Tag: Higgs Boson

Why Higgs Boson called God’s particle

In 1964 peter Higgs with five scientists proposed a theory called the Higgs mechanism to explain the existence of mass in the universe. Before 1930s, atoms were considered as the fundamental particles. Then we found electron, protons and neutrons as atomic particles. Later we found that protons and neutrons are made up of even more small fundamental particles called quarks. Quarks are the fundamental building blocks for the whole universe. The key evidence for the existence of these elementary particles came from a series of inelastic electron-nucleon scattering experiments conducted between 1967 and 1973 at the Stanford linear accelerator center. They are commonly found in protons and neutrons. There are six types of quarks, up quark, down quark, top quark, bottom quark, strange quark, charm quark. They can have positive (+) or negative (-) electric charge. Up, charm and top quarks have a positive 2/3 charge. Down, strange, bottom quarks have a negative 1/3 charge. So protons are positive because there are two quarks (+2/3) ups and one down quark (-1/3), giving a net positive charge (+2/3+2/3-1/3 =1). These three quarks are known as valence quarks, but the proton could have an additional up quark and anti-up quark pair.

The Higgs mechanism theory

In the second half of the 20th century, physicists made a developed a theory called a standard model of particle physics. They theorized about twelve fundamental particles that make up all matter, and four particles called bosons are responsible for three fundamental forces of nature. It includes strong force, weak force, and electromagnetism. Gravity is another force, it is not a part of this model but, it can be modeled using general relativity. With these fundamental particles in the standard model and gravity, we can build almost everything in the entire universe. However until 2012, the standard model was an underlying theory. Because all forces carrying particles should be massless. So, although the photons are massless, experiments show that the weak forces bosons have mass. So that was a promising model that could be used to explain our universe. But perhaps, it would need to be thrown out because it had the seemingly fatal flaw in being inconsistent regarding the way the weak force worked in the late 1950s physicists had no idea to resolve these issues all attempts to solve this problem. But indeed it created new theoretical problems. In 1964, Peter Higgs hypothesized that perhaps the force articles were massless but gained mass when they interacted with an energy field that is the reason for the existence of the entire universe.

During the very early moments following the big bang, in the universe, the elementary particles were massless and they were pure streams of energy that move at the speed of light. As the expansion of the universe was proceeding, density and temperature decreased below a certain key value. According to the theory, the Higgs field interacts with particles and can give them mass. It is theorized that different particles interact differently with the field, the particles that interact with it more intensely have greater mass and particles that don’t interact with it that much have lower mass. Just imagine Higgs field as water, pointed shape objects interact lesser with water and cube shaped objects interact more with it. Some particles don’t interact with the field like photons are massless. A fundamental part of the theory was the presence of a specific particle; it’s called the Higgs boson. A boson that would allow the Higgs mechanism to unfold correctly to give mass to all other particles.

CERN’s discovery of a new particle

Even though Higgs theorized it, scientists can’t able to prove that until 2012. The particle accelerators had to possess a huge amount of energy to detect them. Finally, the Large Hadron Collider (LHC), the CERN’s particle accelerator has been turned on in 2008 and managed to recreate the required energy and temperature conditions in 2012. The Higgs boson was finally experimentally detected and on 4th July, a conference held in the CERN auditorium announced the discovery of a particle compatible with the Higgs boson. The machine accelerates Hadron bundles at close to the speed of light and collides them each other in opposite directions. At four separate points the two beams cross, causing protons to smash into each other at enormous energies, with their destructions being witnessed by super-sensitive instruments. Even if LHC is the world’s largest particle accelerator, it had to work hard to detect Higgs boson. If the Higgs field doesn’t exist, all particles in the universe will become absolutely weightless and fly around the universe in the speed of light. For This reason Higgs boson is often called as the ‘God particle’.

 

 

 

Why Higgs Boson is called as the ‘God Particle’?

By Shashikant Nishant Sharma

In 1964 peter Higgs with five scientists proposed a theory called the Higgs mechanism to explain the existence of mass in the universe. Before 1930s, atoms were considered as the fundamental particles. Then we found electron, protons and neutrons as atomic particles. Later we found that protons and neutrons are made up of even more small fundamental particles called quarks. Quarks are the fundamental building blocks for the whole universe. The key evidence for the existence of these elementary particles came from a series of inelastic electron-nucleon scattering experiments conducted between 1967 and 1973 at the Stanford linear accelerator center. They are commonly found in protons and neutrons. There are six types of quarks, up quark, down quark, top quark, bottom quark, strange quark, charm quark. They can have positive (+) or negative (-) electric charge. Up, charm and top quarks have a positive 2/3 charge. Down, strange, bottom quarks have a negative 1/3 charge. So protons are positive because there are two quarks (+2/3) ups and one down quark (-1/3), giving a net positive charge (+2/3+2/3-1/3 =1). These three quarks are known as valence quarks, but the proton could have an additional up quark and anti-up quark pair.

