Wednesday, March 31, 2021

3114 - BROWN DWARF - stars that do not shine so bright

  -  3114  -  BROWN  DWARF  -  stars that do not shine so bright.  Their brightness depends on their size.  The bigger stars are the brighter they are and the shorter their lives.  We are fortunate that our Sun is in the middle of the pack and should live for 10,000,000,000 years.  


                                                    

-------------  3114  -   BROWN  DWARF  -  stars that do not shine so bright           

-  Planets congeal out of debris floating around newborn stars.  They are the leftover scraps of the star formation process.  Recent discoveries of planetary bodies are 12 to 75 times the size of Jupiter, our biggest planet.  They are not quite big enough to have enough gravity to ignite hydrogen fusion at their cores.  They are called “Brown Dwarfs”.

-

-  Although they are not big enough to fuse hydrogen into helium they are big enough to fuse deuterium into helium.  They briefly start to shine as stars with this process but quickly exhaust their supply of deuterium and start to cool down like a planet.

-

-  Astronomers have found hundreds of these Brown Dwarfs floating throughout our galaxy and some even orbiting other stars like planets.  Brown Dwarfs are very faint and hard to find but estimates from astronomers are that they may be as numerous as the stars we see in our galaxy.

-

-  Planets are born in the disks of gas and dust orbiting a newborn star.  It is believed that Brown Dwarfs can not form this same way that planets do. This process is limited to about 10 to 15 times Jupiter mass.   

-

-  Most are found as independent stars not orbiting other stars.  Astronomers think they are likely failed stars, no different than full blown stars at birth but for some reason get separated from the molecular cloud that feeds them.  They end up stuck in the embryo stage and never mature.

-

-  Stars evolve depending on whatever mass they accumulate.  We know stars for two distinct properties, their brightness and their color.  Brightness is luminosity, or the intensity of their radiation. 

-

-   If we us the luminosity of our Sun as the reference equal to 1, stars have luminosities form 1/10,000 that of our Sun, called Red Dwarfs; to 1,000,000 that of our Sun, called Supergiants.  

-

-  Their brightness depends on their size.  The bigger stars are the brighter they are and the shorter their lives.  We are fortunate that our Sun is in the middle of the pack and should live for 10,000,000,000 years.

-

-  Also, the bigger the star, the more gravity that compresses it, the hotter it gets.  The color of the star tells us its surface temperature.

-

-  Color is another word for frequency, or wavelength of electromagnetic radiation in the visible range. Our eyes detect color because of the different wavelengths that reach the cones in our retina.  The temperature of a radiating body is equal to 0.0029 / wavelength. 

-

-   For example:  Our Sun is yellow light.  Its maximum intensity of radiation occurs at a wavelength of about 500 nanometers.  From the equation, known as Wien’s law, the temperature is .0029 / 5*10^-7 meters = 5,800 degrees Kelvin. 

-

-  (Kelvin is the same as Centigrade but add 273 degrees because the Kelvin scale starts zero at absolute zero, -273C).

-

-  Using this measure of temperature stars range from 2500K to 50,000K:


-  Color         Maximum Temperature, K Example star

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

-

-  Blue-violet 50,000 Mintaka

-

-  Blue-white 30,000 Spica, Rigel

-

-  White 11,000 Sirius, Vega

-

-  Yellow-white             7,500 Canopus, Procyon

-

-  Yellow              5,900 Sun, Capella

-

-  Orange              5,200 Arcturus, Aldebaran

-

-  Red-orange             3,900 Antares, Beltegeuse

-

-  Brown less than 2,500 Brown Dwarfs

-

-  Brown Dwarfs were only discovered 20 years ago.  Much more needs to be learned to understand their origins.  Learning more will help us understand the origins of stars as well as planets.

-

-  These times are great for astronomy.  So much is being learned every day.

-

-  March 31, 2021           BROWN  DWARF  STARS            617          3114                                                                                                                                                         

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

-----  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”  -----------

--------------------- ---  Wednesday, March 31, 2021  ---------------------------






- 3113 - NEUTRON STARS

  -  3113  -  NEUTRON  STARS   -  We have much more to learn about Neutron Stars.  Each property shows itself a little differently depending on our observations and the instruments we use to make the discoveries.   It is possible that Neutron Stars become Quark Stars before they become Black Holes.  


                                                 

- -----------------------  3113  - NEUTRON   STARS  

-  All stars, depending on their size, are destined to evolve into one of these three :

-

------------------  (1)  White Dwarf


------------------  (2)  Neutron Star

-

------------------  (3)  Black Hole

-

-  The White Dwarf goes through a giant Red Dwarf stage before it collapses but it is not large enough to go supernova.  The Neutron Star and Black Hole both evolve after a giant Supernova explosion.

-

------------------  (1)  White Dwarf - If a star is Sun size or up to 7 times the mass of our Sun than it will evolve into a White Dwarf.  The maximum mass a White Dwarf can have after the Red Dwarf sheds much of its mass into outer space is 1.4 Solar Mass.  This is called the “Chandrasekliar limit“, after the physicist who first developed the theory.

-

------------------  (2)  Neutron Star - If  a star is between 8 Solar Mass and 25 Solar Mass it will explode as a Supernova and the remnant core will be a Neutron Star of between 1.4 Solar Mass and 3 Solar Mass.  A 3 Solar Mass is the upper limit for a Neutron Star.  All the other prior star mass must be ejected into outer space with the Supernova explosion.

-

------------------  (3)  Black Hole - If the star is greater than 26 Solar Mass  the same Supernova explosion occurs but the remnant remaining afterwards is so large it becomes a Black Hole.  When the stellar core is greater than 3 Solar Mass the collapsed star has an escape velocity than can exceed the speed of light.  Nothing escapes and the star remnant disappears into a Black Hole.

-

-  “Neutron Stars” are exotic objects that have many strange properties.  Depending on which property we are observing these stars have been called:

-

------------------  (a)  Pulsars

-

------------------  (b)  Gamma Ray Bursters

-

------------------  (c)  X-ray Bursters

-

------------------  (d)  Magnetars

-

------------------  (e)  Soft Gamma Ray Repeaters

-

------------------  (f)  Millisecond Radio Pulsars

-

-  The neutron itself was not discovered until 1932.  But, within a year two astronomers, Fritz Zwicky and Walter Baade, proposed a theory that a massive star could collapse into a Neutron Star.  

