ECIL completes field trials of giant gamma-ray telescope

The telescope has been developed for BARC and was ready to be dispatched to Hanle site in Ladakh region of Jammu and Kashmir

PTI

ECIL completes field trials of giant gamma-ray telescope A screen grab of Electronics Corporation of India Ltd website Hyderabad: A giant Major Atmospheric Cherenkov Experiment (MACE) gamma-ray telescope, being developed and manufactured by Electronics Corporation of India Limited (ECIL), has successfully undergone all the field trials, its manufacturer said in Hyderabad on Tuesday.

The telescope has been developed for Mumbai-based Bhabha Atomic Research Centre (BARC) and was ready to be dispatched to Hanle site in Ladakh region of Jammu and Kashmir. “When installed and fully operational by early 2016, this MACE telescope (which weighs about 180 tons) will be the second largest gamma-ray telescope in the world.

It will help the scientific community of the country to enhance their understanding in the fields of Astrophysics, Fundamental Physics, Particle acceleration mechanisms etc,” according to an ECIL statement. Similar telescopes, setup in Namibia, Europe and the US, have been developed by collaborative efforts of multiple institutions, whereas the MACE telescope has been designed and developed from concept stage to assembly stage by ECIL with technology support from BARC, it said.

The MACE telescope flagging-off ceremony will be held on 28 June by Dr R.K. Sinha, secretary, Department of Atomic Energy & chairman, Atomic Energy Commission, at Antenna Systems Group, ECIL. According to the ECIL, Very High Energy (VHE) gamma rays in the telescope offer a unique insight into some of the most extreme phenomena of universe.

The largest telescope of the same class is the 28 metre diameter HESS telescope, operating in Namibia.

Read more at: http://www.livemint.com/Politics/NBATcV5k2WVUhWU9JUJ3ZP/ECIL-completes-field-trials-of-giant-Gammaray-telescope.html?utm_source=copy

Gamma ray telescope to be flagged off to Ladakh

The world’s largest high-altitude telescope for detection of gamma ray emissions is all set to be transported to Hanle, Ladakh where it will be installed by 2015 summer and become operational by early 2016.

Secretary, DAE, and Chairman Atomic Commission R.K. Sinha will flag off the transportation of the giant telescope to Hanle on Saturday. It will be dismantled and taken to Ladakh in about 45 to 50 trucks.

The ‘Major Atmospheric Cherenkov Experiment’ (MACE) Telescope will be the second largest in the world and the largest at high altitude with a 21m diameter. The largest telescope of the same class is the 28m diameter HESS telescope in Namibia. The responsibility for design, manufacturing, installation and commissioning of the telescope is with the Bhabha Atomic Research Centre to Electronics Corporation of India Limited here.

Very high energy gamma rays offer a unique insight into some of the extreme phenomena of the universe and the MACE telescope would enable scientists to study exotic objects like pulsars, super nova remnants and active galactic nuclei.

It will provide a better understanding of high-energy processes in the universe and help gain more insight into cosmic ray origins. When gamma ray photons enter the earth’s atmosphere, they generate a shower of secondary charged particles which cause a flash of blue Cherenkov light, lasting a few nano seconds.

Made up of 356 indigenously manufactured mirror panels and a high-resolution imaging camera capable of detecting extremely short duration light flashes such as Cherenkov events.

The 45-metre tall telescope is designed to operate in winds speeds up to 30 kmph and retain structural integrity in the parking position in winds speeds up to 150 kmph.

At a press conference here on Friday, Chairman and Managing Director, ECIL, P.Sudhakar said the unveiling of the telescope marked an important day for Indian science and technology. He said other similar telescopes had been built by developed countries in consortium whereas this was built indigenously. He said Hanle was the most suitable place in India to conduct gamma ray experiments. There was a live demonstration of MACE telescope at ECIL for media persons.

R.Koul, head of astro-physical sciences division, BARC, said that another similar telescope would be installed at Hanle in 2018.

http://www.thehindu.com/sci-tech/science/gamma-ray-telescope-to-be-flagged-off-to-ladakh/article6155955.ece

An eventful year on Mars

June 30, 2014

Updated: June 30, 2014 01:50 IST

The Curiosity rover, a car-sized mini- laboratory on six wheels, has so far travelled nearly 8 km since touchdown.