The Higgs field theory

In the second half of the 20th century, physicists made a developed a theory called a standard model of particle physics. They theorized about twelve fundamental particles that make up all matter, and four particles called bosons are responsible for three fundamental forces of nature. It includes strong force, weak force, and electromagnetism. Gravity is another force, it is not a part of this model but, it can be modeled using general relativity. With these fundamental particles in the standard model and gravity, we can build almost everything in the entire universe. However until 2012, the standard model was an underlying theory. Because all forces carrying particles should be massless. So, although the photons are massless, experiments show that the weak forces bosons have mass. So that was a promising model that could be used to explain our universe. But perhaps, it would need to be thrown out because it had the seemingly fatal flaw in being inconsistent regarding the way the weak force worked in the late 1950s physicists had no idea to resolve these issues all attempts to solve this problem. But indeed it created new theoretical problems. In 1964, Peter Higgs hypothesized that perhaps the force articles were massless but gained mass when they interacted with an energy field that is the reason for the existence of the entire universe.

During the very early moments following the big bang, in the universe, the elementary particles were massless and they were pure streams of energy that move at the speed of light. As the expansion of the universe was proceeding, density and temperature decreased below a certain key value. According to the theory, the Higgs field interacts with particles and can give them mass. It is theorized that different particles interact differently with the field, the particles that interact with it more intensely have greater mass and particles that don’t interact with it that much have lower mass. Just imagine Higgs field as water, pointed shape objects interact lesser with water and cube shaped objects interact more with it. Some particles don’t interact with the field like photons are massless. A fundamental part of the theory was the presence of a specific particle; it’s called the Higgs boson. A boson that would allow the Higgs mechanism to unfold correctly to give mass to all other particles.

The Higgs Boson – CMS experiment

CERN’s discovery of a new particle

Even though Higgs theorized it, scientists can’t able to prove that until 2012. The particle accelerators had to possess a huge amount of energy to detect them. Finally, the Large Hadron Collider (LHC), the CERN’s particle accelerator has been turned on in 2008 and managed to recreate the required energy and temperature conditions in 2012. The Higgs boson was finally experimentally detected and on 4th July, a conference held in the CERN auditorium announced the discovery of a particle compatible with the Higgs boson. The machine accelerates Hadron bundles at close to the speed of light and collides them each other in opposite directions. At four separate points the two beams cross, causing protons to smash into each other at enormous energies, with their destruction being witnessed by super-sensitive instruments. Even if LHC is the world’s largest particle accelerator, it had to work hard to detect Higgs boson. If the Higgs field doesn’t exist, all particles in the universe will become absolutely weightless and fly around the universe in the speed of light. For This reason Higgs boson is often called as the ‘God particle’.

“I never expected this to happen in my lifetime and shall be asking my family to put champagne in the fridge.”Peter Higgs

Large Hadron Collider-the world’s largest machine

The smallest thing that we can see with a light microscope is about 500 nano-meters. A typical atom is anywhere from 0.1 to 0.5 nano-meters in diameter. So we need an electron microscope to measure these atoms. The electron microscope was invented in 1931. Beams of electrons are focused on a sample. When they hit it, they are scattered, and this scattering is used to recreate an image. Then what about protons or neutrons? Or what about quarks? The quarks are the most fundamental building blocks of matter. So how did we find such small particles exist? The answer is a particle collider. A particle collider is a tool used to accelerate two beams of particles to collide since 1960s.

The largest machine built by man, the Large Hadron Collider (LHC) is a particle accelerator occupying an enormous circular tunnel of 27 kilometres in circumference, ranging from 165 to 575 feet below ground. It was situated near Genoa, Switzerland. It is so large that over the course of its circumference crosses the border between France and Switzerland. That’s the giant collaboration going on between over 100 countries and 10,000 scientists. The tunnel itself was constructed between 1983 and 1988 to house another particle accelerator, the Large Hadron Collider, which operated until 2000, its replacement, the LHC, was approved in 1995, and was finally switched on in September 2008.

The Larger Hadron Collider (LHC) covers the circumference of 27 kilometres

Working of the Large Hadron Collider

 The LHC is the most powerful particle accelerator ever built and has designed to explore the limits of what physicists refer to as the standard Model, which deals with fundamental sub-atomic particles. There are two vacuum pipes are installed inside the tunnel which intersects in some places and 1,232 main magnets are connected to the pipe. For proper operation, the collider magnets need to be cooled to -271.3 °C. To attain this temperature, 120 tons of liquid helium is poured into the LHC. These powerful magnets can accelerate protons near the speed of light, so they can complete a circuit in less than 90 millionths of a second. Two beams operate in opposite directions around the ring. At four separate points the two beams cross, causing protons to smash into each other at enormous energies, with their destruction being witnessed by super-sensitive instruments. But it’s not that easy to do this experiment. Each beam consists of bunches of protons and most of the protons just miss each other and carry on around the ring and do they it again. Because, atoms are mostly empty space, so getting them to collide is incredibly difficult. It’s like colliding a needle into a needle, provided that the distance between them is 10 kilometres.

