Saturday, December 31, 2022

3800 - MILKY WAY GALAXY

 

 -  3800  -  MILKY  WAY  GALAXY  -   The "poor old heart of the Milky Way"is a population of stars left over from the earliest history of our home galaxy, which resides in our galaxy's core regions.


---------------------  3800  -   MILKY  WAY  GALAXY

- "Galactic archaeology," analyzed data from the most recent release of ESA's Gaia Mission, using a neural network to extract metallicities for two million bright giant stars in the inner region of our galaxy.     

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-  Our home galaxy, the Milky Way, gradually formed over nearly the entire history of the universe, which spans 13 billion years. Over the past decades, astronomers have managed to reconstruct different epochs of galactic history

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-  For almost all stars, there is a "building style" that allows a general verdict on age: a star's so-called metallicity, defined as the amount of chemical elements heavier than helium that the star's atmosphere contains.

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-   Such elements, which astronomers call "metals," are produced inside stars through nuclear fusion and released near or at the end of a star's life, some when a low-mass star's atmosphere disperses, the heavier elements more violently when a high-mass star explodes as a supernova. Each generation of stars "seeds" the interstellar gas from which the next generation of stars is formed, and generally, each generation will have a higher metallicity than the rest.

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-   Milky Way stars may be confined to the central regions, or they may be part of an orderly rotating motion in the Milky Way's thin disk or thick disk. Or else, they may form part of the chaotic jumble of orbits of our galaxy's extended halo of stars which repeatedly plunge through the inner and outermost regions.

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-  Galaxy history is shaped by mergers and collisions, as well as by the vast amounts of fresh hydrogen gas that flow into galaxies over billions of years, the raw material for a galaxy to make new stars. A galaxy's history starts with smaller proto-galaxies: over-dense regions shortly after the Big Bang, where gas clouds collapse to form stars.

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-  Proto-galaxies collide and merge, they form larger galaxies. Add another proto-galaxy to these somewhat larger objects, namely a proto-galaxy that flies in sufficiently off-center ("large orbital angular momentum"), and you may end up with a disk of stars.

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-  Merge two sufficiently large galaxies ("major merger"), and their gas reservoirs will heat up, forming a complicated elliptical galaxy combining a dearth of new star formation with a complex pattern of orbits for the existing older stars.

 

-  The Miky Way Galaxy teenage years coincided with the last significant merger of another galaxy, called Gaia Enceladus/Sausage, whose remnants were found in 2018.   It sparked a phase of intensive star formation and led to a comparatively thick disk of stars we can see today. Adulthood consisted of a moderate inflow of hydrogen gas, which settled into our galaxy's extended thin disk, with the slow, but the continual formation of new stars over billions of years.

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-   The oldest stars in their teenage sample already had considerable metallicity, about 10% as much as the metallicity of our sun. Clearly, before those stars formed, there must have been even earlier generations of stars that had polluted the interstellar medium with metals.

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-   The initial formation of what later became our Milky Way involved three or four proto-galaxies that had formed in close proximity and then merged with each other, their stars settling down as a comparatively compact core, no more than a few thousand light-years in diameter.

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-  Later additions of smaller galaxies would lead to the creation of the various disk structures and the halo. But according to the simulations, part of that initial core could be expected to survive these later developments relatively unscathed. It should be possible to find stars from the initial compact core, the ancient heart of the Milky Way, in and near the central regions of our galaxy even today, billions of years later.

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-  In search of ancient core stars stars from our galaxy's ancient core the LAMOST telescope was used in due to its location on Earth and its inability to observe during the monsoon months in summer, cannot observe the Milky Way's core regions at all.

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-  Spectra are where astronomers find information about the chemical composition of a star's atmosphere, including metallicity.  Typical red giants are about a hundred times brighter than sub-giants and readily observable even in the distant core regions of our galaxy. These stars also have the added advantage that the spectral features that encode their metallicity are comparatively conspicuous, making them particularly suitable for the kind of analysis the astronomers were planning.

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-   It proved comparatively easy to identify the ancient heart of the Milky Way galaxy, the "poor old heart," given their low metallicity, inferred old age, and central location. On a sky map, these stars appear to be concentrated around the galactic center.