Looking straight down at the Gale Crater, the rover's landing site. Source: NASA/JPL-Caltech/ESA/DLR/FU Berlin/MSSS]

Curiosity takes a "selfie" made up of dozens of high-res images using its rover arm camera to celebrate its one Martian year on the planet. [Source: NASA/JPL-Caltech/MSSS]

On June 24, the National Aeronautics and Space Administration’s Mars rover, Curiosity, which soft-landed on the floor of the Gale Crater on a never-before-used contraption called sky crane, successfully completed one Martian year — 687 Earth days. The rover, a car-sized mini- laboratory on six wheels, has so far travelled nearly 8 km since touchdown. What makes the completion of one Martian year all the more significant is the rover’s ability to not only survive the harsh environment of the red planet but also fulfil its primary objective — providing much sought after information on whether past environmental conditions there were favourable for microbial life. The most important parameter that can prove that such a condition existed, is the presence of liquid water at some point in the planet’s history. The rover returned abundant and invaluable information that unequivocally confirmed that Mars once had liquid water that was suitable for drinking. Though there are micro-organisms on Earth that thrive in highly acidic and alkaline conditions, such water bodies, in general, are very unsuitable and challenging for microbial existence.

Here we see the Curiosity rover — the bright blue figure near the large hill in the lower left area — and its tracks in this view from orbit. [Source: NASA/JPL-Caltech/Univ. of Arizona]

The bonanza was indeed the detection of well-rounded pebbles in the rock layers on a dry river bed. Sharp-edged stones can become well-rounded only when transported over a long distance and above a particular speed by surface running water. On Earth, rounded pebbles are seen only in the lower reaches of a river. Also, the deposition of alternate layers of pebbles aligned at a particular angle is strongly suggestive of a paleoriver. The presence of clay minerals inside a drilled rock suggests that water was present for extended periods of time. The detection of mineral orthoclase, abundantly seen in Earth’s crust but never before detected on Mars, in the Windjana sandstone sample is yet another surprise find. The biggest question now is whether Curiosity can reconfirm on the ground the latest find of glacial, periglacial and fluvial (including glacio-fluvial) activity within the Gale Crater some 3,500 million years ago. The potential evidence of paleoglaciers was gathered by cameras on board NASA’s Mars Reconnaissance Orbiter and the European Space Agency’s Mars Express. Despite the presence of liquid water, the lack of atmospheric methane greatly reduces the possibility of any extant or extinct microbial life on Mars. Several other unique features detected by Curiosity confirm that our understanding of the red planet is very limited. There is hence every possibility that India’s Mars Orbiter Mission, which will be inserted into the Martian Orbit on September 24 this year, may unearth some unknown facets of the red planet.

Cute! The Curiosity rover tweeted this, saying, "To drill or not to drill? Investigating my next potential drilling target on Mars." [Source: Twitter user MarsCuriosity]

Here's a picture taken at a location called "Sheepbed," which shows well-defined veins filled with whitish minerals that we think is calcium sulfate. The veins form when water circulates through fractures, depositing minerals along the sides of the fracture. [Source: NASA/JPL-Caltech/MSSS]

A look back at a dune that the Curiosity rover drove across. [Source: NASA/JPL-Caltech/MSSS]

http://www.thehindu.com/opinion/editorial/an-eventful-year-on-mars/article6160466.ece?homepage=true

NEUTRINO HISTORY

 

This history is like a story. It begins at the beginning and it ends at the end. But, the true history of neutrinos is a story of ideas and, like the story of physics, its chronology does not have to be the one of acts and experiments. Moreover, many experiments and actors of the neutrino history have been forget or deliberately omitted, because this story would have become longer than the trajectory of a neutrino in the universe.

The History before the history (1896-1930)

Most of the scientific discoveries have had their origin in problems that scientific community was facing often without knowing it. Before the neutrino comes, the beta decay problem had to appear. And in order for that problem to appear, radioactivity had to be discovered.

Henri Becquerel in the year 1896, then Pierre and Marie Curie were the first actors of this time. While Henri Becquerel discovered some strange radiation coming from uranium salts, Pierre and Marie Curie isolated radium, a material much more radioactive than uranium.

In 1899, Rutherford shows that two types of radiation exist, that he calls alpha and beta. In 1900, Villard gives evidence for a third type of radiation coming from radium, that he calls gamma radiation. In 1902, Pierre and Marie Curie show that beta radiation was nothing else than electrons, while F. Soddy and E. Rutherford estimate that alpha, beta and gamma radiation are different types of radioactivity.

A crazy race begins to study in details those radiations coming from radioactive materials. Around 1904, Rutherford shows that alpha radiation is made of something like helium atoms.
Finally, three types of radioactivity are definitely asserted:

• alpha radioactivity: an Helium 4 nucleus (two protons and two neutrons) comes out of the radioactive nucleus.
• gamma radioactivity: a photon of great energy (few MeV) comes out of the radioactive nucleus.
• beta radioactivity: an electron comes out of the radioactive nucleus.

The beta radiation (electron), the presumed only particle emitted, should have had a well fixed energy. But, after different studies of this radiation made by Lise Meitner, Otto Hahn, Wilson and von Baeyer, James Chadwick shows in 1914 that this is not the case: the electron energy spectrum is continuous.

