Lunch near the largest manhunt in the history of physics. At 8 o'clock, Eastern time on Tuesday morning, scientists at CERN, the European Organization for Nuclear Research, will give a report on the search for the Higgs boson - dubbed the "God particle" called - whose discovery would be the modern theory of justification, how to get the mass of elementary particles. The report comes amid rumors that the two rival armies of scientists sift through the rubble of hundreds of billions of proton collisions at the Large Hadron Collider, or LHC, on the outskirts of Geneva, the two finally see hints of what could be the elusive particles, when more data is collected in the next year. Moreover, researchers say, that in one year must have sufficient data to exclude the existence of the most popular version of the Higgs boson, sending theorists back to their tables to find another explanation of why particles have mass.
Be monitored worldwide.
Among them is Lisa Randall, a theorist at Harvard and author, the God particles of the new book "Knocking on Heaven's Door:. How physics and the universe and scientific thought today's world of light" in an interview with Dennis Overbye of The Times, Dr. Randall provided this guide to action for those of us in the stands.
Question: What is the Higgs boson, and why is it important?
Higgs A. The name refers to at least four things. First, there is a Higgs mechanism, the ultimate responsibility of the masses of elementary particles "This is without doubt one of the most difficult aspects of particle physics is to explain, but basically something like an electric charge no charge -. - fills the vacuum state without particles.
These "rights" associated with a Higgs field. As the particles pass through this field, interacting with the "fees" and this interaction makes them act as if they have mass. Heavier particles, but not particles smaller and lighter. The Higgs mechanism is crucial for the masses of elementary particles.
The Higgs God particle or Higgs boson is the remnant of the proposed simple model which created the Higgs field in the first place. Contrary to popular understanding, the Higgs field gives mass - not the Higgs boson. However, a discovery of the Higgs boson would tell us that the Higgs mechanism is the right thing and help us realize that the theory behind both the Higgs mechanism and the standard model.
In the simplest version of the Higgs mechanism, the experimental result, the Higgs boson. Is the particle that experimenters are looking for.
Higgs is, of course, also the name of the person, Peter Higgs, who first developed the underlying theory (along with five others who are in the running for the Nobel Prize, as long as the Higgs particle is discovered.)
Q: How do we know when we find them?
A. In the simplest version of the Higgs mechanism, we know exactly what is due to the properties of the Higgs boson. This is due to its relationship with the Higgs mechanism, which tells us that through their interactions with a given particle, the God particle mass is determined, in particular.
Knowledge of the interactions, we can calculate the frequency with the Higgs boson will be produced and how it should disintegrate. It can decay only those particles that are light enough to be preserved for energy. Overall, the Higgs boson decays into the heaviest of these particles more often, because it interacts with them the most.
We do not know, however, the mass of the Higgs boson. The Higgs boson decays differently, depending on its mass, since a heavy Higgs boson in a way that is not a light Higgs boson can decay. Therefore, if the researcher of the Higgs boson search, find and use over a range of masses and a variety of search strategies.
Question: What do we know you know so much?
A. experimenters have already mastered a variety of masses. The Higgs boson, if any, must be heavier than 114.4 giga-electron volts (GeV), which are using the units of mass of the particle physicists. In comparison, protons are the foundation of ordinary matter, about 1 giga electron volts, and an electron is only half a million electron-volts.
Based on past searches by the LHC, the Higgs boson, and between about 140 GeV and 500 GeV is excluded. Be the most likely causes of the Higgs mass between about 115 and 140 GeV, which should focus on the field Tuesday's results, although, in principle, the heavier Higgs boson mass is also in dispute.
I do not want to crush the hopes, but not on Tuesday to leave the result as final. This is the toughest mass range for the LHC and the test is difficult for this area. I suspect that there is insufficient evidence to exclude the Higgs boson, but very little to pin entirely possible, without the data in the next year.
P. What difference does it make to its mass?
R. In fact, so that the matter go to the properties is not really a big difference. As long as the Higgs mechanism exists, it is elementary that the masses know they do.
But nobody thinks that the Higgs boson, the last word on what underlies the standard model of God particle physics, the theory is that the basic building blocks of matter and the forces that interact with the description of them. Even if the Higgs boson is discovered, the question remains as to why the masses are what they are and will remain so.
According to quantum field theory - the theory of quantum mechanics and special relativity together - expect crowds than ten thousand trillion times larger. No one ingredient, a fudge of this size would be needed to ensure that all hang together. Do not believe that particle physicists, dass
We all expect a richer theory underlying the Standard Model. That's one reason people are important to us. Some theories only place for a certain range of masses. Knowledge of communication gives us an idea of the underlying theory.
Q: Is the L.H.C. a failure, if not find the Higgs boson?
A. The great irony is that by not finding a Higgs boson would be spectacular from the perspective of God particle physics and pointed to something more interesting than the simple model Higgs. Future research may show that the separate particles in the role of Higgs interactions we have learned to be there for the particles acquire mass.
The other possibility is that the answer is no, is that single particles are fundamental, looking at the Large Hadron Collider today. You could find a more complicated object or part of a complex sector, which would take more time.
P. Does this have anything to do with neutrinos - especially those who have recently traveled faster than light, as they appear on a journey that had arisen in the CERN?
A. neutrinos have a tiny mass. The Higgs mechanism is probably responsible for the well. Just anything that goes faster than light (which is probably not) promotes.
