Physicists on experiments at the Large Hadron Collider have observed a new particle that future analysis may show to be the long-sought Higgs boson, the missing piece in the Standard Model of particle physics. In December 2011, researchers on the Compact Muon Solenoid (CMS) and ATLAS experiments announced seeing tantalizing hints of a new particle in their hunt for the Higgs. Since then, they have more than doubled their collected data, which led to the July 2012 announcement of a new particle. Find out more in this news release.
Credit: CERN/CMS collaboration 2011
The Higgs boson is a central component of the "Standard Model," a theory that defines the relationships between the forces of the universe. But, what if the Higgs boson is not a fundamental particle, but rather a bound state of new particles that have not yet been seen? Scientists who advocate alternative models of particle physics are motivated by the theory of superconductivity. The superconducting state, which is very different from ordinary matter, is not characterized by new particles, but by Cooper pairs--bound states of electrons. Learn more in this Discovery.
Using data from experiments performed in 2010 at the Large Hadron Collider (LHC), the world's largest particle accelerator near Geneva, Switzerland, scientists are studying rare particle decays that could explain why the universe has more matter than antimatter. Learn more in this Discovery.
Credit: 2008, Courtesy of CERN
Over the past three decades or more, physicists have developed their experimental and theoretical understanding of the world of subatomic particles into a comprehensive theory known as the Standard Model. Much of the Standard Model has been verified and tested. Learn more in this Discovery.
Credit: DZero collaboration
The mission of the Division of Physics of NSF's Directorate for Mathematical and Physical Sciences is to support fundamental research across the intellectual frontiers of physics, to support research that has broader impacts on other fields of science and on the health, economic strength, and defense of society, to enhance education at all levels and share the excitement of science with the public through integration of education and research, and to be a steward for the physics community so as to maintain the intellectual capital essential for future advances.
Majorana is a name whose very mention evokes a veil of mystery. On one level, it refers to a mysterious particle that may exist on the boundary of matter and antimatter. Curiously, it is thought to be both a material particle and its own corresponding antiparticle.
University of California, Berkeley, physicists Hitoshi Murayama and Haruki Watanabe have proved that counting the number of Nambu-Goldstone bosons in a material reveals the material's behavior at low temperatures.
New measurements announced by scientists from the Collider Detector at Fermilab and DZero collaborations at the Department of Energy's Fermi National Accelerator Laboratory indicate that the elusive Higgs boson may nearly be cornered.
The world's most precise measurement of the mass of the W boson, one of nature's elementary particles, has been achieved by scientists from the CDF and DZero collaborations at the Department of Energy's Fermi National Accelerator Laboratory. The new measurement is an important, independent constraint of the mass of the theorized Higgs boson.
November 19, 2012
Higgs Boson: Mysterious Particle Could Help Unlock Secrets of the Universe
Researchers on a scientific quest to understand 'the God particle'
The search for a mysterious subatomic particle can certainly involve some enormous tools, not to mention a multitude of scientists. The effort to find the elusive "Higgs boson" includes over 5,800 scientists from 56 countries! It's a subatomic particle that gives other particles, such as quarks and electrons, their mass.
With support from the National Science Foundation (NSF), physicists Michael Tuts at Columbia University and Kyle Cranmer at New York University are among the 21st century explorers who have been on the hunt for the Higgs.
"There is an important and fundamental synergy that's not to be missed in challenging the deepest scientific questions of our time, while simultaneously educating new generations of scientists and engineers, and developing technologies that can advance society and propel the world's economy in the future," says Saul Gonzalez, program director for Experimental Elementary Particle Physics, within NSF's Directorate for Mathematical and Physical Sciences.
Without the Higgs, atoms could not form. "The universe would be a fundamentally different place. There would be no life, no stars," says Cranmer.
Cranmer's and Tuts' detective work is done at CERN, the European Organization for Nuclear Research, located in Geneva, Switzerland, where construction of the Large Hadron Collider and the detectors needed to study these particles took years to complete.
