Tuesday, August 8, 2023

4113 - NEUTRINOS - where do they come from?

 

-    4113  -  NEUTRINOS  -  where do they come from?     Pinpointing cosmic neutrino sources opens up the possibility of using the particles as a new probe of fundamental physics. Researchers have shown that the neutrinos can be used to open cracks in the reigning Standard Model of particle physics and even test quantum descriptions of gravity.


--------------  4113  -  NEUTRINOS  -  where do they come from?

-  

-    Physicists finally know where at least some of these high-energy particles come from, which helps make the neutrinos useful for exploring fundamental physics.  Since 2012, the “IceCube Neutrino Observatory” at the South Pole has detected a dozen or so cosmic neutrinos each year.

-

-   The Sun send us photons of light.  And photons are how we know and undersand our world.  But, the Sun and other parts of the universe sends us neutrinos too.  They are almost massless like photons.  They carry no electric charge, they are neutral, so do not interact with matter.

-  

-    Of the 100 trillion neutrinos that pass through you every second, most come from the sun or Earth’s atmosphere. But a smattering of the particles, those moving much faster than the rest, traveled here from powerful sources farther away.

-

-    For decades, astrophysicists have sought the origin of these “cosmic” neutrinos. Now, the IceCube Neutrino Observatory has finally collected enough of them to reveal telltale patterns in where they’re coming from.

-

-    The new map shows a diffuse haze of cosmic neutrinos emanating from throughout the Milky Way, but strangely, no individual sources stand out. “It’s a mystery” .

-

-     IceCube study from last fall was the first to connect “cosmic neutrinos” to an individual source. It showed that a large chunk of the cosmic neutrinos detected so far by the observatory have come from the heart of an “active” galaxy called NGC 1068. In the galaxy’s glowing core, matter spirals into a central supermassive black hole, somehow making cosmic neutrinos in the process.

-

-    Little is known about how the activity around some supermassive black holes generates these neutrinos, and so far the evidence points to multiple processes or circumstances.

-

-    Abundant as they are, neutrinos usually zip through Earth without leaving a trace; a  huge detector had to be built to detect enough of them to perceive patterns in the directions they arrive from. IceCube, built 12 years ago, consists of kilometer-long strings of detectors bored deep into the Antarctic ice.

-

-    Each year, IceCube detects a dozen or so cosmic neutrinos with such high energy that they clearly stand out against a haze of atmospheric and solar neutrinos. More sophisticated analyses can tease out additional candidate cosmic neutrinos from the rest of the data.

-

-    Astrophysicists know that such energetic neutrinos could only arise when fast-moving atomic nuclei, known as cosmic rays, collide with material somewhere in space. And very few places in the universe have magnetic fields strong enough to whip cosmic rays up to sufficient energies.

-

-    Gamma-ray bursts, ultrabright flashes of light that occur when some stars go supernova or when neutron stars spiral into each other, were long thought one of the most plausible options. The only real alternative was active galactic nuclei, or AGNs —galaxies whose central supermassive black holes spew out particles and radiation as matter falls in.

-

-    In 2016, IceCube began sending out alerts every time they detected a cosmic neutrino, prompting other astronomers to train telescopes in the direction it came from. They tentatively matched up a cosmic neutrino with an active galaxy called TXS 0506+056, or TXS for short, that was emitting flares of X-rays and gamma rays at the same time.

-

-    More and more cosmic neutrinos were collected, and another patch of sky began to stand out against the background of atmospheric neutrinos. In the middle of this patch is the nearby active galaxy NGC 1068. IceCube’s recent analysis shows that this correlation almost certainly equals causation.

-

-    There’s less than a 1-in-100,000 chance that the abundance of neutrinos coming from the direction of NGC 1068 is a random fluctuation.    These two AGNs appear to be the brightest neutrino sources in the sky, yet, puzzlingly, they’re very different. TXS is a type of AGN known as a blazar: It shoots a jet of high-energy radiation directly toward Earth.

-   

-     Yet we see no such jet pointing our way from NGC 1068. This suggests that different mechanisms in the heart of active galaxies could give rise to cosmic neutrinos.