-

-  Their theory predicted that protons and electrons could be collapsed into neutrons by the massive gravity that would squeeze the core to a density of 10^18 kilograms per meter^3.

-

-    A star with a 3 Solar Mass would end up as a Neutron Star only 17 kilometers in diameter and have a density so great that a sugar cube, centimeter^3, would weigh 2,470,000,000 tons.

-

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

-

------------------  Density = Mass / Volume


-  Inserting the mass of the Sun and the volume of a sphere:


------------------  Density = 3 * 1.989*10^30 kilograms / 4/3pi*(8.6*10^3 m )^3


------------------  Density = 2.24 * 10^18 kg/m^3

-

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

-

-  No astronomer at the time expected to ever find such a small, dense object in the vast Universe.

-

-  Then in 1967 Jocelyn Bell at Cambridge University detected radio pulses that had a regular period of exactly 1.3373011 seconds.  In 1968 astronomers found the first Pulsar in the center of the Crab Nebula in the Constellation, Taurus the Bull.

-

-  Later a pulsar neutron star was discovered in the Veil Nebula in the Constellation Cygnus the Swan.  It is 1,500 lightyears away and went supernova 10,000 years ago during Earth’s Ice Age. 

-

-  Another in the Gum Nebula in the Constellation Vela spans 60 degrees across the sky.  At its nearest it is 300 lightyears away, but it has a diameter of 2,300 lightyears.  It’s supernova occurred 11,000 years ago.  Its pulsar period is .089 seconds. 

-

-   Puppis A is another nebula with a neutron star at its center.  These nebulae are extremely beautiful and worth your time to look them up on the internet and see a Hubble Space Telescope picture.  The colors vary from pink hydrogen gas, green sulfur, to blue oxygen gas all powered by a Neutron Star.

-

-  Today there have been over 2000 Pulsar Neutron Stars discovered.  The average Pulsars has a 1 second period (60 rpm) and a 10^-15 second per second spin down rate.  The average Pulsar is 1,000,000 years old and has a magnetic flux strength of 10^12 gauss. 

-

-   The magnetic fields of Neutron Stars can very from 100,000,000 times that on Earth to 100,000,000,000,000 stronger that Earth’s field.  It is believed that the spinning star inside this magnetic field is what is causing it to loose energy and slow down.  But, not by much, 10^-15 second per second equates to 0.03 seconds per 1 million years.

-

-  Often this powerful spinning magnetic field has an axis that is offset from the stars spin axis.  An intense beam of radiation shines in a narrow cone outwardly from the magnetic poles.  The beam sweeps around the sky like a light house beacon.  If the Earth happens to be located in the right direction the beam flashes as it whips past our line of sight.  These are the pulses we see in radio waves, X-rays, and gamma rays.

-

-  The radiating beam gets generated by the spinning Neutron Star’s magnetic field acting like a giant generator.  The intense electric fields generated accelerate the charged protons and electrons located near the stars surface.  The charged particles become channeled and pour out the north and south magnetic poles to be accelerated into outer space.

-

-  The Crab Nebula Pulsar flashes at us 30 times per second. .033 seconds per rotation.  The Crab Nebula is a beautiful object to see in outer space.  It is in the Constellation Taurus 6,500 lightyears away.  

-

-  There are three main stars that outline the “V” shape of the Taurus: Nath, Aldebaran, and Zeta.  The Crab Nebula is next to the star Zeta.  It is the remnants of a Supernova explosion that occurred in the year 1054.  

-

-  The nebula that we see today is the escaping gas and dust that is lit up by the radiation and Pulsar wind from the Neutron Star at its center.  The nebula is 7,600 lightyears across.  The Neutron Star at its center is only 20 kilometers in diameter and spinning at 30 times per second.

-

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

The math and physics is between the dashed lines.  If you do not want to do the math just skim through to the next dashed line and continue learning.

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

-

-  The Crab Nebula measures 4 arc minutes or 240 arc seconds across.  Its diameter can be calculated using the formula:

-

------------------  Arc seconds = 206,265 * diameter / distance.

-

------------------  240 = 206,265 * diameter / 6500 LY / 3.26 LY / parsec

-

------------------  Diameter = 2.32 parsec * 3.26 LY/parsec

-

------------------  Diameter = 7.56 lightyears.

-

-  If the diameter is 7.56 lightyears today and the nebula is expanding at an average of 12,000 kilometers per second when did the supernova explode?

-

------------------  Time = distance / rate

-

------------------  Time = 7.56/2 lightyears radius * 9.4605*10^15 meters/LY / 12*10^5 meters/second.

-

------------------  Time = 2.98 *10^10 seconds / 3.16*10^7 seconds / year

-

------------------  Time = .943 *10^3

-

-  Time was 943 years ago, or the year 1062.  The actual year was 1054 recorded in Chinese history as being visible during the day for three weeks.

-

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

-

-  The Crab Supernova started out as a star 7 Solar Mass when it ran out of fuel and exploded as a Supernova 952 years ago.  The remnant of 3 Solar Mass collapsed down to 17 kilometers in diameter.  

-

-  We know the diameter of a Neutron Star from the calculation that the force of gravity must overcome the nuclear forces that keep the matter from collapsing.  Matter does not compress easily.  Matter is made up of atoms and atoms are made up of proton nuclei and orbiting electrons. 

-

-   If the mass is great enough and the gravity is strong enough it can overcome the resistance of the electrons to collapse into the nucleus.  This electron force is known as degenerative pressure. 

-

-   If we set the pressure from the force of gravity equal to the degenerative pressure and solve for the volume of the sphere remaining we can determine the radius of the Neutron Star sphere.

-

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

-

-  Gravitational Force = Gravitational Constant * product of Masses / distance between them squared.

-

------------------  Force of Gravity = G*m^2/r^2

-

-  G is the constant of proportionality depending on the units used in the measurements.  In our units G = 6.67*10^-11 meter^3/kilogram/seconds^2.

-

-  A star is made up of a certain number of protons and each proton has a mass of 1.67 * 10^-27 kilograms.  Since the mass of the electron is almost 2000 times smaller it is ignored in these calculations. Since the star is star is neutral charge there are the same number of protons as electrons, and the same number of neutrons.