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-   The distances conveniently supplied by Gaia (via the parallax method) allow for a 3D reconstruction that shows those stars confined within a comparatively small region around the center, approximately 30,000 light-years across

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-  The abundance of elements like oxygen, silicon, and neon can be obtained by successively adding alpha particles (helium-4 nuclei) to existing nuclei in a process called "alpha enhancement." Their presence in such quantities indicates that the early stars obtained their metals from an environment in which heavier elements were produced on comparatively short time scales via the supernova explosions of massive stars.

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-  For an older star, like those in the poor old heart, the additional data about chemical composition and temperature allows for a reliable estimate of the star's luminosity. By comparison with how bright that star is in the sky, one can deduce the star's distance.

 

-The combination of a star's position in the sky and its distance gives us the star's three-dimensional location within the Milky Way. The information about the stars' motion towards or away from us, measured by the Doppler shift of their spectral lines, combined with their apparent motions on the sky permits the reconstruction of the stars' orbits within our home galaxy.

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- If such an analysis shows that the stars of the poor old heart belong to two or three different groups, each with its own pattern of motion, those groups are likely to correspond to the different two or three progenitor galaxies whose initial merger created the archaic Milky Way.

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December 24, 2022     MILKY  WAY  GALAXY      3800                                                                                                                                

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Friday, December 30, 2022

3799 - BLACKHOLES - merging? -

 

 -  3799 -  BLACKHOLES  -  merging?  Black Holes shouldn’t be able to merge, but dozens of mergers have been detected. “How Do They Do It?'  Who knows what lurks in the hearts of some globular clusters?


---------------------  3799  -  BLACKHOLES  -  merging?

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-  Astronomers using a collection of gravitational wave observatories found evidence of collections of smaller black holes dancing together as binaries in the hearts of globulars.

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-  What’s more, they’ve detected an increased number of gravitational wave events when some of these stellar-mass black holes crashed together.

The globular cluster NGC 6397 contains many stellar-mass black holes among its 400,000 stars.             

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-NGC 6397 orbits the Milky Way at a distance of about 8,000 light-years from Earth. It has undergone core collapse, with a tightly packed core. Not only does that core contain stars, but also white dwarfs and neutron stars, indicating the aging stellar population.        

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-  Black holes shouldn’t be able to merge. Once black holes get fairly close together in binary pairs, they can settle into stable orbits with each other. The situation changes, however, if they’re dancing together in a crowded environment. That actually describes globular clusters.

-  Those stellar agglomerations contain tens of thousands or even millions of stars packed together. Those stars are tightly gravitationally bound together, which creates a gravity “gradient” from the outside into the core.
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-   As aging supermassive stars in a globular die, some end up as stellar-mass black holes. Eventually, they sink to the core of the cluster. That’s called “mass segregation”. Eventually, they create a sort of “invisible dark core”. 

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-  Black holes in binary pairs in the cluster are most likely to merge. Any nearby massive objects can remove orbital energy from the binary pair. Astronomers call these “dynamical interactions”. The loss of energy pushes them close together and affects the shape of the orbit to make it more elongated. That takes the black hole pair out of the stable orbit they’ve enjoyed.

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-    If this is actually what’s happening, then the black holes pass closer and closer together under the effect of the gravitational interaction. Eventually, a merger occurs. That sets off gravitational waves that we can detect here on Earth. When two black holes are in such an elongated orbit, their gravitational wave signal has characteristic “fingerprints”.

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-  Since 2015, at least 85 pairs of black holes have crashed into each other and been detected by the LIGO-Virgo-KAGRA Collaboration. Gravitational wave research into these kinds of mergers requires worldwide cooperation. That’s because multiple gravitational wave detectors can make it easier for verified events to be studied.
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-  The twin LIGO observatories in the United States work together with the Virgo facility in Italy and the KAGRA observatory in Japan. They carry out joint observations and analysis of resulting data and have worked together since 2010.

-  The research team now expects to sense more mergers of binaries in globular clusters during the next LIGO-Virgo-KAGRA observing run, which begins in 2023.

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December 24, 2022       BLACKHOLES  -  merging?   3799                                                                                                                                

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3792 - JAMES WEBB TELESCOPE - 2022 accomplishments

 

            3792  -  JAMES  WEBB  TELESCOPE  -  2022 accomplishments.  It's been a year since the James Webb space telescope was launched toward the L2 Lagrange point on the far side of the Earth from the sun.

