be the world's most powerful magnet. Electromagnets as strong as 1,000 teslas have been created before. The new electromagnet will be the world's first reusable 100-tesla magnet.

All other magnets of this power were one-and-done. The powerful forces the other electromagnets created tore themselves, and usually the samples being studied, apart milliseconds after they were turned on. Those magnets have their uses, says Boebinger, but destroying samples can be a problem and building new magnets can be expensive.

Studying the same material over and over without destroying it could help scientists tease out the properties of superconductors and other novel materials, said Boebinger, who points out that previous magnet work at the lab helped produce neodymium magnets that enabled wireless phones, cordless drills, and other handheld electronic devices.

New materials, like iron oxyarsenide, could eventually lead to high definition MRI scans or power lines that don't lose any energy to heat and would save consumers millions of dollars each year.

Eventually, however, even this electromagnet will break under the incredible pressures, and when it does it will be loud.

"They have to evacuate the entire building when they turn the magnet on," said Boebinger. "A magnetic disassembly will make a big boom."

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Mankind's Biggest scientific experiment to be conducted on Wednesday this week....
With this experiment we are going to know the answers for the questions which have been a mystery for us since ages......
It is the BIG BANG EXPERIMENT..
the experiment is being conducted by scientists from more than 112 countries only with an aim to unravel the mysteries of universe..
The experiment is done with the help of a huge machine named Large Hadron Collider (LHC)...

The most powerful physics experiment ever built, the Large Hadron Collider will re-create the conditions just after the Big Bang in an attempt to answer fundamental questions of science and the universe itself.

The Large Hadron Collider – a £4bn, 18-mile-long atom-smasher buried 300ft underground on the Swiss-French border...

The Large Hadron Collider (LHC) will smash two beams of particles head-on at super-fast speeds, recreating the conditions in the Universe moments after the Big Bang.

The Alice detector will investigate the moments after the Big Bang

Scientists hope to see new particles in the debris of these collisions, revealing fundamental new insights into the nature of the cosmos.

They will be looking for new physics beyond the Standard Model – the framework devised in the 1970s to explain how sub-atomic particles interact.

The Standard Model comprises 16 particles – 12 matter particles and four force-carrier particles. The Standard Model has worked remarkably well so far.

But it cannot explain the best known of the so-called four fundamental forces: gravity; and it describes only ordinary matter, which makes up but a small part of the total Universe.

Also, one of the most important particles in the Standard Model – the Higgs boson – has yet to be found in an experiment.

Today, the Standard Model is regarded as incomplete, a mere stepping stone to something else. So the LHC should help reinvigorate physics' biggest endeavour: a grand theory to explain all physical phenomena in Nature.

However, some physicists point out that Nature has a habit of throwing curve balls. And some of the most exciting discoveries at the LHC could be those that no-one expects.

There is an essential ingredient missing from the Standard Model. Without it, none of the 16 particles in the scheme would have any mass.

An extra particle is required to provide all the others with mass – the Higgs boson. This idea was proposed in 1964 by physicists Peter Higgs, Francois Englert and Robert Brout.

According to their theory, particles acquire mass through their interactions with an all-pervading field, called the Higgs field, which is carried by the Higgs boson. It is the only Standard Model particle that has yet to be observed experimentally.

As such, the search for the Higgs has become something of a cause celebre in particle physics. Finding the Higgs is one of the main science objectives for the LHC.

The Atlas and CMS experiments are both designed to see it, if it is there. This means that scientists working on these respective experiments will be competing to see it first, once the LHC begins its "science run" sometime in 2009.

The US Tevatron particle accelerator, though less powerful than the LHC, is also engaged in the hunt for the Higgs.

All the matter that we can see in the Universe – planets, stars and galaxies – makes up a minuscule 4% of what is actually out there. The rest is dark energy (which accounts for 70% of the cosmos) and dark matter (26%).

Dark energy cannot be observed directly, but it is responsible for speeding up the expansion of the Universe – a phenomenon that can be detected in astronomical observations.

Like dark energy, dark matter can only be detected indirectly, as it does not emit or reflect enough light to be seen. But its presence can be inferred through its effects on galaxies and galaxy clusters.

Physicists know virtually nothing about the nature of either dark energy or dark matter. But they can speculate.

According to one idea, dark matter could be made up of "supersymmetric particles" - massive particles that are partners to those already known in the Standard Model.

A leading dark matter candidate is the neutralino, the lightest of these "super-partners". And some theoretical physicists have proposed a link between the Higgs mechanism and dark energy.

Each basic particle of "ordinary" matter has its own anti-particle. Matter and antimatter have the same mass, but opposite electric charge.