-

-------------------  Force of Gravity = G*(N*m)^2/r^2

-

-  Gravitational pressure is the force of gravity per unit area.  In this case it is the surface area of a sphere which is equal to 4*pi*r^2.

-

------------------  Gravitational pressure = G*(N*m)^2/r^2 * (4*pi*r^2)   

-

------------------  Gravitational pressure = G*(N*m)^2/ (4*pi*r^4)   

-

------------------  The volume of a sphere, V =  4/3*pi*r^3

-

------------------  r^3 = 3*V/4*pi

-

------------------  r^4 = (3*V/4*pi)^4/3

-

-  Substituting this back into the equation for gravitational pressure:

-

------------------  Gravitational pressure = G*(N*m)^2/ (4*pi*(3*V/4*pi)^4/3)   

-

------------------  Gravitational pressure = .537 *G*(N*m)^2/ (*V)^4/3  

-

-  Since the gravitational pressure directed inward varies throughout the star and our calculation only dealt with the surface area a more rigorous calculation yields a pressure 32% of the number/volume ratio instead of 53.7%: 

-

------------------  Gravitational pressure = .32 *G*(N*m)^2/ (*V)^4/3  

-

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

-

-  The negative pressure, or degeneracy pressure due to the electrons refusal to collapse, is calculated as the ratio of the change in energy to the change in volume:

-

------------------  Degeneracy pressure = Change in energy / Change in volume

-

------------------  Degeneracy pressure = -dE / dV

-

-  This calculation is omitted because it is too complicated.  The result shows the pressure as a function of the number of neutrons per total volume of the star:

-

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

-

Degeneracy pressure = (Planck’s Constant^2/5*M) * (3*pi^2)^2/3 * (N / V)^5/3

-

Where: Planck’ Constant = 1.05*10^-34 joule * seconds

-

------------------  N = number of neutrons = number of electrons = number of protons

-

------------------  N = total mass = 3 Solar Mass / mass of a neutron

-

------------------  M = mass of a neutron = 1.67*10^-27 kilograms

-

------------------  Solar Mass = 1.989*10^30 kg

-

------------------  N  =  3 * 1.989*10^30 kg / 1.67*10^-27 kilograms

-

------------------  N  =  3.573 * 10^57 neutrons

-

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

-

-  Solving these equations for a 3 Solar Mass star and setting the two pressures equal to each other:

-

------------------  Degeneracy pressure = (1.05*10^-34 joule * sec)^2/5*1.67*10^-27 kg)* 9.569  * (3.573 * 10^57  / V)^5/3

-

------------------  Degeneracy pressure = 10.545*10^54 / V^5/3 joule^2 * sec^2/ kg

-

------------------  Gravitational pressure = .32 *G*(N*m)^2/ (V)^4/3

------------------  G  =  gravitational constant = 6.67 *10^-11 m^3/(kg *sec^2)

-

------------------  Gravitational pressure = .32 * 6.67 *10^-11 m^3/(kg *sec^2) *(3 * 1.989*10^30 kg )^2/ (V)^4/3  

-

------------------  Gravitational pressure = 75.843*10^49 /v^4/3  m^3*kg/sec^2

-

------------------  Gravitational pressure = Degeneracy pressure

------------------  75.843*10^49 /V^4/3  m^3*kg/sec^2 =  10.545*10^54 / V^5/3 joule^2 * sec^2/ kg

-

------------------  V^1/3 = .1390*10^5 meters

-

------------------  Volume = 4/3*pi*r^3

-

------------------  4/3*pi*r^3^1/3 = .1390*10^5 meters

-

------------------  Radius = 8.6 kilometers

-

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

-

-  The diameter of the 10 Solar Mass star collapses to 17.2 kilometers.  The star collapsed from a radius of 700,000,000 meters to a Neutron Star radius of 8,600 meters in less than one second. 

-

-  The bounce that occurs at the core sends a tremendous shockwave back into space blowing away most of the mass and leaving a remnant of 3 Solar Mass.  The scattered mass becomes the interstellar medium that lights in the colorful expanding nebula.

-

-    The neutron core will have temperatures in the millions degree Kelvin and a magnetic field a trillion times stronger than Earth.  The angular momentum has to be conserved in the collapse of this star so when the radius is reduced the angular spin velocity must increase to keep the momentum constant. 

-

-   Before the collapse the star was rotating once every 57 days.  After the collapse it was spun up to .00074 seconds per rotation, or 1,345 rotations per second.  An rpm of 81,000.  That is really having your engine revved up.

-

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

-

------------------  Angular momentum = mass * angular velocity * radius^2

-

-  To have the same angular momentum before and after:

-

-------------------  3 Solar Mass * 2*pi/57days * (7*10^8 m)^2 = 3 Solar Mass * 2*pi/period * (8.6*10^3 m)^2

-

------------------  Period = 7.433*10^-4 seconds per cycle

-

-  The Neutron Star is rotating 1,345 times per second.

-

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

-

If the Neutron Star is spinning 1,345 rotations per second and the radius is 8.6 kilometers the velocity at the surface is 24% the speed of light.

-

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

-

------------------  Velocity  =  1345/second * 2*pi* 8.6 km

-

------------------  Velocity = 72,678 kilometers / second

-

-  Light travels at 299,800 kilometers / second , so this 24% the speed of light.

-

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

-

-  If a particle is orbiting just above the surface of a Neutron Star its speed is 39% the speed of light:

-

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

-

-  Kepler’s law for orbiting bodies is the ratio of the square of the periods and the cube of the radius are the same.

-

------------------  Period^2 = (Radius Neutron Star / Radius of Earth)^3 * (Mass of Sun/Mass of Neutron Star)

-

------------------  Period^2 = (8.6 km / 1.5*10^8 km)^3 * (1 Solar Mass/ 1.4 Solar Mass)

-

------------------  Period^2 =  210.4*10^-24 years

-

------------------  Period = 14.5 *10^-12 years * 3.15*10^7 seconds / year

-

------------------  Period = 45.69*10^-5 seconds

-

------------------  Velocity = 2*pi*radius / period

-

------------------  Velocity = 2*pi*8.6 km / 45.69*10^-5 seconds

-

------------------  Velocity = 1.18 *10^5 km/sec

-

-  118,000 km/sec with the speed of light 299,800 km/sec means that the particle orbiting just above the surface is traveling at 39% the speed of light.  If it were traveling 100% the speed of light it would be a Black Hole and not a Neutron Star.

