Quantum mechanics has long classified particles into just two distinct types: fermions and bosons.
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Quantum mechanics has long classified particles into just two distinct types: fermions and bosons.

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CERN Releases 300 Terabytes of Particle Collision Data [04.22.16]
hyperspecific poll
i find those identical to me repulsive, but am attracted to my opposite
there are many identical to me and there is no way to distinguish between us
i cannot be in the same state as anyone identical to me
many people think the anti-me is actually just me going backwards in time
i am believed to have been around since the first 15 seconds of the universe
if in a box with one identical to me, our wave-function is anti-symmetric
i am always observed to spin; my intrinsic angular momentum is ħ/2
i weigh less than 10^{-30} kilograms
my charge was first measured by observing droplets of oil
when bound to a nucleus i can escape by absorbing a photon with enough energy
multiple apply to me
none of these apply to me
Edit: oh no, I forgot to say that if multiple apply, please put them in the tags if you're willing <3 (too late to change the options on the poll (>_<))
Revealing the hidden symmetries of a superconductor
A possible method for probing the properties of exotic particles that exist on the surfaces of an unusual type of superconductor has been theoretically proposed by two RIKEN physicists. The paper is published in the journal Physical Review B. When cooled to very low temperatures, two or more electrons in some solids start to behave as if they were a single particle. This can give the material some exotic properties. For example, superconductivity arises in some materials because electrons form into couples known as Cooper pairs that move through the material without facing any electrical resistance.
Read more.
[Fermions.]

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La Supersymétrie
Qu’est-ce que la supersymétrie ? Comment peut-on la visualiser ? Quelle est la différence entre les fermions et les bosons ? Toutes ces réponses en 15 minutes !
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The minus sign for fermions ultimately derives from the double cover of SU(2)↠SO(3).
Michael Weiss
Super Kamiokande
I took this picture, which is a photograph of the photomultiplier tubes in the Super Kamiokande neutrino observatory in Japan. This photograph was part of “The Universe and Art” exhibition in Singapore’s ArtScience Museum in April’17.
The Kamiokande was the first neutrino detector which could measure the direction of neutrinos and proved that they were indeed coming from the Sun. It started running in 1987 as a 2140 ton water-Cherenkov detector, situated in Kamioka mine, at a depth of 1000m.
Its’ measured flux of solar neutrinos confirmed the “Solar Neutrino Problem” which was first established by the Homestake Chlorine Solar Neutrino Experiment in 1968 by R. Davis et al. This problem was that the measured flux of neutrinos from the sun were half of the flux predicted by the Standard Solar Model. Later, in 1999, the SNO Solar Neutrino Experiment was the first to confirm the existence of neutrino oscillations, which was a solution to the solar neutrino problem.
In 1996, the Kamiokande upgraded to Super-Kamiokande, which was a 50 kiloton water-Cherenkov detector. A cherenkov detector detects cherekov radiation, which is electromagnetic radiation emitted when a charged particle with sufficiently large energy travels through the a medium (in this case, water) with a speed greater than the speed of light in that medium. It is somewhat like an “optical shock wave”. Cherenkov radiation is emitted in a cone, which when reaches the wall of the photomultiplier detectors, form a ringed pattern shape:
credit: http://www.slac.stanford.edu/econf/C040802/lec_notes/Casper/Casper.pdf
How a photomultiplier works: A photon enters it through the glass surface. It hits the photocathode which is placed on the inner surface of the glass. The photocathode, when hit by the photon, emits an electron. The electron is attracted and accelerated to the first dynode, which is charged positively by a high voltage. This causes the dynode to emit several electrons. These electrons are attracted to a second dynode, which has an even higher positive electric potential. This process repeats many times till the last dynode has a huge number of electrons. This is how the signal of a single electron is enormously amplified.
Neutrino research have spanned across particle physics, nuclear physics, astrophysics and cosmology. With the first discovery stage (of neutrino masses and mixing) over, the second discovery stage aims to solve the remaining issues:
What is the absolute value of neutrino masses?
To establish the character of the neutrino mass spectrum
To search for sterile neutrinos (does it exist?)
Are neutrinos with definite masses Majorana or Dirac particles?
To investigate effects of CP violation in the lepton sector and to determine the phase angle.
This is all so exciting as the existence of neutrino oscillation implies the need for an extension or a revamp of the Standard Model.