Friday, March 19, 2021

3098 - ASTRONOMY - unsolved mysteries?

  -  3098  - ASTRONOMY  -  unsolved mysteries?  -  These were some of the major unsolved problems in astrophysics. 


-------------------   3098 -   ASTRONOMY  -  unsolved mysteries

-------------------  Tabby’ star, formally known as KIC 8462852, is an F type main-sequence star in the constellation of Cygnus. What brought Tabby’s star in limelight is its anomalous dimming.   The maximum dimming of around 22%.

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-  Several hypotheses have been put forward to explain these fluctuations. The first one says that the star is surrounded by an uneven ring of dust.  Researchers found less dimming in the infrared light from the star than in its ultraviolet light. Any object larger than dust particles would dim all wavelengths of light equally when passing in front of Tabby’s Star.

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-   The second hypothesis says that Tabby’s star is surrounded by a cloud of disintegrating comets orbiting the star elliptically. But, the fact that a cloud of a comet can cause dimming up to 22% has cast doubt on this theory.

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------------------------   Magnetars are neutron stars with a tremendous magnetic field. The magnetic field of a typical magnetar lies between 1-100 billion Tesla. The maximum magnetic field that can be generated under special laboratory conditions is just a few hundred Tesla. Just like the neutron stars, they are about 10 miles wide and have a mass of 2-3 times that of Sun. This implies they are quite dense. A tablespoon of its material will weigh 100 million tons.

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-  The origin of such a strong magnetic field is hypothesized to be a magneto -hydrodynamic process in the turbulent, extremely dense conducting fluid that exists before the neutron star settles into its equilibrium position. 

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-  The magnetic field of a magnetar would be lethal even at a distance of 1000 kilometers due to the strong magnetic field distorting the electron clouds of the subject’s constituent atoms, rendering the chemistry of life impossible. 

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-  At a distance of halfway from Earth to the moon, a magnetar could strip information from the magnetic stripes of all credit cards on Earth. As of 2010, they are the most powerful magnetic objects detected throughout the universe.

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------------------------ Fast Radio Bursts (FRBs) are unresolved point source-like, broadband, spanning a large range of radio frequencies, millisecond flashes found in parts of the sky. The physical phenomenon that causes these bursts is still a mystery. Possible sources of FRBs are neutron stars, blackholes, or extraterrestrial intelligence.

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-  Although the exact origin and cause is uncertain, most are believed to be extragalactic. The first Milky Way FRB was detected in April 2020. The origin of FRBs is still one of the most intriguing unsolved problems in astrophysics.


------------------------ The Ultra-High Energy Cosmic Rays are the cosmic rays with unimaginably high energy: greater than 10^18 electronvolts. The “Oh My God particle” detrected by the University of Utah’s Fly’s Eye experiment on the evening of 15 October 1991 over Dugway Proving Ground, Utah was a shock to astrophysicists.

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-  They estimated its energy to be approximately 3.2×10^20 eV (50 Joules). Equivalent to  an atomic nucleus with kinetic energy equal to that of a baseball weighing 5 ounces  traveling at 60 mph. The origin of such particles is still a hypothesis. It is one of the major unsolved problems in astrophysics.

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------------------------  The solar cycle is a repeated cycle of solar fluctuations that has a period of 11 years. Every 11 years, the magnetic field of the Sun flips completely. This means that the Sun’s north and south poles switch places.

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-   The solar activity is also influenced by this cycle. The beginning of the solar cycle is the solar minimum, with minimum sunspots. Then, in the middle of the cycle, the solar activity reaches its maximum and the number of sunspots also increases.

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-  Giant eruptions on the Sun, such as solar flares and coronal mass ejections, also increase during the solar cycle. These eruptions send powerful bursts of energy and material into space. Understanding the solar cycle is still a great mystery for scientists.


------------------------   Another unsolved problem in solar physics is the corona mystery. The corona is the outermost part of the solar atmosphere. It can be seen during a total solar eclipse. The problem is that the corona has a temperature of about a million Kelvin while the surface of the Sun, the photosphere, is at about 5,900 K.

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-   How can the heat flow from cold to the hot body? How can the most basic law of thermodynamics break down? Is there any other mechanism that is taking place in the corona? If yes, then what is it? Is it the Alfven Waves?


------------------------ The “lithium problem” is an astrophysical problem on the abundance of Li-7 isotope. Minutes after the big bang, the first elements formed. These included hydrogen, helium, lithium, and trace amounts of other elements.