Do we have to throw away the energy conservation principle, the sacred principle of scientists always verified by experiment ?... Niels Bohr, among others, dares to believe it. We must wait the year 1930 and Wolfgang Pauli in order the see an other solution.

The birth (1930-1934)

From what we know today, misters Neutrinos were born around 15 billions years ago, soon after the the birth of the universe. Since this time, the universe has continuously expanded, cooled and neutrinos have made their own way. Theoretically, they are now many and constitute a cosmic background radiation whose temperature is 1.9 degree Kelvin (-271.2 degree Celsius). The other neutrinos of the universe are produced during the life of stars and the explosion of supernovae.

But the idea of the neutrino came to life only in 1930, when Wolfgang PAULI tried a desperate saving operation of "the energy conservation principle". The 4th of December 1930, invited at a physicists workshop in Tubingen, he sends to his colleagues a strange letter...

In February 1932, J. Chadwick discovers the neutron, but neutrons are heavy and do not correspond to the particle imagined by Pauli.

At Solvay conference in Bruxelles, in October 1933, Pauli says, speaking about his particles:

"... their mass can not be very much more than the electron mass. In order to distinguish them from heavy neutrons, mister Fermi has proposed to name them "neutrinos". It is possible that the proper mass of neutrinos be zero... It seems to me plausible that neutrinos have a spin 1/2... We know nothing about the interaction of neutrinos with the other particles of matter and with photons: the hypothesis that they have a magnetic moment seems to me not funded at all."

In 1933, F. Perrin shows that the neutrino mass has to be very much lower than the electron mass. The same year, Anderson discovers the positron, the first seen particle of anti-matter, verifying thus the theory of P.A.M. Dirac and confirming the idea of neutrino in the minds of Pauli and Fermi. End of 1933, while Frederic Joliot-Curie discovers the beta plus radioactivity (a positron is emitted instead of an electron), Enrico Fermi takes the neutrino hypothesis and builds his theory of beta decay (weak interaction).
[ Since this time, physicists have made a lot of progress in the understanding of weak interaction and we now speak about protons and neutrons, composed of three quarks each. One of the quarks of the neutron transforms into an one, producing the emission of a W boson, which decays into an electron and an anti-neutrino ]

The neutrino quest begins, but people had to be quite reckless and persevering in those years because, as soon as 1934, Hans Bethe and Rudolf Peierls showed that the cross section (probability of interaction) between neutrinos and matter should be extremely small: billions of time smaller than the one of an electron. This particle interacts so weakly with matter that it can go through the whole earth without deviation.

First quest of the inaccessible star (1935-1956)

Until the end of the forties, physicists try to measure the recoil of a nucleus during its beta decay. All the measurements are compatible with the hypothesis of only one neutrino emitted with the electron. But no direct observation of neutrino seems feasible, since its predicted probability of interaction is too weak for any feasible experiment: a very abundant source of neutrinos and a very sensitive and huge heavy detector are needed. In 1939, Luis Alvarez shows that tritium is radioactive. Until today, beta decay of tritium has been used to give the best limit on the neutrino mass.

In 1945, the first atomic bomb explodes. Despite of the horror it inspires, it is for the physicists a remarkable powerful source of neutrinos. Frederick Reines, who is working at Los Alamos, speaks to Fermi in 1951 about his project to place a neutrino detector near an atomic explosion. In 1952, he meets Clyde Cowan and they finally agree to use a more "pacific" source of neutrinos: the nuclear plant of Hanford, Washington.
The detector is quickly built. Their experiment is proposed in February 1953, realized in spring and their results come out during the summer 1953. But the signal is not convincing. They do again their experiment in 1956, more carefully and this time near the nuclear plant of Savannah River, South Carolina. The improvements made, especially do decrease the background signal, give them the jack pot! The neutrino is here. Its tag is clearly visible in the detector, well above the backgrounds like cosmic radiation signals.
[ Near the same nuclear plant, other physicists, like Luis Alvarez or Ray Davis, had tried to detect neutrinos using carbonate chloride solutions, where chlore should have transform into radioative argon under the interaction with a neutrino. Unfortunately for them, a nuclear plant delivers only anti-neutrinos! ]

Reines and Cowan experiment principle consisted in using a target made of around 400 liters of a mixture of water and cadmium chloride. The anti-neutrino coming from the nuclear reactor interacts with a proton of the target matter, giving a positron and a neutron. The positron annihilates with an electron of the surrounding material, giving two simultaneous photons and the neutron slows down until it is eventually captured by a cadmium nucleus, implying the emission of photons some 15 microseconds after those of the positron annihilation. All those photons are detected and the 15 microseconds identify the neutrino interaction.

