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South Pole Telescope will study 'noise' from the early universe
Scientists just got a valuable tool in their quest to understand the cosmic microwave background radiation that persists from the earliest days of the universe. The South Pole Telescope recently received an ultra-sensitive camera that will study the cosmic microwave background at an extreme level of detail. Its 16,000 detectors (ten times more than a previous experiment) can spot minuscule changes in temperature when they receive light, helping them pick up the ancient microwave energy that's virtually omnipresent in the universe but difficult to detect with conventional methods.
Physicists keep striking out in the search for dark matter
Space may be the final frontier, but we've barely begun to explore its underlying mechanics. For as much as humanity has discovered since we first looked to the heavens, we've only seen about five percent of the total matter in the universe. The other 95 percent -- the so-called "dark matter" -- well, we can't even figure out how to see yet. But that doesn't mean researchers from around the world aren't devising ways to do so.
Work starts on a massive underground neutrino experiment
Neutrinos are notoriously difficult to understand, but work is underway to know them a little better. Researchers have officially broken ground on the Long-Baseline Neutrino Facility, the home to the international Deep Underground Neutrino Experiment. When it's finished 10 years from now, the South Dakota project will be the largest-ever US experiment built to study the subatomic particle -- teams will remove 870,000 tons of rock to create the caverns needed for the facility's centerpiece liquid argon detector. All that excavation should pay off, though, as it promises to shed light on some of the mysteries of the universe.
Behold, the majesty of weird, but beautiful science!
Artist or scientist? Work of art or laboratory machine? The two pairs needn't be exclusive and we've collected a batch of real-world photos to prove it. The artistry in crafting experimental machines to explore the fabric of our world rivals that used to create futuristic movie sets or avant-garde sculptures. The closer you explore reality, the more unusual and exotic it tends to appear. With that in mind, we offer you a gallery of science-based gadget porn to dazzle your eyes and titillate your brain. [Image: Lawrence Berkeley National Lab - photo by Roy Kaltschmidt]
NOvA neutrino detector captures cosmic rays in 3D, aims to unlock the mysteries of the universe
All apologies accepted if you mistook that image above as cover art for Daft Punk's new album -- it's not (although the duo should consider it.). That Tron-ish, equalizer-like graphic is actually a 3D representation of particle activity left behind by cosmic rays interacting within NOvA, the Department of Energy's under construction neutrino detector. It's the first such visual record made possible by the University of Minnesota-operated facility that, when completed, will extend for more than 200 feet underground in an area near the Canadian border and endure regular bombardment by a controlled stream of neutrinos. Beyond its obvious visual appeal, data like this should give physicists at the DOE's Fermi National Accelerator Laboratory insight into the nature of neutrinos (some of which are said to have been issued from the Big Bang) and, by extension, the origins of our ever-expanding universe. For now, though, the project's still in the baby steps phase -- only 12 feet of the detector (the currently operational portion) has been successfully built out -- so the reality-shattering, scientific epiphanies will have to wait. Until then, it's all still life as we safely know it.
DECam: Gazing deep into the final frontier in search of dark energy
The National Optical Astronomy Observatory (NOAO) puts it into perspective right away: "Eight billion years ago, rays of light from distant galaxies began their long journey to Earth." It's important to hold that fact in mind, as we marvel at the first images from deep in the belly of our universe to arrive from the Chile-based Dark Energy Camera (DECam). As that name might suggest, peering at remote galaxies for purely visual gratification isn't the camera's primary purpose. The result of eight years of planning and hard work, involving engineers and scientists from three continents, the DECam is mounted on the Victor M. Blanco Telescope at the Cerro Tololo Inter-American Observatory in Chile. Sitting atop a 7,200-foot mountain, the camera is part of the Dark Energy Survey, which intends to gather information on over 300 million galaxies. The goal is to better understand dark energy -- a concept that represents our best explanation for why the universe's rate of expansion is speeding up, rather than slowing due to gravity. Gaze past the break for the background on the project.
Neutrinos can transmit messages through walls, mountains, planets
Neutrinos may not travel as fast as we first hoped, but then they have other special abilities to make up for it. Being almost massless, they can penetrate the thickest barriers, which ought to make them ideal message carriers. To illustrate the point, scientists sent the word "Neutrino" on a beam of particles through 240 meters (800 feet) of solid stone and received it loud and clear on the other side. The same approach could potentially be used to send a message right through the center of a planet, making it possible, according to one of the researchers, to "communicate between any two points on Earth without using satellites or cables." The experiment required the latest particle accelerators at Chicago's Fermilab, which flung the neutrinos over a 2.5 mile track before firing them off at an underground receiver, but it proved the principle: Shrink the accelerator down to the size of a smartphone and neutrino messaging could be huge. Or it could die in a format war with quantum teleportation.
Pour one out for the Tevatron particle accelerator, because it's shutting down today
The eyes of the physics community are collectively fixed upon Illinois today, where, later this afternoon, researchers at Fermilab will shut down the Tevatron particle accelerator... for good. That's right -- the world's second-largest collider is being laid to rest, after a remarkable 25-year run that was recently halted due to budgetary constraints. Earlier this year, Fermilab's scientists and a group of prominent physicists pleaded with the government to keep the Tevatron running until 2014, but the Energy Department ultimately determined that the lab's $100 million price tag was too steep, effectively driving a nail through the accelerator's subterranean, four-mile-long coffin. First activated in 1985, the Tevatron scored a series of subatomic breakthroughs over the course of its lifespan, including, most notably, the discovery of the so-called top quark in 1995. Its groundbreaking technology, meanwhile, helped pave the way for CERN's Large Hadron Collider, which will now pursue the one jewel missing from the Tevatron's resume -- the Higgs boson. Many experts contend that the collider could've gone on to achieve much more, but its ride will nonetheless come to an inglorious end at 2PM today, when Fermilab director Pier Oddone oversees the Tevatron's last rites. "That will be it," physicist Gregorio Bernardi told the Washington Post. "Then we'll have a big party."