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-   The observed composition of the universe is consistent with the big bang model for hydrogen and helium. However, there is a discrepancy when it comes to lithium. The most widely accepted models of the Big Bang suggest that three times as much primordial lithium should exist.

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-  Several solutions have been hypothesized to solve the missing lithium problem. There might be a need for more accurate determination of the abundance of lithium in the universe. The astrophysical solution says that there is an error in calculation. Another possible way to find the remaining lithium is to make corrections in nuclear physics. Incorrect or missing reactions could give rise to the lithium problem.

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------------------------ The Hawking radiation is electromagnetic radiation that is predicted to be released by blackholes due to quantum events near the event horizon.  For all discovered and localized blackholes, this effect is too small to be measured under experimentally achievable conditions. Because of that, Hawking radiation has not been detected yet. In the meantime, physicists are building and analyzing analogous systems.

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-  In September 2010, it was thought that a laboratory-created body, simulating a white hole’s event horizon radiated an optical analog to Hawking radiation, although to this date no official confirmation of the accuracy of this experiment exists. 

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-  One of the latest predictions also links sonic blackholes (for which sound perturbations are analogous to light in a gravitational blackhole) to a form of perfect fluid flow that could simulate Hawking radiation.

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-  While it is not yet known how and when will Hawking radiation be detected, scientists are diligently working towards this purpose. What happens after such radiation is discovered is also unknown, but one can only hope that it will open a new era when it comes to understanding blackholes. 

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------------------------   A galactic rotation curve is the plot of the orbital rotational velocity of stars versus their distance from the center. Consider the solar system. Mercury orbits the Sun in 88 days while for Neptune, it takes about 165 years. Also, the orbital velocity of planets decreases as we go from Mercury to Neptune. However, this is not true for disk galaxies. Stars revolve around their galaxy’s center at equal or increasing speed over a large range of distances.

-  Rotation curve of spiral galaxy Messier 33 , and a predicted one from distribution of the visible matter. The discrepancy between the two curves can be accounted for by adding a dark matter halo surrounding the galaxy.

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-  This discrepancy has two implications. Either Newton’s laws of classical mechanics aren’t universal or there is an additional matter in the galaxy that isn’t visible to us. This invisible matter is known as dark matter. The discrepancy in the galaxy rotation curves is one of the first evidence of dark matter.

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------------------------   One of the most important unsolved problems in Astrophysics is blackholes. Blackholes first appeared in the solutions of the equations of general relativity. Though a lot of research is taking place in this field, the question is: Do the mathematical blackholes predicted by General Relativity really exist, or are they the eternally collapsing objects?

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-  The scientific community is divided into two sects: one which says that the blackholes observed are the ones that are predicted by GTR, having a singularity while others say that they aren’t the mathematical blackholes but are eternally collapsing objects. 

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-  There are many observed facts that the former cannot explain. One of them is the strength of the magnetic field. How can blackholes produce such a strong magnetic field when the only source is the particles of the accretion disk. 

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-   The model of eternally collapsing objects instead of blackholes accounts for many observed facts and is thought to be a better model. But still far away from being accepted worldwide.

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-  These were some of the major unsolved problems in astrophysics.  Here are some more:

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-  2985 - ASTRONOMY   -  how fast is universe expanding?  In order to understand where our Universe came from and where it’s going, you need to measure how much it’s expanding. If everything is moving away from everything else, we can extrapolate in either direction to figure out both our past and our future. 

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-  2933  -  ASTRONOMY  -  most important discoveries.  Below is a list of ten most important discoveries in astronomy:  

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-  2917  -  ASTRONOMY  -  measurements in astronomy?   When we try to comprehend the Universe, there’s a whole lot that doesn’t add up. All the matter we observe and try to measure, from planets, stars, dust, gas, plasma, and exotic states and objects, can’t account for the gravitational effects we see in the orbits of stars in galaxies and galaxies in clusters. 

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 -  2874  -  ASTRONOMY  -  is universe expansion real?  -  When we study the Universe, there is a whole lot that doesn’t add up. All the matter we observe and infer, from planets, stars, dust, gas, plasma, and exotic states and objects,  can’t account for the gravitational effects we see. 

-  2769 -  ASTRONOMY  -  learning from most distant stars?  -  Everything we see has happened in the past.  When you see the Sun it is as it was 8 minutes ago.  When we see our nearest star that image is 4.3 years old.   Stars in our galaxy can be 100,000’s years old.  Stars in far away galaxies are now billions of years old.  The oldest that our telescopes can see are stars that are 4,000,000,000 years older today.


-  March 19, 2021    ASTRONOMY  -  unsolved mysteries?               3097                                                                                                                                                          

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