P. made in 1993, the U.S. Congress a large collider of America, the Superconducting Supercollider, which would have been greater than the machine at CERN. He had found the Higgs boson years?
R. Yes, if things had gone according to plan. And it would be able to do things that were not have simple Higgs boson, too. The L.H.C. can be searched as well, but with lower energy of the work is demanding and requires more time.
Be monitored worldwide.
Among them is Lisa Randall, a theorist at Harvard and author, the God particles of the new book "Knocking on Heaven's Door:. How physics and the universe and scientific thought today's world of light" in an interview with Dennis Overbye of The Times, Dr. Randall provided this guide to action for those of us in the stands.
Question: What is the Higgs boson, and why is it important?
Higgs A. The name refers to at least four things. First, there is a Higgs mechanism, the ultimate responsibility of the masses of elementary particles "This is without doubt one of the most difficult aspects of particle physics is to explain, but basically something like an electric charge no charge -. - fills the vacuum state without particles.
These "rights" associated with a Higgs field. As the particles pass through this field, interacting with the "fees" and this interaction makes them act as if they have mass. Heavier particles, but not particles smaller and lighter. The Higgs mechanism is crucial for the masses of elementary particles.
The Higgs God particle or Higgs boson is the remnant of the proposed simple model which created the Higgs field in the first place. Contrary to popular understanding, the Higgs field gives mass - not the Higgs boson. However, a discovery of the Higgs boson would tell us that the Higgs mechanism is the right thing and help us realize that the theory behind both the Higgs mechanism and the standard model.
In the simplest version of the Higgs mechanism, the experimental result, the Higgs boson. Is the particle that experimenters are looking for.
Higgs is, of course, also the name of the person, Peter Higgs, who first developed the underlying theory (along with five others who are in the running for the Nobel Prize, as long as the Higgs particle is discovered.)
Q: How do we know when we find them?
A. In the simplest version of the Higgs mechanism, we know exactly what is due to the properties of the Higgs boson. This is due to its relationship with the Higgs mechanism, which tells us that through their interactions with a given particle, the God particle mass is determined, in particular.
Knowledge of the interactions, we can calculate the frequency with the Higgs boson will be produced and how it should disintegrate. It can decay only those particles that are light enough to be preserved for energy. Overall, the Higgs boson decays into the heaviest of these particles more often, because it interacts with them the most.
We do not know, however, the mass of the Higgs boson. The Higgs boson decays differently, depending on its mass, since a heavy Higgs boson in a way that is not a light Higgs boson can decay. Therefore, if the researcher of the Higgs boson search, find and use over a range of masses and a variety of search strategies.
Question: What do we know you know so much?
A. experimenters have already mastered a variety of masses. The Higgs boson, if any, must be heavier than 114.4 giga-electron volts (GeV), which are using the units of mass of the particle physicists. In comparison, protons are the foundation of ordinary matter, about 1 giga electron volts, and an electron is only half a million electron-volts.
Based on past searches by the LHC, the Higgs boson, and between about 140 GeV and 500 GeV is excluded. Be the most likely causes of the Higgs mass between about 115 and 140 GeV, which should focus on the field Tuesday's results, although, in principle, the heavier Higgs boson mass is also in dispute.
I do not want to crush the hopes, but not on Tuesday to leave the result as final. This is the toughest mass range for the LHC and the test is difficult for this area. I suspect that there is insufficient evidence to exclude the Higgs boson, but very little to pin entirely possible, without the data in the next year.
P. What difference does it make to its mass?
R. In fact, so that the matter go to the properties is not really a big difference. As long as the Higgs mechanism exists, it is elementary that the masses know they do.
But nobody thinks that the Higgs boson, the last word on what underlies the standard model of God particle physics, the theory is that the basic building blocks of matter and the forces that interact with the description of them. Even if the Higgs boson is discovered, the question remains as to why the masses are what they are and will remain so.
According to quantum field theory - the theory of quantum mechanics and special relativity together - expect crowds than ten thousand trillion times larger. No one ingredient, a fudge of this size would be needed to ensure that all hang together. Do not believe that particle physicists, dass
We all expect a richer theory underlying the Standard Model. That's one reason people are important to us. Some theories only place for a certain range of masses. Knowledge of communication gives us an idea of the underlying theory.
Q: Is the L.H.C. a failure, if not find the Higgs boson?
A. The great irony is that by not finding a Higgs boson would be spectacular from the perspective of God particle physics and pointed to something more interesting than the simple model Higgs. Future research may show that the separate particles in the role of Higgs interactions we have learned to be there for the particles acquire mass.
The other possibility is that the answer is no, is that single particles are fundamental, looking at the Large Hadron Collider today. You could find a more complicated object or part of a complex sector, which would take more time.
P. Does this have anything to do with neutrinos - especially those who have recently traveled faster than light, as they appear on a journey that had arisen in the CERN?
A. neutrinos have a tiny mass. The Higgs mechanism is probably responsible for the well. Just anything that goes faster than light (which is probably not) promotes.
P. made in 1993, the U.S. Congress a large collider of America, the Superconducting Supercollider, which would have been greater than the machine at CERN. He had found the Higgs boson years?
R. Yes, if things had gone according to plan. And it would be able to do things that were not have simple Higgs boson, too. The L.H.C. can be searched as well, but with lower energy of the work is demanding and requires more time.
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