For the primary time ever,
physicists at the world’s largest particle accelerator have observed
differences within the decay of particles and antiparticles containing a basic
building block of matter, called the quark.
The
finding could help explain the mystery of why matter exists in the least.
"It's a historic milestone," said Sheldon
Stone, a professor of physics at Syracuse University and one among the
collaborators on the new research.
Matter
and antimatter
Every particle of matter has an antiparticle, which
is identical in mass but with an opposite electrical charge. When matter and
antimatter meet, they annihilate each other. That's a controversy. the massive
Bang should have created a constant amount of matter and antimatter, and every one
of these particles should have destroyed one another rapidly, leaving nothing
behind but pure energy.
Clearly, that did not happen. Instead, about 1 in a
very billion quarks (the elementary particles that compose protons and
neutrons) survived. Thus, the universe exists. What meaning is that particles
and antiparticles must not behave entirely identically, Stone told Live
Science. they ought to instead decay at slightly different rates, with an
imbalance between matter and antimatter. Physicists call that difference in
behavior the charge-parity (CP) violation.
The notion of the CP violation came from Russian
physicist Andrei Sakharov, who proposed it in 1967 as evidence for why matter
survived the massive Bang.
"This is one amongst the standards necessary for
us to exist," Stone said, "so it's reasonably important to know what
the origin of CP violation is."
There
are six differing types of quarks, all with their own properties: up and down,
top and bottom, and charm and strange. In 1964, physicists first observed the
CP violation in reality in strange quarks. In 2001, they saw it happen with
particles containing bottom quarks. (Both discoveries led to Nobel prizes for
the researchers involved.) Physicists had long theorized that it happened with
particles containing charm quarks, too, but nobody had ever seen it.
Stone is one in every one of the researchers on the
massive Hadron Collider (LHC) beauty experiment, which uses CERN's Large Hadron
Collider, the 16.5-mile (27 kilometers) ring on the French-Swiss border that
sends subatomic particles careening into each other to re-create the flashes of
mind-boggling energy that followed the large Bang. because the particles smash
into one another, they forced the lock their constituent parts, which then
decay within fractions of a second to more stable particles.
The latest observations involved combinations of
quarks called mesons, specifically the D0 ("d-zero") meson and also
the anti-D0 meson. The D0 meson is formed of one quark and one anti-up quark
(the antiparticle of the up quark). The anti-D0 meson could be a combination of
1 anti-charm quark and one quark.Both of those mesons decay in many
ways, but a small percentage of them find themselves as mesons called kaons or
pions. The researchers measured the difference in decay rates between the D0
and also the anti-D0 mesons, a process that involved taking indirect
measurements to make sure they weren't just measuring a difference within the
initial production of the 2 mesons, or differences in how well their equipment
could detect various subatomic particles.
The bottom line? The ratios of decay differed by a
tenth of a percent.
"The means the D0 and also the anti-D0 don't
decay at the identical rate, and that is what we call CP violation," Stone
said.
And that makes things interesting. The differences
within the decays probably aren't sufficiently big to elucidate what happened
after the large Bang to depart behind such a lot matter, Stone said, though
it's large enough to be surprising. But now, he said, physics theorists get
their turn with the information.
Physicists depend on something called the quality
Model to elucidate, well, everything at the subatomic scale. The question now,
Stone said, is whether or not the predictions made by the quality Model can
explain the quark measurement the team just made, or if it'll require some type
of new physics — which, Stone said, would be the foremost exciting outcome.
"If this might only be explained by new physics,
that new physics could contain the concept of where this CP violation is coming
from," he said.
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5 Comments
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ReplyDeleteRead my comment below or link to PhotonStructure .com
DeleteInstability of threshold gammarays and mesons.
ReplyDeleteIn the case of the 1.0216 Mev gammaray, it has the same total energy as an electron and a positron. This is the "threshold gammaray" used for matter creation called "pair- formation" of an electron and a positron. These orbiting charges generate an e-m field which propagates at c. The expended energy reduces the magnitude of the rotating opposite charges which very gradually increases the binary orbital radius, and causes a redshift of the wavelength called entropy (decay). This propagation obeys the e-m "right-hand rule." The forefinger of the right hand points in the z-direction, of the photon propagation. The 3 smaller fingers curl into the palm of the right hand, and represent the e-m field. The right thumb points straight up and represents the photon amplitude.
Electric current uses free electrons but only the negative electron is a free particle. The opposite plus charge is contained in the conductor, but this causes an unstable path (not unlike the unstable gammarays above threshold energy as well as all mesons). In electric conductors, this instability manifests as thermal collisions producing heat. In superconductors, the 2/3 c electron velocity in circuit can increase to almost c, because of the more stable path with few electron collisions.
For photons, the internal charges' paths inside the unstable gammarays is due to the diameter of the internal (+,--) electrons being larger than the orbital radius. Only after this threshold energy is reached can the "pair-formation" occur with the proper e-m pulse field.
Mesons, being unstable through their full spectrum, exhibit a distinct "wobble" and are composed of two (+,--) muons, referred to as "the electron's fat cousin" having a mass up to 207 electron masses each. Meson velocities are considerably less than c, but is basically the same binary structure as the photon -- just with the much greater masses of the orbiting (+,--) muons.
Photon Mass and Instability
DeleteThe zero point energy field (AKA/"the new aether") is full of a myriad of free charges, with many almost as equally massive, or not quite aligning accurately enough, to form stable photons. These virtual particles are short-lived -- but the ones with equal but opposite charges will frequently form stable photons that may increase in energy by, for example, constructive interference. After achieving threshold gammaray energy, and being exposed to a sufficient external field, it can create an electron and a positron in a process called pair-formation. The creation operator describes this process of the supersymmetric matter creation mechanism. The annhilation process when an electron and positron merge, forming two photons of equal energy with each having 1/2 threshold energy, and traveling in opposite directions to comply with the 2nd law of thermodynamics. BTW, the threshold gammaray instability energy is 1.0216 meV, twice the mass of the electron. Gammarays below this threshold will not separate into their components. Mesons, that have their full spectrum as unstable short-lived particles, can release their two component (+,--) muons by a similar process as the unstable gammarays. After the meson reaches its lifetime, 2 oppositely charged muons of 207 electron masses each will form spontaneously (at about E(-21} sec.). Mesons have a wobble, thought to be caused by the internal muon diameters being larger than their rotational radius. This is also the case with threshold gammarays and larger. It would be a good idea to investigate whether a gammaray wobble occurs, however their internal masses (an electron and a positron) are much smaller than the internal muons. This meson spectrum could signify the final range of the e-m spectrum. Meson velocity is somewhat smaller than c, the velocity of light, and may clarify the photon's internal dynamics, which has only been available since the minute photon mass was utilized in the calculation. It demonstrates why specific energy photons have a certain wavelength, velocity, entropy and refractive qualities. The early mass calculations for atomic electron mass transitions had values so much greater than the energetic quantum transitions that it was convenient to disregard the photon mass in their calculations so they "defined" it as zero, thus throwing the baby out with the bathwater.
There is something weird about this. It appears to be a poor translation of another document. Why would a discovery by an American scientist need translating into English? Oh and Professor Stone died in 2021. So there is that.
ReplyDelete