           


            ---------  3792  -  JAMES  WEBB  TELESCOPE  -  2022 accomplishments

            

            -   SEEING FARTHER INTO THE PAST THAN EVER BEFORE.  To see the precious rare photons from the most distant galaxies in the universe, the bigger the telescope, the better.  Space telescopes don't come bigger than JWST, with its 21-foot (6.5 meters) primary mirror.

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            -  The farther a galaxy is from us, the faster it is receding from us because of the expansion of the universe, so the more its light becomes stretched, shifting the light toward redder wavelengths.

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            -  The most distant galaxies, which are also the earliest galaxies we can see, emit light that is shifted all the way into near-infrared wavelengths by the time it reaches Earth. It's this redshift that prompted scientists to design JWST to specialize in near- and mid-infrared light.

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            -  Prior to JWST's launch, the most distant known galaxy was one called GN-z11. It has a redshift of 11.1, which corresponds to seeing the galaxy as it was 13.4 billion years ago, just 400 million years after the Big Bang. That was the absolute limit of what telescopes before JWST could detect.

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            -   Objects of great mass, such as galaxy clusters, warp space with their gravity, creating a magnifying lens-like effect that amplifies light from more distant objects. Astronomers began finding faint, red smudges in the background of these lenses.  These smudges have turned out to be the most distant galaxies ever seen.

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            First was a galaxy at a redshift of 12.5, called GLASS-z12 (GLASS is the name of a specific survey program, the "Grism Lens-Amplified Survey from Space"). We see this galaxy as it existed 13.45 billion years ago, or 350 million years after the Big Bang.

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            -  Galaxies with even greater redshifts soon followed. One, nicknamed Maisie's Galaxy, is seen as it existed just 280 million years after the Big Bang, at a redshift of 14.3, while another, at redshift 16.7, is seen just 250 million years after the Big Bang. There have even been claims for a galaxy at an astounding redshift of 20, which if confirmed would have existed just 200 million years after the Big Bang.

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            -  DISCOVERING WHAT LIT UP THE UNIVERSE.  Following the Big Bang, but before stars and galaxies had formed, the universe was dark and shrouded in a fog of neutral hydrogen gas. Ultimately light, particularly ultraviolet radiation, ionized that fog. But where did that light initially come from to end the cosmic dark ages?

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            -    Astronomers believe that light came either from young galaxies filled with stars, or from active supermassive black holes, which are surrounded by accretion disks of brilliantly hot gas and shoot powerful jets into space

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            -    This characteristic suggests that fully-formed galaxies were on the scene quickly, but whether they already contained supermassive black holes remains to be seen.

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            -    JWST MEASURES EXOPLANET ATMOSPHERE.  Astronomers have now found more than 5,000 exoplanets and counting, but despite this remarkable haul, we still know next to nothing about many of them.

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            -   When a planet passes in front of its star, some of the star's light filters through the planet's atmosphere, and molecules in the atmosphere can absorb some of that starlight, creating dark lines in the star's spectrum, a barcode-like breakdown of light by wavelength. Knowing what's in a planet's atmosphere, or even whether it has an atmosphere at all, can teach astronomers about how a planet might have formed and evolved, what its conditions are like and what chemical processes are taking place in that atmosphere.

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            -     In August, 2022, astronomers announced that JWST had made the first confirmed detection of carbon dioxide gas in the atmosphere of an exoplanet, in this case WASP-39b, which is 700 light years-away.

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            -    Later, in November, astronomers released a more complete spectrum showing the absorption lines of elements and molecules in WASP-39b's atmosphere, including not only carbon dioxide but also carbon monoxide, potassium, sodium, sulfur dioxide and water vapor.

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            -    The spectrum showed that there was a lot more oxygen in the planet's atmosphere than carbon, as well as an abundance of sulfur. Scientists think that sulfur must have come from numerous collisions that WASP-39b experienced with smaller planetesimals when it was forming, giving us clues to the planet's evolution that could also hint at how the gas giants in our own solar system, Jupiter and Saturn, formed.