-

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

-

-  Over 2000 Pulsars have been discovered.  By plotting the spin-down rates versus the periods of rotation these Pulsars can be grouped into categories of Neutron Stars that have certain properties.  Pulsars tend to slow down as they loose energy.  

-

-  For example, the Crab Pulsar rotates once every 0.033 seconds, but it is slowing down at the rate of 0.000000364 seconds per day.  This is an equivalent spin-down rate of 0.4213*10^-12 seconds per seconds which puts the Crab Pulsar as a younger Pulsar above the middle of the pack. 

-

-   The full range of spin-down rates is from 10^-21 seconds per second to 10^-9 seconds per second versus their periods ranging from .001 seconds per rotation to 100 seconds per rotation.  

-

-  The Pulsars with 5, 10, 100 second periods have the most intense magnetic fields.  They are known as Magnetars and they pulse only X-rays rather than radio waves.  They are also know as X-ray Pulsars.

-

-  The crust of the Pulsar Neutron Star is composed of a rigid, superdense form of iron that quivers in response to a changing magnetic field.  Enormous stresses in the crust cause it to crack, creating star quakes and releasing blasts of gamma rays.  These Neutron Stars are known as Gamma Ray Bursters, or Soft Gamma Ray Repeaters.

-

-  Many Neutron Stars are binaries and the more massive star can feed off the less massive star.  An accretion disk can form with infalling gas adding energy to the Neutron Star spinning it even faster.  The gas in the accretion disk heats up and emits a torrent of X-rays.  These are known as X-ray Bursters.

-

-  The oldest Pulsars have radiated most of their energy and settled down to become Millisecond Radio Pulsars that are extraordinarily stable.  With spin-down rates of 10^-20 seconds per second their pulses are more stable than our best atomic clocks here on Earth.

-

-  We have much more to learn about Neutron Stars.  Each property shows itself a little differently depending on our observations and the instruments we use to make the discoveries.

-

-    It is possible that Neutron Stars become Quark Stars before they become Black Holes.  Regardless the more massive Neutron Stars are at the edge of evolving into Black Holes.

-

-    Because most everything disappears they are less exotic than Neutron Stars.  Their mass, event horizon, and spin are the only three things we have to describe them, so far.  This is just a pebble of knowledge on the shore of a whole ocean of the unknown to be explored.

-

-  March 30, 2021             NEUTRON  STARS                  625          3113                                                                                                                                                         

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

-----  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”  -----------

--------------------- ---  Wednesday, March 31, 2021  ---------------------------






Monday, March 29, 2021

3111 - EINSTEIN - Why does energy equal mass?

  -  3111 -   EINSTEIN -  Why does energy equal mass?  If you extrapolate all the way back, the universe gets smaller and smaller, it gets denser and denser, and warmer and warmer. Finally you get to a point where it's really small, really hot and dense. That's actually the Big Bang theory: that the universe started in such a condition. That's where you really have to stop.


--------------------  3111  - EINSTEIN -  Why does energy equal mass?

-   E = mc².    In plain English, it tells us that energy is equal to mass multiplied by the speed of light squared, teaching us an enormous amount about the Universe. 

-

-  This one equation tells us how much energy is inherent to a massive particle at rest, and also tells us how much energy is required to create particles (and antiparticles) out of pure energy.

-

-    It tells us how much energy is released in nuclear reactions, and how much energy comes out of annihilations between matter and antimatter.

-

-  Why does energy have to equal mass multiplied by the speed of light squared? Why couldn’t it have been any other way? 

-

-  Einstein's equation is amazingly elegant. But is its simplicity real or only apparent? Does E = mc² derive directly from an inherent equivalence between any mass's energy and the square of the speed of light? Or does the equation only exist because its terms are defined in a conveniently particular way?”

-

-  Energy is a particularly tricky thing to define. There are many examples.  There’s potential energy, which is some form of stored energy that can be released. 

-

-  There is gravitational potential energy, like lifting a mass up to a large height, chemical potential energy, where stored energy in molecules like sugars can undergo combustion and be released, or electric potential energy, where built-up charges in a battery or capacitor can be discharged, releasing energy.

-

-  There’s kinetic energy, or the energy inherent to a moving object due to its motion.

There’s electrical energy, which is the kinetic energy inherent to moving charges and electrical currents.

-

-  There’s nuclear energy, or the energy released by nuclear transitions to more stable states.

-

-  And, of course, there are many other types of energy. Energy is one of those things that we all “know it when we see it,” but to a physicist, we want a more universal definition. The best one we have is simply: extracted/extractable energy is a way of quantifying our ability to perform work.

-

-  Work has a particular definition itself: a force exerted in the same direction that an object is moved, multiplied by the distance the object moves in that direction. 

-

-  Lifting a barbell up to a certain height does work against the force of gravity, raising your gravitational potential energy; releasing that raised barbell converts that gravitational potential energy into kinetic energy; the barbell striking the floor converts that kinetic energy into a combination of heat, mechanical, and sound energy. Energy isn’t created or destroyed in any of these processes, but rather converted from one form into another.

-

-   The way most people think about E = mc², when they first learn about it, is in terms of what we call “dimensional analysis.” They say, “okay, energy is measured in Joules, and a Joule is a kilogram * meter² per second². 

-

-  So if we want to turn mass into energy, you just need to multiply those kilograms by something that’s a meter² per second², or a (meter/second)², and there’s a fundamental constant that comes with units of meters/second: the speed of light, or c.

-

-  After all, you can measure any velocity you want in units of meters/second, not just the speed of light. In addition, there’s nothing preventing nature from requiring a proportionality constant, a multiplicative factor like ½, ¾, 2Ï€, etc., to make the equation true.

-

-  What we can do is imagine that there’s some energy inherent to a particle due to its rest mass, ie: Potential energy,  and additional energy that it might have due to its motion, ie: kinetic energy. 