For example, a proton has an anti-particle called an anti-proton (a proton with a negative charge). An electron has an anti-particle called a positron (an electron with a positive charge).

What happened to the anti-matter that emerged from the Big Bang?

In the same way that an ordinary proton and electron can come together to form a hydrogen atom, an anti-proton and a positron can form an atom of anti-hydrogen.

When a particle of ordinary matter meets its anti-particle, the two disappear in a flash, as their mass is transformed into energy.

They are said to "annihilate" one another. But equal amounts of matter and anti-matter must have been produced in the Big Bang.

So why did matter and anti-matter not completely annihilate each another after the birth of the Universe?

Today, we live in a Universe almost entirely composed of ordinary matter. Scientists will use the LHC to investigate why this is, and what happened to all the anti-matter.

Attempts to unify gravity with the other fundamental forces have come to a startling prediction: that every known particle has a massive "shadow" partner particle.

Atlas is one of the experiments that could find evidence for supersymmetry

All particles are classified as either fermions or bosons. A particle in one class has superpartner in the other class, "balancing the books" and doubling the number of particles in the Standard Model.

For example, the superpartner of an electron (a fermion) is called a selectron (a boson). Evidence for supersymmetry would enable the "unification" of three fundamental forces - the strong, weak, and electromagnetic – helping to explain why particles have the masses they have.

It would also give a boost to string theory – one stab at a grand "theory of everything". But string theory is not dependent on discovering evidence for supersymmetry.

In addition to the four dimensions we already know about, string theory predicts the existence of six more.

Some physicists even think the existence of these extra dimensions could explain why gravity is so much weaker than the other fundamental forces. Perhaps, they argue, we are not feeling its full effects.

This might be explained if its force was being shared with other dimensions. If these extra dimensions do exist, the LHC could be the first accelerator to detect them experimentally.

At high energies, physicists could see evidence of particles moving between our world and these unseen realms. For example, they could see particles suddenly disappear into one of these dimensions.

Alternatively, particles originating from an extra dimension could suddenly appear in our world.

According to some physicists, the LHC can operate at high enough energies to generate mini-black holes.

However, the vast majority of particle physicists say there is no need for alarm. If any should be created, they should evaporate quickly.

How a black hole might look if it is generated in the collider

A recent report dealing with the collider's safety acknowledged the possibility that the LHC could create these primordial black holes.

The report says: "If microscopic black holes were to be singly produced by colliding the quarks and gluons inside protons, they would also be able to decay into the same types of particles that produced them.”

The suggestion that black holes could be made in the LHC has stoked fears in the online world that one of these micro-black holes could swell in size, swallowing up the Earth.

In March, plaintiffs requested an injunction in a US court stopping the LHC from switching on.

However, physicists stress that any such phenomena would be short-lived and thus would pose no threat to our planet.

Building the LHC

The Large Hadron Collider is not just an extraordinary science experiment, it is also a remarkable engineering undertaking. Just getting it built is an astonishing story in itself.

The LHC took 10,000 scientists a total of 14 years to assemble

How do you build a "Big Bang Machine"? That was the challenge which scientists at Cern began to ponder in the early 1980s, when the idea for the Large Hadron Collider was born.

Cern's governing council wanted to build a kind of time machine that could open a window to how the Universe appeared in the first microseconds of its existence.

If it could recreate the fleeting moments 13.73 billion years ago, when the fundamental building blocks of the cosmos took shape, then the world we live in today would be brought into much sharper focus.

It could discover how matter prevailed over antimatter, learn how dark matter was formed, and catch our first glimpse of the elusive Higgs boson - a "missing jigsaw piece" in our model of the universe.

We might even find evidence of the existence of other dimensions. But to conjure up these conditions, the Cern council new it needed to perform an engineering miracle.

The 12-storey ATLAS detector weighs in at 7,000 tonnes

To generate the necessary high energies, the designers required a particle accelerator more magnificently complex than any machine ever built.

Beams of protons would be hurled together at 99.9999999% of the speed of light, in conditions colder than the space between the stars and each travelling with as much energy as a car at the speed of 1,600km/h.

And yet the fruits of these explosions - high-energy particles - would decay and disappear from view in less than a trillionth of a second.

To "photograph" these valuable prizes would require a detector as large as a five storey building, yet so precise, it could pinpoint a particle with an accuracy of 15 microns - 20 times thinner than a human hair.

How on earth do you build a machine like that? The journey took 14 years, more than 10,000 scientists, from 40 countries, and a financial injection anticipated at up to 6.2bn euros - four times the original budget. But it was achieved, on time. Well, almost.