Detector of the 1953 experiment

Scheme of the 1956 experiment

The second quest (1957-1962)

The neutrino (or more precisely the anti-neutrino) coming out of a nuclear reactor is an electron type neutrino (), because, in beta decay, he is emitted together with an electron. Is it different from the muon type neutrino (), that could be associated to the muon, an other particle observed in cosmic rays?... Or is this difference only a theoretical arbitrary convenient assertion? Reines was not permitted to continue his researches. He had to come back at Los Alamos.

Others made the continuation and, in 1959, in the cafeteria of Columbia university, New-York, began the quest of the neutrino. After a discussion between T.D. Lee and M. Schwartz, this last one realized the possibility to produce a quite intense neutrino beam from decay of pions, that are particles produced in great quantity when a proton beam of GeV energy encounters matter. T.D. Lee and C.N. Yang are enthusiastic about the idea and begin to calculate the expected cross sections, while Schwartz associates to Leon Lederman, Jack Steinberger and, later, a young physicist from Orsay Jean-Marc Gaillard. They find the ideal detector for their experiment while looking at the spark chamber built by J. Cronin and his team, at Princeton.

In 1960, Lee and Yang are more and more convinced that if a reaction like is not observed, this is because two types of neutrinos exist. Meantime, the construction of spark chambers (a 10 tons set full of neon gas) runs rapidly. At the beginning of 1962, all is ready to run. The accelerator of Brookhaven delivers some hundreds of millions of neutrinos per hour, among which about 40 interact clearly with the detector. In 6 cases over 40, the particle coming out of the interaction is identified as an electron, which is approximately the expected background. In 34 cases over 40 , the output particle is identified as a muon. Conclusion: the is a different particle.

If the , and the have been a unique and same neutrino, our neutrino hunters would have obtain the same numbers of muons and electrons.

The neutrino is CERNed (1963-1983)

The discovery of , and implied a natural fever among the physicists. Numerous experiments and breakthroughs, almost in the same time, about quarks and leptons, came one after an other.

During the sixties and seventies, electrons and neutrinos of high energy are used to probe the composition of nucleons (that is neutrons and protons). The evidence for quarks, then the study of it, is quite grateful to the neutrino. One sees at CERN, during the seventies, especially in 1975 and 1976, the experiments CDHS, CHARM and CHARM II, then BEBC, which all give remarkable results about quark structure of nucleons and allow to better encompass this strange force: the weak interaction.

Some photographs of detectors

BEBC
CHARM
CHARM II
CDHS

In 1970, Glashow, Illiopoulos and Maiani make the hypothesis of the existence of a second quark family. At the end of 1974, their hypothesis is confirmed by two american experiments. Second family of neutrinos, second family of quarks: a nice bridge begins to be drawn between leptons families and quark families.

In 1973, after an incredible race between the Fermilab team and the CERN team of the bubble chamber "Gargamelle", neutral currents (neutrino interaction with matter where neutrino is not transformed into an other particle like muon or electron) are discovered. In 1977, the team lead by Leon Lederman discovers at the Stanford accelerator the b quark, that is a third quarks family. Approximately at the same time, Martin Perl discovers the particle tau, that is the third leptons family. The neutrino is there: physicists can smell it but have not seen it! In 1998, it has still not been observed experimentally!

In 1983, the W boson shows its existence to the experiment UA1 by decaying in electron and anti-neutrino. Then comes the Z boson. The weak interaction and the neutrino print definitively their mark in physics history. A long way has been covered since the first beta decay recognized by Curie and Rutherford in 1898.

The neutrino dance (1983-1996...)

In the eighties, "theoretical and practical considerations" push progressively some physicists to agree on a non zero mass neutrino. Quantum mechanics allow then the oscillation of neutrinos A can, along its travel in the universe, becomes a and vice-versa.

In 1979, in an other experiment, F. Reines, still near the nuclear plant of Savannah River, undertakes the measurement of the ratio between neutral current and charged current, with anti-neutrinos on deuterium. The result is not compatible with theoretical predictions and could be explained by the oscillation of neutrinos. But no conclusion yet.

Under the sting of this result (that will later be corrected by other experiments), a team of ILL (Laue Langevin Institute) in Grenoble try to find oscillation of neutrinos near the nuclear reactor of its Institute. Then, many experiments search oscillation of neutrinos near nuclear plants around the world. Especially, the team of ILL gives birth to two teams: Goesgen in Switzerland and Bugey in France, between Chambery and Lyon. This last one implies five french laboratories, including LAPP. The two experiments Goesgen and Bugey find in 1984 two opposite results: Bugey has seen oscillations and Goesgen not. Finally, Bugey corrects the shooting direction and gives also a limit on neutrino oscillation. No neutrinos oscillation yet.
Result: if the mass difference between and is not very small (more than 0.1 eV), there is no more than 10% of mixing between the neutrinos, that is has not more than 10% of chance to transform into a .