Astronomers suspect there is some material surrounding the active core in NGC 1068 that blocks the emission of gamma rays as neutrinos are produced.  We know very little about the cores of active galaxies because they are too complicated.

-

-    The cosmic neutrinos originating in the Milky Way muddle things further. There are no obvious sources of such high-energy particles in our galaxy, in particular, no active galactic nucleus. Our galaxy’s core hasn’t been bustling for millions of years.

-

-   Astronomers speculate that these neutrinos come from cosmic rays produced in an earlier, active phase of our galaxy.  The accelerators that made these cosmic rays may have made them millions of years ago.

-

-    What stands out in the new image of the sky is the intense brightness of sources like NGC 1068 and TXS. The Milky Way, filled with nearby stars and hot gas, outshines all other galaxies when astronomers look with photons. But when it’s viewed in neutrinos, “the amazing thing is we can barely see our galaxy,” . “The sky is dominated by extragalactic sources.”

-

-     Neutrinos offer rare clues that a more complete theory of particles must supersede the 50-year-old set of equations known as the Standard Model. This model describes elementary particles and forces with near-perfect precision, but it errs when it comes to neutrinos: It predicts that the neutral particles are massless, but they aren’t, not quite.

-

-    Physicists discovered in 1998 that neutrinos can shape-shift between their three different types; an electron neutrino emitted by the sun can turn into a muon neutrino by the time it reaches Earth. And in order to shape-shift, neutrinos must have mass, the oscillations only make sense if each neutrino species is a quantum mixture of three different very tiny masses.

-

-   Dozens of experiments have allowed particle physicists to gradually build up a picture of the oscillation patterns of various neutrinos, solar, atmospheric, laboratory-made. But cosmic neutrinos originating from AGNs offer a look at the particles’ oscillatory behavior across vastly bigger distances and energies.

-

-   Cosmic neutrino sources are so far away that the neutrino oscillations should get blurred out  wherever astrophysicists look, they expect to see a constant fraction of each of the three neutrino types. Any fluctuation in these fractions would indicate that neutrino oscillation models need rethinking.

-

-   Another possibility is that cosmic neutrinos interact with dark matter as they travel, as predicted by many dark-sector models. These models propose that the universe’s invisible matter consists of multiple types of nonluminous particles. Interactions with these dark matter particles would scatter neutrinos with specific energies and create a gap in the spectrum of cosmic neutrinos that we see.

-

-   Or, the quantum structure of space-time itself can drag on the neutrinos, slowing them down. A group based in Italy recently argued in Nature Astronomy that IceCube data shows hints of this happening, but other physicists have been skeptical of these claims.

-

-    The exact fraction of each neutrino type depends on the source model, and the most popular models, by chance, predict that equal numbers of the three neutrino species will arrive on Earth. But cosmic neutrinos are still so poorly understood that any observed imbalance in the fractions of the three types could be misinterpreted. The result could be a consequence of quantum gravity, dark matter or a broken neutrino oscillation model, or just the still-blurry physics of cosmic neutrino production.

-

-   We need to detect many more cosmic neutrinos. IceCube is being upgraded and expanded to 10 cubic kilometers over the next few years, and in October, a neutrino detector under Lake Baikal in Siberia posted its first observation of cosmic neutrinos from TXS.

-

-    And deep in the Mediterranean, dozens of strings of neutrino detectors collectively called “KM3NeT” are being fastened on the seafloor by a robot submersible to offer a complementary view of the cosmic-neutrino sky.

-

-    What will we learn with these new eyes?

-

-

August 6,  2023                      4113

------------------------------------------------------------------------------------------                                                                                                                       

--------  Comments appreciated and Pass it on to whomever is interested. ---

---   Some reviews are at:  --------------     http://jdetrick.blogspot.com ----- 

--  email feedback, corrections, request for copies or Index of all reviews

---  to:  ------    jamesdetrick@comcast.net  ------  “Jim Detrick”  -----------

--------------------- ---  Tuesday, August 8, 2023  ---------------------------------

 

 

 

 

 

           

 

 

Posted by at

No comments:

Post a Comment

Subscribe to: Post Comments (Atom)