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            -   In addition, the existence of sulfur dioxide is the first example of a product of photochemistry on a planet beyond the solar system, since the compound forms when a star's ultraviolet light reacts with molecules in a planetary atmosphere.

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            -   WEBB SEARCHES FOR HINTS OF LIFE AND HABITABILITY.   The planets of the TRAPPIST-1 system of seven rocky planets orbiting a red dwarf star located 40.7 light-years away from Earth. Four of these worlds lie in the star's putative habitable zone, where temperatures would permit liquid water to persist on the surface; given the right conditions they could potentially be habitable to varying degrees.

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            -    Models predict that TRAPPIST-1c will have an atmosphere similar to Venus, with lots of carbon dioxide. While TRAPPIST-1c is likely too hot to be habitable, determining whether it has an atmosphere and, if so, whether that atmosphere possesses carbon dioxide will be a big step toward characterizing Earth-size worlds.

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            -   It will also be a big task, requiring 100 hours of observing time with JWST, which is tackling about 10,000 hours of observations during its first year of science.

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            -   JWST is targeting the other worlds in the TRAPPIST-1 system that are more likely to be habitable, as well as similar worlds around other nearby stars. Astronomers will be on the lookout for biosignatures, such as the presence of both methane and oxygen in an atmosphere.

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            -  The discovery of photochemical reactions in WASP-39b's atmosphere is also an important step, since photochemical reactions drive the formation of the carbon-based molecular building blocks of life.

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            -  JWST STUDIES COSMIC CHEMISTRY & GALAXY EVOLUTION.   Some stars live for billions upon billions of years, but others exist for just a short time before either exploding in a supernova or expanding to become a red giant that then puffs off its outer layers into deep space. In both situations, the stars disperse large amounts of cosmic dust formed from elements heavier than hydrogen and helium across space.

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            -    It turns out that there is a relationship between a galaxy's mass, its star-formation rate and its chemical abundances. Deviations from this relationship at high redshift might indicate that galaxies evolved differently in the early universe.

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            -    Prior to JWST, astronomers could only reliably measure the abundances of various elements in galaxies up to a redshift of 3.3; in other words, galaxies that existed about 11.5 billion years ago. But how abundant these heavy elements were in galaxies earlier than this is a bit of a mystery.

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            -    Early results from JWST have shown that the relationship between star formation and mass does hold for galaxies at redshifts as high as 8, but that their abundance of heavier elements is three times lower than expected. This discrepancy suggests that stars and galaxies formed more quickly than we realized, before enough generations of stars had the chance to die out and disperse their elements into the cosmos.

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            -    JWST SETS ITS SIGHTS ON THE SOLAR SYSTEM.  Brilliant Jupiter, its faint rings and several of its small moons imaged by JWST.

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            -    JWST's images showed Jupiter's faint rings and some of its small moons, as well as the planet's atmospheric bands and auroras. By observing in near- and mid-infrared light, with the high resolution that JWST's giant mirror provides, astronomers are able to peer deeper into Jupiter's atmosphere to see what's going on beneath the cloud tops and learn how deeply the clouds extend.

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            -    JWST has also imaged faraway Neptune, Saturn's moon Titan and Mars. While JWST's portrait of the Red Planet shows temperature variations on Mars' surface and absorption by carbon dioxide in its atmosphere. In the future, JWST will observe Mars to track more tenuous gases, such as mysterious seasonal plumes of methane that could originate in either geological or biological activity.

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            -    One of the Hubble Space Telescope's most iconic images was that of the Pillars of Creation, columns of molecular gas many light-years long found in the Eagle Nebula. Those columns are cosmic nurseries where stars are born. JWST has revisited the Pillars of Creation, and the resulting images in near- and mid-infrared light are just as special as the original.

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            -    JWST's infrared vision is able to penetrate through the dust in the Pillars to gain a better view of the star formation going on inside, showing knots of molecular gas on the verge of collapsing into nascent stars. When those stars are just a few hundred thousand years old, they begin to shoot out jets that erode the edges of the Pillars.

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            -   JWST CHANGED HOW SPACE TELESCOPES ARE BUILT.  JWST's massive, golden primary mirror, formed by unfolding 18 hexagonal segment, was brand-new engineering to permit a telescope of such great size to be launched into space.