-

-  We can imagine starting a particle off high up in a gravitational field, as though it started off with a large amount of gravitational potential energy, but at rest.

-

-  When you drop it, that potential energy converts into kinetic energy, while the rest mass energy stays the same. At the moment just prior to impact with the ground, there will be no potential energy left: just kinetic energy and the energy inherent to its rest mass, whatever that may be.

-

-  How does a particle gains energy when it falls in a gravitational field?  There’s some energy inherent to the rest mass of a particle and that gravitational potential energy can be converted into kinetic energy (and vice versa)?  

-

-  Let’s throw in one more idea: that all particles have an antiparticle counterpart, and if ever the two of them collide, they can annihilate away into pure energy.

-

-    E = mc² tells us the relationship between mass and energy, including how much energy you need to create particle-antiparticle pairs out of nothing, and how much energy you get out when particle-antiparticle pairs annihilate. 

-

-  Instead of having one particle high up in a gravitational field, imagine that we have both a particle and an antiparticle up high in a gravitational field, ready to fall. Let’s set up two different scenarios for what could happen, and explore the consequences of both.

-

-  It is possible to create matter/antimatter pairs from pure energy, and vice versa.

-

-  Scenario 1: the particle and antiparticle both fall, and annihilate at the instant they would hit the ground. This is the same situation we just thought about, except doubled. Both the particle and antiparticle start with some amount of rest-mass energy. 

-

-  We don’t need to know the amount, simply that’s whatever that amount is, it’s equal for the particle and the antiparticle, since all particles have identical masses to their antiparticle counterparts.

-

-  Now, they both fall, converting their gravitational potential energy into kinetic energy, which is in addition to their rest-mass energy. Just as was the case before, the instant before they hit the ground, all of their energy is in just two forms: their rest-mass energy and their kinetic energy.

-

-   Only, this time, just at the moment of impact, they annihilate, transforming into two photons whose combined energy must equal whatever that rest-mass energy plus that kinetic energy was for both the particle and antiparticle.

-

-  For a photon, however, which has no mass, the energy is simply given by its momentum, p, multiplied by the speed of light: E = pc. Whatever the energy of both particles was before they hit the ground, the energy of those photons must equal that same total value.

-

-  How do photons gain energy when they fall in a gravitational field?

-

-  Scenario 2: the particle and antiparticle both annihilate into pure energy, and then fall the rest of the way down to the ground as photons, with zero rest mass. Now, let’s imagine an almost identical scenario. 

-

-   We start with the same particle and antiparticle, high up in a gravitational field. Only, this time, when we “release” them and allow them to fall, they annihilate into photons immediately: the entirety of their rest-mass energy gets turned into the energy of those photons.

-

-  The total energy of those photons, where each one has an energy of  E = pc, must equal the combined rest-mass energy of the particle and antiparticle in question.

-

-  We measure photons energies when they reach the ground. By the conservation of energy, they must have a total energy that equals the energy of the photons from the previous scenario.

-

-   This proves that photons must gain energy as they fall in a gravitational field, leading to what we know as a gravitational blueshift, but it also leads to something spectacular: the notion that E = mc² is what a particle’s (or antiparticle’s) rest mass has to be.

-

-  The physics of gravitational redshift/blueshift is a core feature of General Relativity.

When a quantum of radiation leaves a gravitational field, its frequency must be redshifted 

-

-  There’s only one definition of energy we can use that universally applies to all particles, massive and massless, alike,  that enables scenario #1 and scenario #2 to give us identical answers: E = √(m²c4 + p²c²). 

-

------------------------  Think about what happens here under a variety of conditions:

-

-  If you are a massive particle at rest, with no momentum, your energy is just √(m²c4), which becomes E = mc².

-

-  If you’re a massless particle, you must be in motion, and your rest mass is zero, so your energy is just √(p²c²), or E = pc.

-

-  If you’re a massive particle and you’re moving slow compared to the speed of light, then you can approximate your momentum by p = mv, and so your energy becomes:           E = √(m²c4 + m²v²c²). 

-

-   You can rewrite this as E = mc² · √(1 + v²/c²), so long as v is small compared to the speed of light.

-

-  Perform what’s known, mathematically, as a “Taylor series expansion“, where the second term in parentheses is small compared to the “1” that makes up the first term. 

-

-  If you do, you’ll get that E = mc² · [1 + ½(v²/c²) + ...], where if you multiply through for the first two terms, you get E = mc² + ½mv²: the rest mass plus the non-relativistic formula for kinetic energy.

-

-  Another way to derive that E = mc² for a massive particle at rest, it would be to consider a photon, which always carries energy and momentum,  traveling in a stationary box with a mirror on the end that it’s traveling towards.

-

-  When the photon strikes the mirror, it temporarily gets absorbed, and the box with the absorbed photon has to gain a little bit of energy and start moving in the direction that the photon was moving which is the only way to conserve both energy and momentum.

-

-  When the photon gets re-emitted, it’s moving in the opposite direction, and so the box having lost a little mass from re-emitting that photon has to move forward a little more quickly in order to conserve energy and momentum.

-

-  By considering these three steps the total energy and the total momentum must be equivalent. If you solve those equations, there’s only one definition of rest-mass energy that works out: E = mc².

-

-   In our Universe, energy is conserved, momentum is conserved, and General Relativity is our theory of gravitation. 

-

-  This all started with the whole universe packed together in an infinitely small point, then it exploded, and the entire mass that made up the universe was sent out into space.

-

-  An astrophysicist would tell you that everything about that statement is wrong.  That's not at all how we should think about the Big Bang.

-

-  What does "Big Bang" really mean?  The Big Bang theory is that about 14 billion years ago the universe was in a state that was much warmer and much denser, and that it expanded.

-

-  Since then space has continued to expand and has become colder.  When the universe was about 10^-32 seconds old. That's 0.0000000000000000000000000000000001 seconds.

-

-   This was not an explosion.  Here is how the idea came about.  In the early 1920s, mathematician Alexander Friedmann discovered that Einstein's general theory of relativity provides for an expanding universe. 

-

- The Belgian priest Georges Lemaître came to the same conclusion. Shortly afterwards, Edwin Hubble showed that galaxies are actually moving apart.