Collision of protons at near the speed of light

The aim of these collisions is to produce countless new particles that stimulate, on a micro scale, some of the conditions postulated in the Big Bang at the birth of the universe. Higgs Boson was discovered with the help of LHC. This so called ‘God Particle’ that could be responsible for the very existence of mass. If it disappeared, all particles in the universe will become absolutely weightless and fly around the universe in the speed of light (299,792,458 m/s). that means we can reach our moon in 1.3 seconds from earth.

“When you look at a vacuum in a quantum theory of fields, it isn’t exactly nothing.”Peter Higgs

Discovery of God Particle : Super Exclusive >>>>>>>

The two largest experiments at the Large Hadron Collider (LHC), ATLAS and CMS, have observed a previously undetected way that the Higgs boson can decay — into an elementary particle called the bottom quark, and its antiparticle.

The same experiments, based at CERN, the European particle-physics laboratory outside Geneva, Switzerland, first discovered the Higgs in 2012. The boson, which is a key part of the mechanism that gives other particles their masses, put in place the final piece of the standard model of particle physics.

LHC researchers have accumulated evidence of the particle decaying into a variety of products, following theoretical predictions, including into two photons and an electron–antielectron pair.

Credit: Third Party Reference

In June, researchers revealed that they had also seen the Higgs interact with the top quarks, the most massive known elementary particle. The bottom-quark decay, announced on 28 August is expected by theory but the signal had been hiding in the data, because the interaction is difficult to single out from the many other processes that can also produce those particles.

Geneva, 28 August. Six years after its discovery, the Higgs boson has at last been observed decaying to fundamental particles known as bottom quarks. The finding, presented today at CERN by the ATLAS and CMS collaborations at the Large Hadron Collider (LHC), is consistent with the hypothesis that the all-pervading quantum field behind the Higgs boson also gives mass to the bottom quark. Both teams have submitted their results for publication today.

The Standard model of particle physics predicts that about 60% of the time a Higgs boson will decay to a pair of bottom quarks, the second-heaviest of the six flavours of quarks. Testing this prediction is crucial because the result would either lend support to the Standard Model – which is built upon the idea that the Higgs field endows quarks and other fundamental particles with mass – or rock its foundations and point to new physics.

Credit: Third Party Reference

Spotting this common Higgs-boson decay channel is anything but easy, as the six-year period since the discovery of the boson has shown. The reason for the difficulty is that there are many other ways of producing bottom quarks in proton–proton collisions. This makes it hard to isolate the Higgs-boson decay signal from the background “noise” associated with such processes. By contrast, the less-common Higgs-boson decay channels that were observed at the time of discovery of the particle, such as the decay to a pair of photons, are much easier to extract from the background.

To extract the signal, the ATLAS and CMS collaborations each combined data from the first and second runs of the LHC, which involved collisions at energies of 7, 8 and 13 TeV. They then applied complex analysis methods to the data. The upshot, for both ATLAS and CMS, was the detection of the decay of the Higgs boson to a pair of bottom quarks with a significance that exceeds 5 standard deviations. Furthermore, both teams measured a rate for the decay that is consistent with the Standard Model prediction, within the current precision of the measurement.

This observation is a milestone in the exploration of the Higgs boson. It shows that the ATLAS and CMS experiments have achieved deep understanding of their data and a control of backgrounds that surpasses expectations. ATLAS has now observed all couplings of the Higgs boson to 

“Since the first single-experiment observation of the Higgs boson decay to tau-leptons one year ago, CMS, along with our colleagues in ATLAS, has observed the coupling of the Higgs boson to the heaviest fermions: the tau, the top quark, and now the bottom quark. The superb LHC performance and modern machine-learning techniques allowed us to achieve this result earlier than expected,” said Joel Butler, spokesperson of the CMS collaboration.

Credit: Third Party Reference

With more data, the collaborations will improve the precision of these and other measurements and probe the decay of the Higgs boson into a pair of much-less-massive fermions called muons, always watching for deviations in the data that could point to physics beyond the Standard Model.

“The experiments continue to home in on the Higgs particle, which is often considered a portal to new physics. These beautiful and early achievements also underscore our plans for upgrading the LHC to substantially increase the statistics. The analysis methods have now been shown

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