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            -  JWST was launched on December 25, 2021, the $10 billion infrared  observatory was designed to learn how galaxies form and grow, to peer far back into the universe to the era of the first galaxies, to watch stars be born inside their nebulous embryos in unprecedented detail, and to probe the atmospheres of exoplanets and characterize some of the closest rocky worlds.

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            -   The complexity of the James Webb Space Telescope, includes its fold-out, segmented 21-foot mirror and its delicate sun-shield the size of a tennis cour

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            -   The main reason that JWST is performing so well is because of its superlative optics, which are able to achieve their maximum potential resolution for the majority of infrared wavelengths that the telescope observes in. This success means that JWST's images have a clarity to them that were unobtainable by the likes of the Hubble Space Telescope and NASA's retired Spitzer Space Telescope, or larger telescopes on the ground such as those at the Keck Observatory in Hawaii, whose vision is blurred by Earth's atmosphere.

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            -    But with JWST, individual stars so close together they were once indistinguishable can now be resolved; the structures of very distant galaxies are now discernible; and even something close by such as the rings of Neptune pop with the most detail seen in decades.

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            -   Normally, faint details or features around a bright object, such as the dark and tenuous rings around blue Neptune, are difficult to see against the glare of the bright object. To counteract this, an instrument is required to have the characteristic of "high dynamic range" to take in both the faint and the bright at the same time.

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            -   It's not only the planets of our solar system that JWST is scrutinizing. A key aim of the telescope is to detect the composition of exoplanets' atmospheres using a technique called transmission spectroscopy. As a planet transits its star, the star's light shines through the planet's atmosphere, but atoms and molecules within that atmosphere can block some of the light at characteristic wavelengths, which gives away the composition of the atmosphere.

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            -  The first exoplanet result released from JWST was the transmission spectrum of WASP-39b, which is a "hot Jupiter" exoplanet orbiting a sun-like star located 700 light-years away. JWST detected carbon dioxide in WASP-39b's atmosphere, the first time the gas has ever been detected on an exoplanet.

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            -   Other gases present included carbon monoxide, potassium, sodium, water vapor and sulfur dioxide, the last of which can only be created through photochemistry when atmospheric gases react with the ultraviolet light from the planet's star.

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            -   In particular, the TRAPPIST-1 planetary system of seven worlds orbiting an M-dwarf 40 light-years away is a key target of the JWST. Preliminary results, which failed to detect thick blankets of hydrogen surrounding some of the TRAPPIST-1 worlds, were released during a conference held at STScI in December, but we'll have to be patient for more comprehensive results from these planets, of which up to four could reside in their star's habitable zone.

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            -   Currently, astronomers do not understand what determines why stars form with the masses that they have, only that low-mass stars are much more common than luminous high-mass stars, at least in the local universe. Was this still the case over 13 billion years ago in the first galaxies? Answering that question could help explain both how galaxies formed and what ended the universe's dark ages.

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            -  The JWST has impressed scientists in the six months that it has been gathering data since becoming fully operational in June, but the real fireworks are still to come with major discoveries awaiting us.

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            December 24, 2022                            3797                                                                                                                               

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

            -----  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”  -----------

            --------------------- ---  Friday, December 30, 2022  ---------------------------

             

             

             

             

                     

             

             

3801 - PHYSICS - what is the “standard model”?- -

 

 -  3801  -  PHYSICS  -  what is the “standard model”?    The Standard Model explains the fundamental physics of how the universe works. It has endured over 50 trips around the sun despite experimental physicists constantly probing for cracks in the model's foundations.


---------------------  3801  -  PHYSICS  -  what is the “standard model”?-

-   There is a bit more to be learned about how the universe works.  For example:  Neutrinos represent three of the 17 fundamental particles in the Standard Model. They zip through every person on Earth at all times of day.

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-  In 2021, physicists around the world ran a number of experiments that probed the Standard Model. Teams measured basic parameters of the model more precisely than ever before. Others investigated the fringes of knowledge where the best experimental measurements don't quite match the predictions made by the Standard Model. And finally, groups built more powerful technologies designed to push the model to its limits and potentially discover new particles and fields.

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-The Standard Model of physics allows scientists to make incredibly accurate predictions about how the world works, but it doesn’t explain everything.