The last of the LHC's 1,700 dipole magnets is lowered into place

The plans for the Large Hadron Collider began to gather momentum in the early 1980s, inspired by the success of its predecessor at Cern, a collider known as the Large Electron Positron (LEP).

But it was not until 1994 that the formal proposal for the LHC was ratified by Cern's member states, and the engineering work began.

The accelerator would be housed in a near-circular 27km-long tunnel, buried 50m-175m underneath the Jura mountains, criss-crossing the Swiss-French border. The tunnel was already in place - being the once occupied by LEP, which was eventually disassembled in 2000.

Inside the LHC vacuum pipe, two parallel beams of subatomic particles (protons or lead ions) would hurtle in opposite directions at record energies.

Crashing together at specially designated junctions, they would release unstable, high-energy particles - including, perhaps, the elusive Higgs Boson.

To generate a magnetic field powerful enough to steer the high-energy particles around the pipe requires 1,740 superconducting magnets, which together required some 40,000 leak-tight welds and 65,000 "splices" of superconducting cables.

If you added all the filaments of these strands together, they would stretch to the Sun and back five times, with enough left over for a few trips to the Moon.

In order to conduct, the magnets must be cooled to within a couple of degrees of "absolute zero", the theoretical limit for how cold anything can get. This requires a constant supply of liquid helium pumped down from eight over-ground refrigeration plants - about 400,000 litres per year in total. Enough to fill 1000 swimming pools.

Engineers excavating the cavern for CMS encountered serious difficulty

At the junctions where particles collide, four enormous detectors have been designed to observe the microscopic wreckage.

Between 1996 and 1998, approval was granted for four giant "experiments" - Alice, Atlas, CMS and LHCb - to be housed in four enormous underground caverns, dug strategically around the collider loop.

Excavating these caverns out of sand, gravel and rock was a considerable feat. In the case of the 7,000 tonne ATLAS detector, it took two years to burrow a cavern large enough to hold a 12-storey building.

But while Atlas may be the largest cavern, it was CMS - 10km up the ring below the village of Dessy - which proved the most problematic at the excavation stage.

The cavern shaft had to be bored through a 50m layer of glacial deposits, including fast flowing water, which threatened to flood the shaft. Engineers repelled these underground rivers by piping super-chilled brine down the shaft, allowing a wall of ice 3m thick to form around the circumference.

It took six months to freeze the walls of the two CMS shafts. But while the barrier worked initially, the water eventually broke through, forcing engineers to first pump down liquid nitrogen to turn the area into "Siberian permafrost", in the words of Austin Ball, CMS Technical Coordinator.

LHC components were transported to Cern from all over the world

Building the components of both the accelerator and the detectors was a truly international effort.

In the case of the 12,500-tonne CMS detector, the coiled strands of its central solenoid magnet - all 50km of them - began their life in Finland, before travelling to factories in Grenoble, Neuchatel and Genoa, to be braided, coated, and welded.

After being shipped to Marseille, they went up the river to Macon, where they were unpacked and driven by lorry under the mountains to Cern.

In fact, the diameter of the magnet was restricted to ensure it was just narrow enough that components could squeeze through the tunnels. The clearance was a matter of centimetres.

The CMS magnet is the most powerful solenoid ever built - conducting a current of 12,000 amperes - to create a magnetic field 100,000 times stronger than the Earth's.

The detector units of CMS were squeezed in with centimetres to spare

The next problem, of course, was how to get a 45m-long, 25m-high, 7,000-tonne detector, through a shaft hole 20m wide.

The answer of course is to do it in bits. ATLAS was lowered piece by piece over several years, and assembled almost entirely in the subterranean cavern.

The largest piece - the barrel toroid magnet - fitted down the cavern shaft with only 10cm of clearance on either side.

But the building of the detectors is not all heavy engineering. Layer upon layer of electronic sensors had to be wired and connected by hand, which meant up to 300 people a day working in the cavern cramped against each other.

Squeezing each piece into place was "like solving a wooden puzzle" - there is only one possible way of doing it, according to Professor Andy Parker of Cambridge University, one of the founders of Atlas.

"Everything fits together like Russian dolls. I saw one design for Atlas which fitted together, but you couldn't assemble it, because there was no room to move the pieces past each other. Every single millimetre of space was fought over," he said.

The CMS detector, on the other hand, was largely assembled above ground, in several enormous units.

The largest, at 2,000 tonnes (the weight of five jumbo jets, or one-third of the weight of the Eiffel tower) took 10 hours to lower down a 100m shaft, with a clearance of 20cm either side. The world's largest electromagnet had to be handled with extreme care.