-

-  The galaxies are moving away from us. The light from them is “red-shifted“, meaning the waves have become longer and shifted towards the red end of the light spectrum. Not only that, galaxies are disappearing from us faster and faster.

-

-  Someday, almost all the galaxies we can currently observe in telescopes will be out of view. Eventually the stars will go out and observers will look out into an eternally dark and lonely sky.  Fortunately, that's an extremely long way off.

-

-  We can also play the story the opposite way. The galaxies are moving apart and they have been closer before.  If you take the entire observable universe and rewind all the way back, everything fit into a very, very small area.

-

-  Then we come to the point in time of the Big Bang. What happened?  It's easy to think that the Big Bang was an explosion, in which substances were thrown out, like pieces of wood flying off after a hand grenade goes off.

-

-   But the Big Bang, it's not the substance that travels out.  The universe itself expands, space itself expands.

-

-  An explosion where the mass explodes in all directions is not an accurate picture of the Big Bang.

-

-  The second myth is that the universe is expanding into something.  It is not the galaxies that are moving apart, but space in between them that's expanding.

-

-  

-  A few galaxies are blue-shifting, meaning they're moving towards us. This applies to some nearby galaxies. But over large distances, this effect is eclipsed by Hubble-Lemaître's law, which states how fast galaxies are moving away in proportion to distance. In fact, the distance increases faster than light between points that are extremely far apart.

-

-  The universe doesn't expand into anything.  The universe has an edge.

-

-  The observable universe is a bubble surrounding us that is 93 billion light-years in diameter. The more distant something is that we look at, the farther back in time we're seeing. We can't observe or measure anything farther away than the distance light has managed to travel towards us since the Big Bang.

-

-  Since the universe has been expanding, the observable universe is counter intuitively larger than 14 billion light-years.  Scientists calculate that the universe outside our bubble is much, much larger than that, perhaps infinite in size.

-

-   The universe can be "flat," it appears not to be curved. That would mean that two light rays would remain parallel and never meet. If you tried to travel to the end of the universe, you would never reach it. The universe goes on infinitely.

-

-  If the universe has “positive curvature“, it could in theory be finite. But then it would be like a kind of strange sphere. If you traveled to the "end" you would end up in the same place you started, no matter which direction you took. It's a bit like being able to travel around the world and ending up back where you started.

-

-  In either case, the universe can expand without having to expand into anything.  An infinite universe that's getting bigger is still infinite. A "spherical universe" has no edge.

-

-    The third myth is that the Big Bang had a center.  If we imagine the Big Bang as an explosion, it's easy to think that it exploded outwards, from a center. That's how explosions work.

-

-  But that wasn't the case with the Big Bang. Almost all galaxies are moving away from us, in all directions. It seems like the Earth was the center of the beginning of the universe. But it wasn't.

-

-  All other observers would see the same thing from their home galaxy.  The universe is expanding everywhere at the same time. The Big Bang didn't happen in any particular place.  It happened everywhere.

-

-  The forth myth is that the whole universe was gathered in a tiny little point.  It's true that our entire observable universe was gathered incredibly tightly together in very little space at the beginning of the Big Bang.

-

-  But how can the universe be infinite, and at the same time have been so small?  You might read that the universe was smaller than an atom at first and then the size of a football. But that analogy insinuates that space had boundaries in the beginning, and an edge.

-

-  There's nothing that says that the universe wasn't already infinite at the Big Bang.  It was just smaller in the sense that what was then a meter, has now expanded into enormous distances of many billions of light years.

-

-  When you talk about how big the universe was at certain times, it refers to our observable universe.  The whole observable universe comes from a tiny little area that you can call a point. But the point next to it has also expanded, and the next point as well. It's just that it's so far away from us that we can't observe it.

-

-  The fifth myth is that the universe was infinitely small, hot and dense.  The universe began as a “singularity“.   It was infinitely small am infinitely hot. 

-

-  Singularities are an expression for mathematics that breaks down and can't be described with ordinary physics.  The universe today is a little bigger than it was yesterday. And it's even a little bigger still than it was a million years ago. The Big Bang theory involves extrapolating this back in time. Then you need a theory for that: and that's the general theory of relativity.

-

-  If you run the general relativity theory all the way back you reach a point of infinitely high density and heat, where the size is zero.  That's pure mathematical extrapolation beyond what the theory actually allows.  You then come to a point where the energy density and temperatures are so high that we no longer have physical theories to describe them.

-

-   In order to describe such an extreme condition you need a theory that combines gravity and quantum theory. No one has been able to formulate it yet. The expectation is precisely that a “quantum gravity theory” wouldn't lead to the conclusion that everything goes back to one point.

-

-  So what happened at this time, the earliest point in the history of the universe, is still hidden from us.  That is a review I will never get to write.

-

-  3050  -

-

-   3047  -    EINSTEIN  -  are his theories real life?  One of the most mysterious components in the entire Universe is “dark energy“, which wasn’t supposed to exist. We had assumed that the Universe was a balancing act, with the expansion of the Universe and the gravitational effects of everything within it fighting against one another. 

-

-  2687  -  EINSTEIN  -  his cosmological constant?  -   In 1917 Albert Einstein completed his equations for General Relativity and a new theory for gravity.  He recognized that a problem with his equations required the contraction or the expansion of the Universe but not the static condition that everyone thought existed at the time. 

-

-  2596  - EINSTEIN  -  has theories of the Universe?  The basic principles of general relativity can be stated quite simply: The presence of matter distorts the fabric of space and time, and objects travel on the shortest path in that distorted space-time universe.  Getting to this conclusion is another story.

-

-  2556  -  Einstein’s legacy 100 years later.

-

-  2483  -   Testing Einstein’ theories.

-

-  2284  -  Einstein’s theory of gravity.

-

-  2234  -  What did Einstein say about the Universe?

-

-  2216  -  Einstein’s math and the theory of he gravity lens.

-

-  1582 -  Using the Pythagorean theory to derive the theory of relativity.

-

-  1142  -  Can Einstein’s equations pass the tests?  His equations are alone in unifying space, time, mass, energy, motion and light. 

-

-  929  -  Einstein’s Legacy.   If you can link the equations of General Relativity and Quantum Mechanics it would be a supertechifragilisticexpialedocious breakthrough in physics. 