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-In 1897, J.J. Thomson discovered the first fundamental particle, the electron, using nothing more than glass vacuum tubes and wires. More than 100 years later, physicists are still discovering new pieces of the Standard Model.

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-The Standard Model is a predictive framework that does two things. First, it explains what the basic particles of matter are. These are things like electrons and the quarks that make up protons and neutrons.              

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-  Second, it predicts how these matter particles interact with each other using "messenger particles". These are called bosons, photons and the famous Higgs boson, and they communicate the basic forces of nature. The Higgs boson wasn't discovered until 2012 after decades of work at CERN particle accelerator.

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-  The Standard Model is incredibly good at predicting many aspects of how the world works, but it does have some holes.  It does not include any description of gravity. While Einstein's theory of General Relativity describes how gravity works, physicists have not yet discovered a particle that conveys the force of gravity.                                                                     -

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-  A proper "Theory of Everything" would do everything the Standard Model can, but also include the messenger particles that communicate how gravity interacts with other particles.

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-  Another thing the Standard Model can't do is explain why any particle has a certain mass.  Physicists must measure the mass of particles directly using experiments. Only after experiments give physicists these exact masses can they be used for predictions.

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-  Recently, physicists on a team at CERN measured how strongly the Higgs boson feels itself.   Another CERN team also measured the Higgs boson's mass more precisely than ever before. And finally, there was also progress on measuring the mass of neutrinos.    

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-   Physicists know neutrinos have more than zero mass but less than the amount currently detectable. A team in Germany has continued to refine the techniques that could allow them to directly measure the mass of neutrinos.

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-  Projects like the Muon g-2 experiment highlight discrepancies between experimental measurements and predictions of the Standard Model that point to problems somewhere in the physics.

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-  Projects like the Muon g-2 experiment highlight discrepancies between experimental measurements and predictions of the Standard Model that point to problems somewhere in the physics.

-In April 2021, members of the Muon g-2 experiment at Fermilab announced their first measurement of the magnetic moment of the muon. The muon is one of the fundamental particles in the Standard Model, and this measurement of one of its properties is the most accurate to date.

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-  The reason this experiment was important was because the measurement didn't perfectly match the Standard Model prediction of the magnetic moment. Basically, muons don't behave as they should. This finding could point to undiscovered particles that interact with muons.

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-  In April 2021, physicist Zoltan Fodor showed how they used a mathematical method called Lattice QCD to precisely calculate the muon's magnetic moment. Their theoretical prediction is different from old predictions, still works within the Standard Model and, importantly, matches experimental measurements of the muon.

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-  The disagreement between the previously accepted predictions, this new result and the new prediction must be reconciled before physicists will know if the experimental result is truly beyond the Standard Model.

-New tools will help physicists search for dark matter and other things that could help explain mysteries of the universe.

         

-First, the world's largest particle accelerator, the Large Hadron Collider at CERN, was shut down and underwent some substantial upgrades. Physicists just restarted the facility in October, and they plan to begin the next data collection run in May 2022.

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-  The upgrades have boosted the power of the collider so that it can produce collisions at 14 TeV, trillion electrpn volts.  This is up from the previous limit of 13 TeV. This means the batches of tiny protons that travel in beams around the circular accelerator together carry the same amount of energy as an 800,000-pound passenger train trading at 100 mph.At these incredible energies, physicists may discover new particles that were too heavy to see at lower energies.                                                                                                                                                         

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  Some other technological advancements were made to help the search for dark matter. Many astrophysicists believe that dark matter particles, which don't currently fit into the Standard Model, could answer some outstanding questions regarding the way gravity bends around stars, gravitational lensing, as well as the speed at which stars rotate in spiral galaxies. 

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-  The development of immense new detectors like Hyper-Kamiokande and DUNE. Using these detectors, scientists will hopefully be able to answer questions about a fundamental asymmetry in how neutrinos oscillate. They will also be used to watch for proton decay, a proposed phenomenon that certain theories predict should occur.

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-  2021 highlighted some of the ways the Standard Model fails to explain every mystery of the universe. But new measurements and new technology are helping physicists move forward in the search for the “Theory of Everything”

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December 30, 2022      PHYSICS  -  what is the “standard model”     3801                                                                                                                                

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

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

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

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

--------------------- ---  Friday, December 30, 2022  ---------------------------