Cranmer first visited CERN as a graduate student. "When I was at CERN, I would watch these pieces of equipment going across the road and it was like a science fiction film, with these enormous magnets that just don't look like they're plausible, being driven across the road to ultimately be lowered by cranes into place," he recalls. "And, to have all of these millions of components put together by physicists, and have it work, is pretty surprising sometimes, but we pulled it off."
And, as complex as huge magnets, super cold temperatures, and protons moving at nearly the speed of light can be, Tuts says the search for the Higgs has captured the imagination of non-scientists as well.
He recalls that, a few years ago, during his plane trips to Switzerland, he'd get blank stares when he told people what he was working on. But, Tuts says, now, just as often, he will get an enthusiastic query, 'Oh, the God particle, how's that going?' from other travelers.
"Historically, we know that fundamental research is the engine that drives technology," says Tuts. "I can't assure you that discovering a Higgs particle will help you tomorrow, or make your life better tomorrow, but in 10 years, 20 years, maybe 50 years, the fundamental research that we're doing now is going to be the technology of the future."
That, adds Tuts, is how science has worked throughout history.
"You could go back to the time of Michael Faraday, who did experiments on electricity. And, people said, 'Well that's cute, that's interesting, but so what?' Well, could you imagine our life without electricity? It's so fundamental to us. I think, in the future, we'll see that," adds Tuts.
The particle detectors used to identify the Higgs boson are the size of a six-story building, full of hundreds of millions of electronic instruments. The ATLAS detector, used by Tuts and Cranmer, works like a huge digital camera. It records hundreds of billions of protons colliding at nearly the speed of light. This "camera" takes 40 million pictures per second.
"We go from 40 million to about 400 images per second, saved for further analysis, and the trick is to make sure that you don't throw away the good stuff," explains Tuts.
Still, thousands of computers, some at New York's Brookhaven National Lab, filter those remaining images, looking for traces of the Higgs boson, which decays quickly.
"It only lasts for less than a billionth of a billionth of a second, so we never see the Higgs itself. We only see the things it decays into, and we only have this sort of indirect evidence at first. We have to go through and try to work out what happened," explains Cranmer. "People have likened it to taking two Swiss clocks and smashing them together, and looking at the gears flying out, trying to figure out what was going on inside!"
Why the intense search for the Higgs? Over the past few decades, scientists have been trying to understand all the different building blocks of nature. They came up with a theory called "the Standard Model."
"We've been checking it in all sorts of experiments all across the world for decades, and it's just the theory that refuses to fail. It has passed every test that we've thrown at it," says Cranmer. "But one of the real mysteries was that there was one more particle in this theory that we hadn't seen, which is the Higgs boson. So, somehow, in some sense, we knew the theory was right because it had worked so well but, in other ways, it was this mystery, because there was a missing piece."
On July 4, 2012, CERN's Director General Rolf Dieter-Heuer cautiously announced the discovery of a new particle, with all the proper characteristics of a Higgs boson.
"They had finally collected enough data that they could actually, definitively say, "We've seen something, and that something looks like a Higgs boson," says Tuts.
For these two physicists, and thousands of others around the world, the adventure is just beginning. Still ahead at CERN is an effort to unravel more exotic mysteries, from figuring out what happened immediately after the Big Bang to discovering extra dimensions of time and space!
"It's like Columbus heading off into the ocean. We don't know what's going to be there. Maybe we'll discover America. Maybe we'll discover India. Who knows? This is a triumph of human curiosity. It's really key to our understanding of the universe," says Tuts.
"And so what I hope we're doing is actually inspiring the next set of kids who are maybe now in high school, or maybe even younger, to say, 'Wow, I can ask the question--where do we come from? Where are we going,'" adds Tuts. "We desperately, in our society, need more people who are involved and interested in science and technology."
The research in this episode was funded by NSF through the American Recovery and Reinvestment Act of 2009.
Any opinions, findings, conclusions or recommendations presented in this material are only those of the presenter grantee/researcher, author, or agency employee; and do not necessarily reflect the views of the National Science Foundation.