-

-   395  -  deriving E=mc^2  using a teeter totter

-

-  409    -  Einstein is right again.  Measurements with the Gravity Probe satellite.  

-  

-  March 28, 2021  -   EINSTEIN -  Why does energy equal mass?         3111                                                                                                                                                          

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

--------------------- ---  Monday, March 29, 2021  ---------------------------






3112 - TIME - think about it?

  -  3112  -  TIME  -  think about it?    Using both optical fibers and invisible laser transmission of data, the researchers have measured the meaning of a second more accurately than ever before. They did it by looking at minute, the measure of size, not time, differences between time kept by the atoms.

---------------------  3112  -  TIME  -  think about it?

-  Measuring time gets down to measuring the length of a second.  Science now is using three different elements to measure the length of a second.  They have made some accuracy improvements:

-

-  3.25.2021,   2:15 PM.   To date, atomic clocks, which absorb and emit photons at regular frequencies to keep time are the most accurate way to measure the passage of time in seconds, but their accuracy has been stagnated for more than a decade.

-

-  Using both optical fibers and invisible laser transmission of data, the researchers have measured the meaning of a second more accurately than ever before. They did it by looking at minute, the measure of size, not time, differences between time kept by the atoms, a crucial step toward redefining time itself.

-

-   Previous attempts to measure these minute differences between how atoms keep time , referred to the ratio between them, had only ever delivered an accuracy of up to 17 digits.

That is 17 zeros after the one second decimal point.

-

-  Now using this new model, which includes the first-ever use of a ‘free-space link’ for this purpose using laser pulses of data going through the air instead of a cable, scientists have now measured this ratio reliably out to 18 digits.

-

-  The time is 3.25.2021,   2:150,000,000,000,000,001 PM  

-

-   Cesium beam atomic clocks have long reigned supreme as the element of choice in atomic clocks, but that could soon be changing.  One digit is a big deal.

-

-  Such frequency-ratio measurements are equivalent to determining the distance from Earth to the Moon to within a few nanometers.

-

-  The research team reports continued refinement of atomic clock measurements using this model has the potential to redefine the second as we know it and can help physicists test fundamental theories of the universe, including relativity and dark matter, by measuring atomic perturbations even more precisely.

-

-   The first atomic clock began ticking in 1949. It was powered by an ammonia molecule, but a cesium isotope quickly became the standard only a few years after.

-

-  Since then, scientists have relied on these incredibly precise clocks, which are largely immune to earthly headaches like earthquakes, to help keep precise time. This measurement is used to not only define time itself, but to guide satellites in orbit via GPS as well.   Such a clock, called the “Master Clock,” resides at the U.S. Naval Observatory (USNO) in Washington D.C. 

-

-  Historically, atomic clocks have worked using cesium to measure fractions of time by counting the jumps the atoms make between different energy states when exposed to certain radio-wave frequencies. 

-

-  Since 1967, the official definition of a second has been “the duration of 9,192,631,770 periods of the radiation corresponding to the transition between the two hyperfine levels of the ground state of the cesium-133 atom.  In other words, there are just over 9 billion cesium energy jumps in one second of time.

-

-  While this method has worked for decades, it is still far from perfect. The oscillation frequency of cesium clocks is in the microwave region of the electromagnetic spectrum.  The spectrum rainbow stretches from low energy radio waves to high energy gamma rays and describes all possible frequencies of incoming light.

-

-  Newer designs for atomic clocks instead focus on elements whose frequencies would in the higher frequency optical spectrum instead. These frequencies would be 100,000 times faster than the microwave range ones emitted from cesium clocks and in turn 100 times more accurate.

-

-  But before scientists can think about replacing the cesium in our atomic clocks, they have to prove that other elements would work even better. 

-

-   To better measure time more accurately the researchers used three elemental clocks:

-

------------------------------  An aluminum-ion atomic clock

-

------------------------------  One made using ytterbium

-

------------------------------  The third using strontium

-

-   The research team set up the aluminum-ion and ytterbium clocks at a National Institute of Standards and Technology lab in Boulder and the strontium clock roughly a mile away at the University of Colorado’s JILA lab.

-

-  The idea is to measure how transmitting measurement data between these distances would impact its accuracy. The data was transmitted using both a 2.2-mile long optical fiber and a 0.9-mile stretch of free-space link communication via laser pulses.

-

-  Over several months the team pinged this atomic data back and forth between the institutions to determine how reproducible and accurate their measurements were. The goal was not to choose the best element for a new atomic clock, but to instead perfect the ways these elements’ time-keeping accuracy was compared. With those new standards established, it would then be possible to find a replacement for cesium.

-

-  From their experiments, the research team was able to make the most accurate measurement to date of these ratios between the clocks and also determined that the free-space link provided the same level of uncertainty as the longer, bulkier optical fiber.

-

-  This new research has not yet shaken the longstanding definition of a second, but it has made serious progress toward ushering in a new era of atomic time-keeping. Continuing to refine and test these models could one day soon transform the meaning of a second, improving not only international timekeeping but boosting the accuracy of everything from self-driving cars to your FitBit as well via GPS.

-

-  Atomic clocks are vital in a wide array of technologies and experiments, including tests of fundamental physics. Clocks operating at optical frequencies have now demonstrated fractional stability and reproducibility at the 10^−18 level, two orders of magnitude beyond their microwave predecessors.

-

-   Frequency ratio measurements between optical clocks are the basis for many of the applications that take advantage of this remarkable precision. However, the highest reported accuracy for frequency ratio measurements has remained largely unchanged for more than a decade. 

-

-  Here we operate a network of optical clocks based on 27Al+ , 87Sr  and 171Yb , and measure their frequency ratios with fractional uncertainties at or below 8 * 10^−18. 

-  

-  Exploiting this precision, we derive improved constraints on the potential coupling of ultralight bosonic dark matter to standard model fields. Optical clock network utilizes not just optical fiber, but also a 1.5-kilometer free-space link. 

-

-  This advance in frequency ratio measurements lays the groundwork for future networks of mobile, airborne and remote optical clocks that will be used to test physical laws, perform relativistic geodesy and substantially improve international timekeeping.

-

----------------------------  Other Reviews about time, request number:

-

-   3107  -  Thinking what time is?  Everything you see is younger when you see it.  It takes time for the light to reach you and it is the speed of light that is constant.  Time is variable it depends on where you are and how fast you are moving.  It even gets more complicated. 