But the history does not stop there, because the neutrino is facetious. Since 1969, a physicist named Ray Davis tried, in Homestake mine, under 3000 meters of earth and stones, to catch a few solar neutrinos per year, using a very big detector made of 600 tons of industrial solvent based on chlorine. His first results surprised. They are confirmed today, after 20 years of data: above a neutrino energy of 1 MeV, the sun emits three times less neutrinos than predicted by the standard solar model.

Astrophysicists scraped their heads and other experiments were undertaken in order to confirm this unexpected deficit. Especially, three experiments: GALLEX, SAGE and KAMIOKANDE. The experiment of Davis, HOMESTAKE, uses chloride, GALLEX uses gallium and KAMIOKANDE uses water. Theoretically, the different experiment does not see the same neutrinos, according to their origin from thermonuclear reactions in the sun.

Could the observed deficit of solar neutrinos come from neutrinos oscillation?... The idea is attractive, but the results of the experiments show that it is difficult to make it practical.

On an other hand, in 1985, S.P. Mikheyev and A.Y. Smirnov developped the work of L. Wolfenstein about neutrino oscillation enhanced by the presence of matter: this is the MSW effect. The solar neutrino deficit could come also from an oscillation during the path inside the sun. But experiment is the only truth.

Neutrinos are re-CERNed (1989-1996...)

In 1989, as early as the first months of data taking at LEP, the new CERN particle accelerator, the study of the Z boson lifetime allows to show that only three light neutrino families exist. This was a major physics result!

The shorter is the lifetime of a particle, the more undetermined is its mass. One says that its mass distribution has a width. And this width increases with the number of possibilities for the particle to decay. The Z boson, whose mean lifetime is around 10^-23 second, can decay in pairs particle, anti-particle like neutrino, anti-neutrino. The more is the number of neutrino families, the larger is the width of the Z mass distribution.

In 1992, two experiments at CERN are built in order to detect neutrino oscillations: NOMAD and CHORUS, which, thanks to neutrino oscillations, hope to see some neutrinos inside a beam of produced with the protons of the CERN SPS accelerator. The data taking began in 1994 and first results were given in 1998.

The neutrino still dance (1993-1998...)

In 1995, the GALLEX experiment publishes its final result: a deficit of about 40% over almost the whole spectrum of solar neutrinos. SAGE confirms wisely this number and KAMIOKANDE observes a deficit of 50%, but for the Bore neutrinos only (above 7.5 MeV). The HOMESTAKE experiment, sensitive to Bore and Beryllium neutrinos had seen a deficit of 70%. The mystery is still there. Depending on the solar neutrino energy, the deficit is not the same. The MSW effect could explain this selective deficit.

Finally, KAMIOKANDE observes a deficit of in the cosmic rays showers. To try to interpret all those deficits by using only neutrino oscillations interpretation is not an easy work!... And it becomes very difficult if you try to incorporate the results obtained by LSND experiment at Los Alamos: an oscillation between anti- and anti-.

In 1996, LSND experiment announced new results: 22 interactions of anti- when 4 such interactions were expected. The non zero neutrino mass hypothesis seems to be stronger, but the scientific quest is like a mountain climber: it must make sure of its hanging points before continuing to progress. Results of other experiments and confirmation from LSND are thus impatiently waited...

1998, the LSND confirmation arrives and a Japanese experiment, Super-Kamiokande, has seen also an anomaly in the number of atmospheric neutrinos and solar neutrinos. The results are still preliminary but all seems in place for a massive neutrino or for a new gift from nature (that is a new scientific discovery).

Physicists continue their quest !

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Last update: 26/06/1999 : http://wwwlapp.in2p3.fr/neutrinos/anhistory.html

http://lappweb.in2p3.fr/neutrinos/anhistory.html

The future: Particle physics in the 21st century

 

The last century has seen revolutionary discoveries in particle physics. Quarks emerged as the tiniest building blocks. We learned that antiparticles exist for each type of particle and that forces are transmitted by quantum particles called bosons. Slowly the Standard Model of particles and their interactions came into focus. Yet, although many questions have been answered, fundamental mysteries remain.

The hunt for the Higgs boson

The current theoretical framework of particle physics is deeply connected to a hypothetical particle, the Higgs boson, transmitting a new type of force. Physicists believe it is the last missing piece in the Standard Model, and its discovery would present the key to understanding why some but not all particles have mass. If nature does not provide for a Higgs boson, other particles and forces are needed to save the interactions of the Standard Model components and to explain the origin of mass.

Past experiments have failed to find the Higgs boson, although experimenters at the European Particle Physics Laboratory, CERN, may have seen the first signs of a Higgs signal in their detectors in the year 2000. In the next few years the CDF and DZero experiments at Fermilab are the only experiments in the world capable of discovering the Higgs particle, the key to understanding the property of mass.