Its cylindrically arranged silicon wafer detectors contain a vast network of micro-circuitry - including 73,000 radiation-hard, low-noise microelectronic chips, almost 40,000 analogue optical links and 1,000 power supply units.

To manufacture these required an entirely new method of auto-assembly.

Failure of a magnet in testing delayed the LHC start-up by almost a year

Though the LHC was originally slated to begin operations in late 2007, the entire project was set back after a failure in one of the quadrapole magnets used to focus the beam, which buckled during testing.

This meant all similar magnets would have to be redesigned and replaced.

Other, less serious problems arose due to with leaky plumbing of liquid helium, and also when some copper "fingers" used to ensure electrical continuity between magnets buckled when the magnets were warmed up.

The final tab for the LHC is expected to come in at a colossal 6.4bn euros, four times the original budget set by the Cern Council in 1995.

But that sum still represents good value for money, according to Dr Chris Parkes, of Glasgow University, UK, who works on the LHCb detector.

He said: "Tom Hanks is to appear in the movie of Dan Brown's Angels and Demons, which involves scientists at Cern making anti-matter. But the new experiment at the LHC to understand anti-matter cost less than Tom Hanks will earn from the movie."

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India offers software support to unravel Big Bang secrets...
India also has its part to do for the worlds biggest experiment.. If all goes well, the experiment will unravel the mysteries of the universe, particularly the very moment that led to the creation of time and space, a la the Big Bang.

Despite not being a member of CERN, the European nuclear research organisation, India made a significant contribution as an observer state to the build-up of the $9 billion experiment. Scores of Indian scientists and other professionals in nuclear and other material sciences took part in select areas of setting up the Large Hadron Collider (LHC) machine over the last 20 years.

The LHC is at the heart of the experiment that will contribute to the knowing of the unknown in the formation of the universe. “The privilege to participate in the 21st century’s biggest scientific experiment and the modest role played in setting up the LHC and experiments are indeed major achievements for India,” said Archana Sharma, staff scientist at CERN.

Built under 100 metres of rock and sandstone, the LHC is a giant machine that will work at full tilt by driving two beams of particles in clockwise and anti-clockwise directions around a specially constructed underground 27 km ring at almost the speed of light, i.e., 299,792,458 metres/second. Each beam will complete 11,245 laps of the machine per second.

When each particle — proton — collides with another proton coming in the opposite direction, it would result in a collision creating mass from energy via the famous Einstein equation in E = Mc2 — the mother of all creations of space.

“Within a second (after the Big Bang), the super-hot universe expanded and cooled dramatically, its temperatures falling from a few trillion to a few billion degrees,” observed Simon Singh, the author of the book Big Bang.

Scientists at CERN are now recreating that very second after all matter and energy, which were hitherto condensed, exploded at that very moment of the Big Bang. There are four major experiments that will be conducted at four points around the ring where the beams will be directed into head-on collisions and India is participating in the CMS experiment and the Alice experiment.

The CMS explores into the next developments in the world of physics, and more importantly, into the elusive Higgs boson particle — popularised as the God particle — that explains the origin of mass. The Alice experiment will study what happened when the super-hot universe expanded within a second after its creation 13 billion years ago, especially the protons, equivalent to hydrogen nuclei, reacted with other particles in a next few minutes to form light nuclei such as helium.

“The ratio of hydrogen to helium in the universe was largely fixed within these first few minutes, and is consistent with what we see today,” said Singh.

The LHC will search for all those extra dimensions through giant detectors that will examine the shower particle debris. Besides, the experiment might also create “dark matter” which is currently present in the universe. Scientists had calculated that about 23 per cent of the universe is dark matter, 73 per cent dark energy and 4 per cent ordinary matter.

“It is once in a generation experiment, and for 20 years, all the fine details have gone into conceiving this gigantic experiment,” Archana Sharma told Business Standard. “For years to come, we will see several results emanating from this experiment at CERN that will advance the understanding of several unknown factors in universe,” she said.

Indian research establishments including the Tata Institute for Fundamental Research (TIFR), Bhaba Atomic Research Centre, Saha Institute, and Punjab University were involved in providing software and quality-testing services of detectors.

“To study and view the experiments from 70 million channels, you need awesome computing infrastructure and TIFR is involved in addressing some of the software requirements,” Sharma said, suggesting that India contributed about $25 million towards the LHC project.

The LHC project also generated some legal challenges and led to fears about the possible creation of a black hole that would wreck the planet. But the attempts to stop the machine from experimenting were dismissed in courts.

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