-

-  2691  -  Time to Think.  -  Your brain has to do the same calculations to adjust positions with time, especially astronomer’s brains.  Everything seen through the telescope is younger as you see that it is at the time you see it.  It takes time for light to reach us,  especially at astronomical distances.  Light from the Sun is 8 minutes old, and that is the closest star.

-

-  The next closest star is 4 ½ years younger as we see it.  It takes 4 ½ years for the light to reach us.

-

-  2205  -  Optical Lattice Clock.

-

-  2422  -  The Beginning of Time  -  If you could run the clocks backward 13,700,000,000 years you would reach the beginning of time.  Thought to be the creation of time and space. The end of time would be the end of endings.  The boundaries of time seem to be the boundaries of our reasoning as well

-

-  2087  -  Is Time slowing Down?

-

-  2420  - Time to Think, again


-  854 -   Time, GPS, and Entropy

-

-  2381 -   Pressed for Time

-

-  2800  -  A 24 hour Day  -  Time -  How do you go from GPS time to Universal Time, just add 19 seconds.  Why?

-

-  2523  -   Fast Speed and Short Time  -  The smallest fraction of time is 10^-43 seconds. That is how long it takes light to travel the smallest possible distance, 10^-35 meters.  If a distance got any smaller it would become a mini-blackhole (  See Reviews 2526 and 2738)

-

-  2386  -  Time is what God created  - to prevent everything from happening all at once.

-

-  2123  -   Why 60 minutes.

-

-  356  -  Time is Getting Short  -  Zeptosecond pulses ( 10^-21) are used to study nuclear events in side an atom.  We are not there yet with our technology.  Attoseconds ( 10^-18) is used to study electrons orbiting the nucleus in atoms.  Femtoseconds (10^-15) measures chemical reactions and the interactions of molecules.

-

- 2166  -  Jim’s Universal Calendar.  History from 10^-43 seconds to today summarized in 19 pages.

-

-  2379  -  Deriving Time Dilation from the Pythagorean Theorem.  Sorry, that is all the time I have.  


-  March 23, 2021          TIME  -  think about it?                               3101                                                                                                                                                          

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--------------------- ---  Monday, March 29, 2021  ---------------------------






Sunday, March 28, 2021

3110 - BLACKHOLE - first picture

  -  3110  -  BLACKHOLE  -  first picture.  The first image of a blackhole's magnetic fields is of Galaxy M87's supermassive blackhole in polarized light. The lines mark the orientation of polarization, which is related to the magnetic field around the shadow of the blackhole. 


----------------------  3110  -  BLACKHOLE  -  first picture

-   The Event Horizon Telescope (EHT) collaboration reveal how the blackhole, 55 million light-years away, appears in polarized light. The image marks the first time astronomers have captured and mapped polarization, a sign of magnetic fields, so close to the edge of a blackhole.

-

-  Scientists still don't understand how magnetic fields, areas where magnetism affects how matter moves, influence blackhole activity. Do they help direct matter into the hungry mouths of black holes? Can they explain the mysterious jets of energy that extend out of the galaxy's core?

-

-  The EHT collaboration has been studying the supermassive object at the heart of M87 for well over a decade. In April 2019, the team's hard work paid off when they revealed the very first image of a blackhole. Since then, the scientists have delved deeper into the data, discovering that a significant fraction of the light around the M87 blackhole is polarized.

-

-  Light becomes polarized when it goes through certain filters, like the lenses of polarized sunglasses, or when it is emitted in hot regions of space that are magnetized. In the same way polarized sunglasses help us see better by reducing reflections and glare from bright surfaces, astronomers can sharpen their view of the blackhole by looking at how light originating from there is polarized. 

-

-  Polarization allows astronomers to map the magnetic field lines present around the inner edge of the blackhole.

-

-  These new polarized observations of the M87 black hole are key to explaining how the galaxy is able to launch energetic jets from its core.  One of M87's most mysterious features is the bright jet of matter and energy that emerges from its core and extends at least 100,000 light years away.

-

-   Most matter lying close to the edge of a blackhole falls in. However, some of the surrounding particles escape moments before capture and are blown far out into space in the form of these jets.

-

-  Now, March, 2021,  with the new image of the blackhole in polarized light, the team has looked directly into the region just outside the black hole where this interplay between inflowing and ejected matter occurs.

-

-  The observations provide new information about the structure of the magnetic fields just outside the blackhole, revealing that only theoretical models featuring strongly magnetized gas can explain what astronomers are seeing at the event horizon.

-

-  Magnetic fields are theorized to connect blackholes to the hot plasma surrounding them.  Understanding the structure of these fields is the first step in understanding how energy can be extracted from spinning blackholes to produce powerful jets.

-

-  To observe the heart of the M87 galaxy, the EHT collaboration linked eight telescopes around the world, including the Smithsonian Astrophysical Observatory's Submillimeter Array, to create a virtual Earth-sized telescope. The impressive resolution obtained with the EHT is equivalent to that needed to image a credit card on the surface of the Moon.

-

- This unprecedented resolving power allowed the team to directly observe the blackhole with polarized light, revealing the presence of a structured magnetic field near the event horizon.  As the EHT continues to grow, future observations will refine the picture and allow astronomers to study how the magnetic field structure change over time.

-

-  The EHT collaboration involves more than 300 researchers from Africa, Asia, Europe, North and South America. The international collaboration is working to capture the most detailed blackhole images ever obtained by creating a virtual Earth-sized telescope. 

-

-  Supported by considerable international investment, the EHT links existing telescopes using novel systems creating a fundamentally new instrument with the highest angular resolving power that has yet been achieved.

-

-  The individual telescopes involved are: ALMA, APEX, the IRAM 30-meter Telescope, the IRAM NOEMA Observatory, the James Clerk Maxwell Telescope, the Large Millimeter Telescope, the Submillimeter Array, the Submillimeter Telescope, the South Pole Telescope, the Kitt Peak Telescope and the Greenland Telescope.

-

-  March 28, 2021                                                                               3110                                                                                                                                                          

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

--------------------- ---  Sunday, March 28, 2021  ---------------------------