The Search for the Higgs (article in Beamline, March 2001, PDF)

What is Electroweak Symmetry Breaking (article in FermiNews, January 1998, PDF)

Experts explain the Higgs

Higgs essay contest winners

Solving the neutrino puzzle

The MiniBooNE experiment will look for oscillations of electron neutrinos into muon neutrinos.

Neutrinos are the most elusive of elementary particles. They were postulated in 1931, but it took more than 20 years to observe the first neutrinos in an experiment. Today, we still know very little about these particles; and their biggest secret is their mass. Physicists have identified three different types of neutrinos, all much lighter than an electron. Because they fill the universe, even with their tiny mass neutrinos still could contribute as much as five percent to the total mass of the universe.

The Kamioka Observatory in Japan has found strong evidence for non-zero neutrino mass. New neutrino experiments will search for confirmation and for an understanding of the nature of neutrino mass. The experiments will look for neutrino oscillations, the transformation of one type of neutrino into another, a unique indication for neutrino mass. Fermilab hosts two neutrino experiments, MiniBooNE and MINOS, both currently under construction.

Neutrino Oscillations – what it all means

Neutrino experiments worldwide

Quark-gluon plasma

Creating collisions of high-energy particles in particle accelerators is the best way of reproducing – in a tiny region of space – the high-energy conditions of the early universe, when the temperature was billions of degrees and atoms hadn't formed yet. Physicists think that the Big Bang produced a primordial soup of particles containing free-moving quarks and gluons, the building blocks that eventually formed protons and neutrons.

View of a gold-ion collision in the STAR detector at Brookhaven National Laboratory.

Scientists at the Brookhaven National Laboratory try to recreate these conditions by colliding gold ions at high energies. Though a single proton inside the gold ions has much less energy than the protons circulating the Tevatron, the acceleration of an ion with many protons and neutrons is the ideal method of bringing matter to a "boil."

Quark-gluon plasma

Where's the antimatter?

Particle physicists can produce antimatter with accelerators, and current experiments even investigate the properties of antihydrogen. Our everyday world, however, is completely dominated by matter. Where did the antimatter go?

Scientists believe that the early universe contained as many particles as antiparticles. As they interacted with each other, a slight asymmetry in the laws of nature favored the survival of matter. Experimenters have observed this misalignment in processes involving kaons, unstable particles that contain strange quarks. The BaBar experiment at the Stanford Linear Accelerator Center and the BELLE experiment at the Japanese KEK laboratory examine whether this effect also occurs in the decay of particles containing bottom quarks. The CDF and DZero experiments at Fermilab, as well as the HERA-B experiment at the German particle physics laboratory DESY, carry out complementary research.

CP symmetry and its violation

Dark Matter

Gravitational lensing, which results in distorted images of galaxies far away, indicates the presence of additional invisible matter.

Astrophysics experiments have shown that visible, or luminous, matter accounts for less than 10 percent of the entire mass in the universe. The motion of galaxies and other scientific observations indicate the presence of gravitational forces that seem to come from an unknown type of invisible matter, called dark matter. New astrophysics experiments, including the Sloan Digital Sky Survey and the Pierre Auger Observatory supported by Fermilab, will provide more information on the extent of dark matter and its role in the evolution of the universe. The Cryogenic Dark Matter Search looks for heat created by dark matter particles passing through an ultracold detector.

Physicists hope to identify some of the elementary constituents of dark matter using future high-energy particle accelerators. Research & Development programs study the scientific merit and technological feasibility of various possibilities.

Evidence for Dark Matter

Explore the Science of Dark Matter

Fulfilling Einstein's dream

The unification of electric and magnetic forces into an electromagnetic theory represented a major achievement at the end of the 19th century. It took about 70 years before theorists achieved a comparable breakthrough: the unification of the electromagnetic force with the weak force, which is responsible for particle decay processes. The resulting electroweak theory fueled many speculations about a Grand Unified Theory that would also incorporate the strong and gravitational forces.

Albert Einstein

Einstein attempted to construct a theory that would encompass both gravity and electromagnetism – with no success. But mathematical and theoretical advances at the end of the 20th century revived Einstein's dream. Superstring theory may hold the key to constructing a theory of quantum gravity, the essential step in linking gravity to the other fundamental forces. Future experiments will provide guidance as physicists compare theoretical predictions with real-world data.

A Unified Physics by 2050?

Extra dimensions

Nobody knows the actual size and shape of elementary particles such as quarks. Experiments have yielded upper limits on their size, but nobody knows how tiny they really are. Particle physicists usually think of quarks and other fundamental particles as point-like objects that have no volume at all. String theories, however, envision particles as little loops that can vibrate like the strings of a violin.

At the subatomic level, our universe may be linked to extra dimensions.

Though we perceive our world as consisting of one time dimension and three spatial dimensions, each point in the universe could have tiny extra dimensions attached to it. Only certain types of particles and interactions would feel their presence. In the context of string theories, this novel idea could explain why at the atomic level gravity is much weaker than any other force. The latest generation of particle physics experiments is prepared to explore space and time at the smallest scales.

The search for extra dimensions

These are just some of the ideas and anticipations that physicists have. Although the Standard Model is one of the most successful and thoroughly tested theories in physics, it cannot be the final answer. Many unsolved mysteries seem to require concepts and mechanisms that go beyond our present knowledge. It will take powerful accelerators, world-class experiments and groundbreaking ideas to unravel the secrets of matter, space and time.

Eleven physics questions for the new century

Last modified 04/25/2014

 

http://www.fnal.gov/pub/science/inquiring/matter/future/index.html

RADIOACTIVITY IS 100 YEARS OLD

 

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100 years ago, Henri Becquerel discovered radioactivity. This discovery and the following scientific works made our century completely different from the previous ones. Radioactivity, this astonishing property of matter: mankind was able to extract its energy and to use it (for the best and for the worst!)

 

X-rays discovery

All begins in fact in the year 1895 with the discovery of a prussian professor, director of the Wurzburg Physics Institute: Wilhelm Roentgen. On the 8th of November, he covers with a black strong paper an apparatus that he uses to study electricity phenomena and he sees a surprising phenomena: the screen placed nearby seems shining some green light. Moreover, his hand placed behind the screen shows the shadow of his hand-bones!

Very surprised, he repeats different experiments during all the month of December, speaking to nobody, saying just to his wife that what he is studying will make people think that he became creasy! Only at the end of December, he publishes a short article, claiming for a fantastic news: the existence of an unknown and strange radiation, that is thus quickly named "X rays". For this discovery, he receives the first physics Nobel price in 1901.

Today, those "X rays" are well known to be a particular type of light, that is photons of high energy, greater than energy of UV. This discovery is a big thunder in the sky of physicists and Roentgen is asked everywhere to demonstrate the existence of X rays; mediatic travels and shows that he will almost all refuse. Two or three years later, he stops the study of X rays. His part of work in the story finishes.

Laboratory of Wilhelm Roentgen
His laboratory now reconstituted

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Radioactivity shows his nose

Henri Poincare, very excited, gives a communication about the discovery of Roentgen, during the weekly session of the French Science Academy. Henri Becquerel is there and decides to study the existence of a possible relation between those famous X rays and the fluorescence phenomena. In those times, he was studying the fluorescence of uranium salts. Once exposed to the light of sun (thus to UV photons) those salts can radiate visible light: this is called fluorescence.

He carries thus his uranium salts under the sun, places them close to photographic plates covered with black strong paper. The development of the plates shows that uranium salts radiates X rays, the only known radiation capable of impressing the plates through black paper. Fluorescent materials would be also X rays sources?

The following week, the sky of Paris is grey and covered No way to expose uranium salts to the sun. Becquerel stows his covered photographic plates and his uranium salts in a drawer. By "chance", the sun is absent during many days and the plates are left in the drawer during many days. Finally, Henri Becquerel decides nevertheless to develop his unexposed plates. Very surprised, he remarks that the plates are impressed. A new type of radiation emitted by non fluorescent uranium has gone through the strong black paper. The shadow of the copper cross that Becquerel had placed between uranium and the covered plates is visible: the new radiation has not gone through it.

Photographic plate of Becquerel impressed by the radioactivity of uranium.

Radiation emitted by some material at rest! Radiation spontaneously emitted without any trapped energy before!... What a strange phenomena! Becquerel baptises them "U rays" and continues to study those strange radiations, but only with uranium salts. It made him impossible to do the great step realised by Pierre and Marie Curie. For him, the play stops here. He has been "the lighter of the star".
Some hundred meters from the "Jardin des Plantes", where is working Becquerel, a young polish woman, Marie Sklodowska has just get married with Pierre Curie, director of studies at the Physics and Chemistry School of Paris. She works with him in his small laboratory. Eighteen months later, she presents her PhD thesis about the U-rays (radioactivity) of Henri Becquerel. She shows that, like uranium, the thorium is radioactive. And, in July of 1898, with the help of Pierre, she succeeds in isolating a new material, a million time more radioactive than uranium, that she calls "polonium". Then, from penchblende ore (many tons!), Pierre and Marie extract by hand some milligrams of an other new material, 2.5 millions times more radioactive than uranium: the radium. For this discovery, Pierre and Marie Curie receive the physics Nobel price in 1903. Some years later, Marie Curie, alone since the death of Pierre in 1906, isolates metallic radium with an electrolytic procedure and receives the Nobel price of Chemistry, in 1911.

The laboratory of Pierre and Marie Curie

One kilogram of radium during 1600 years gives more than 60 billions of Joules, equivalent to the electricity consumption of a Paris inhabitant in one year! Where does this considerable amount of energy come from, like from a magic source?... Marie Curie made the hypothesis that some unknown radiation present everywhere in the universe can be absorbed by the radium, which then reemits this energy as radioactivity. Now, we speak about weak interaction and strong interaction in order to explain radioactivity of atomic nucleus, but the idea of Marie was original and may reappears some day...?

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The study of atomic nucleus

The next step of the story is made of long and patient studies, with many fondamental breakthroughs in understanding what is matter. Rutherford, Chadwick, Curie and Villard show that the emitted radiations are of three types: the helium nuclei (alpha radiation), electrons (beta radiation) or very energetic photons (gamma radiation). Then, James Chadwick shows in 1914 that the spectrum of the beta radiation (the strongness of emission versus the energy of the electron) is continuous. This is contrary to the fundamental principle of the energy conservation!... This mystery ended with the hypothesis of a new particle emitted with the electron of beta radiation: the neutrino.
Wolfgang Pauli imagines this particle in 1930 for the sake of energy conservation principle and Enrico Fermi names it in 1933. The neutrino will then be detected only in 1956 by F. Reines and C. Cowan.

The atomic nucleus was discovered around 1911 thanks to, among others, Rutherford, Geiger and Marsden. The knowledge about it improves with a prodigious celerity: in 1932, James Chadwick discovers the neutron, while Irene and Frederic Joliot-Curie having observed the neutron decay, did not recognize it as a new particle of the nucleus. Later, knowing about the Nobel price given to Chadwick for the discovery of the neutron, Rutherford says, according to E. Segre: "For the neutron, it's Chadwick alone. Joliot-Curie are so brilliant that they will quickly have it for something else!".

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Nuclear energy

In 1934, Irene and Frederic Joliot-Curie discover the artificial radioactivity, making a great step toward the use and the control of radioactivity. For this discovery, they received the Nobel price of chemistry in 1935.

Until this date, atomic nuclei emitting radiation were found in nature: it was called the natural radioactivity. It had been known since Rutherford that this natural radioactivity changed a nucleus into an other one: for instance radium becomes finally lead after many radioactive decays. We could say that lead does not become gold but gold becomes lead! But... this change of matter was not under control. It was not possible to construct the desired chemical element as the alchemist dreamed... But Irene and Frederic Joliot-Curie, made the dream become almost reality.

They were the first to show that mankind could build under control some news radioactive nuclei. By shooting an aluminium sheet with alpha particles (helium nuclei), they were able to make radioactive phosphorus, a new isotope of the stable phosphorus that was never observed in nature. They demonstrated it by chemically isolating the phosphorus produced before it becomes silicium by its radioactivity. The creation an unnatural radioactive element is what we call the creation of artificial radioactivity.

In 1938, some physicists perceive the possibilities of the nuclear energy (badly named atomic energy). Hahn and Strassmann, two german scientists, demonstrate that the uranium nucleus can be cut in two parts: this is the fission of the nucleus. Some months later, Joliot-Curie and his colleagues Halban and Kowarski detects an emission of neutrons when an uranium nucleus is cut. Frederic Joliot-Curie even already forsees the huge energetic ressources that it could give to mankind. All his life, he will continuously fight for a pacific use of nuclear energy. In 1948, thanks to the energy and the willpower of Joliot, the first french nuclear stack, named Zoe, begins to run. It was stopped in 1976 and became a museum showing the story of the nuclear energy since Pierre and Marie Curie. Today, about 80% of the french electricity comes from nuclear energy. The big problem of radioactive wastes is not yet solved correctly, but since 1994, some serious works are made at CNRS or at CERN, to demonstrate the feasability of the coupling between a particle accelerator and a nuclear plant using thorium instead of uranium. This could produce less long lived radioactive waste and may be could give the possibility one day to "incinerate" the highly radioactive contaminants and wastes (instead of graving them 1 km under the earth surface).

But this chapter of the radioactivity history ends also with the first nuclear bomb which exploded on the 16th of July 1945, in the desert of Alamogordo, near the town of Los Alamos, and which prompted Robert Oppenheimer, director of the Manhattan project to say, looking at the explosion: "God bless us, we have created something more awful than hell".

This complete transformation of our century, which gave the horror of the two bombs of 1945 launched on human beings, was possible thanks to the discovery of radioactivity. But, don't blame the inventor of matches when pyromans use it to make criminal fires.

Radioactivity and X rays are also used today in medical care, biology, archaeology, to restore antic art, to preserve alimentation, and so on... We can hope that new possibilities of benefic applications will be found tomorrow. This is true only with the strong following condition: scientists and responsable people must be able to keep wisdom in science and in the use of science discoveries.

http://lappweb.in2p3.fr/neutrinos/centenaire/rada.html