Tuesday, July 30, 2019

Relativity: Eugene Khutoryansky's explanation


This post is a collection of quotes from Eugene Khutoryansky's relativity videos on YouTube. I recommend that everyone should watch the videos linked below and other physics videos on Eugene's channel. There are 37 quotes divided into 10 sections.

Click here to view Eugene's channel

1. Two central principles of Einstein's relativity
2. Time and moving near the speed of light
3. Disagreement on simultaneity
4. Simultaneity and length contraction
5. Length contraction near the speed of light
6. Length contraction at the speed of light
7. Energy, mass and the speed of light
8. Relativistic mass and rest mass
9. Traveling across the universe and back
10. Cause of gravity

1. Two central principles of Einstein's relativity


"Einstein's theory of relativity is based on two principles. The first principle is that if you have two objects and nothing else then it is not possible to tell which object is moving and which object is standing still... In general, any observer can believe that they are standing still and that the rest of the universe is moving around them." (Albert Einstein's Theory of Relativity, 2011)

"The second principle is the speed of light is the same for all observers." (Albert Einstein's Theory of Relativity, 2011)

2. Time and moving near the speed of light


"Suppose Adam fires a laser at the ground, which bounces off a mirror and Adam measures the time it takes for the light to return to the spaceship. From Adam's perspective, the laser light goes straight up and down. From Sarah's perspective, the laser light follows a 'V' shape path. The 'V' shape path is longer than the straight up and down path." (Albert Einstein's Theory of Relativity, 2011)

"Since the speed of light is the same for all observers, from Sarah's perspective it takes a longer amount of time for the laser light to return to the spaceship. But if Sarah looks at Adam's clock, she will see that Adam's clock read less time in between when he fired the laser and when he received the reflected light back." (Albert Einstein's Theory of Relativity, 2011)

"The closer that a spaceship approaches the speed of light, the slower the time inside the ship will flow. If the speed of the spaceship was equal to the speed of light, then time inside the ship would stop altogether. However, no matter how fast the spaceship travels, Adam will never notice that time for him is going slower." (Albert Einstein's Theory of Relativity, 2011)

"Everything is slower by the exact same amount, including the speed of his thoughts, so time for Adam appears to be flowing normally... Adam will think that everyone else's clocks are moving slowly." (Albert Einstein's Theory of Relativity, 2011)

3. Disagreement on simultaneity


"Suppose there are three ships moving together and Adam fires a laser to the two other ships. From Adam's perspective, all three ships are standing still and the two other ships will receive the laser light at the same time." (Albert Einstein's Theory of Relativity, 2011)

"Sarah must see the light from both lasers move at the same speed. Therefore, Sarah will see the left ship receive the laser light before the right ship. But we know that the clocks on the two ships read the same time when they each receive the laser light. This means that Sarah must see the clock on the left spaceship running ahead of the clock on the right spaceship." (Albert Einstein's Theory of Relativity, 2011)

"According to Einstein's theory of relativity, different observers will disagree on whether or not two events happened at the same time and no observer is more correct than any other." (Nature of Time and Simultaneity, 2015)

"If two events happened at both the same time and place, then everyone will agree that the two events happened together." (Nature of Time and Simultaneity, 2015)

"Even after the time necessary for light to travel is taken into account, different observers will still disagree about whether or not two different events happened at the same time." (Nature of Time and Simultaneity, 2015)

4. Simultaneity and length contraction


"Suppose that Adam sends a command for all the ships to fire their engines at the same time. From Adam's point of view, all the ships accelerate together and the distance between them stays the same." (Albert Einstein's Theory of Relativity, 2011)

"From Sarah's point of view, time on the left ship is running ahead of time on the right ship. Sarah will see the left ship accelerate first and the right ship accelerate last and the distance between the ships will shrink." (Albert Einstein's Theory of Relativity, 2011)

"Each spaceship can be thought of as being made up of smaller spaceships, with the distance between them shrinking as they move faster." (Albert Einstein's Theory of Relativity, 2011)

5. Length contraction near the speed of light


"The closer a spaceship approaches the speed of light, the shorter it becomes." (Albert Einstein's Theory of Relativity, 2011)

"Everything inside the spaceship has gotten shorter by the exact same amount, including Adam himself and all his rulers, so everything inside the spaceship will look normal to Adam." (Albert Einstein's Theory of Relativity, 2011)

"From Adam's point of view, his ship is standing still and it is the rest of the universe that is moving. Therefore Adam will think its the rest of the universe that has gotten shorter." (Albert Einstein's Theory of Relativity, 2011)

6. Length contraction at the speed of light


"From light's point of view, the journey took no time because the entire universe has shrunk to absolute zero length and the two planets have therefore always been at the same location." (At the speed of light, what would you see? 2015)

"From light's point of view there is no 'journey', because every point along its path is located at exactly the same position in space and they all pass by at exactly the same moment in time." (At the speed of light, what would you see? 2015)

7. Energy, mass and the speed of light


"Suppose two ships throw identical balls at each other. The balls bounce off each other and return to each ship. From Sarah's point of view, time on Adam's ship is moving slowly. From Sarah's point of view, Adam throws his ball much more slowly." (Albert Einstein's Theory of Relativity, 2011)

"From Sarah's point of view, Adam's ball and everything on Adam's ship must have more [relativistic] mass. Otherwise, Adam's ball would not have had enough momentum to cause her ball to bounce back. This is the meaning of E = MC^2." (Albert Einstein's Theory of Relativity, 2011)

"As an object moves with more energy, its [relativistic] mass increases. This is why nothing can travel faster than the speed of light." (Albert Einstein's Theory of Relativity, 2011)

"As an object gets close to the speed of light, its [relativistic] mass becomes so big that an infinite amount of energy would be required to move it faster." (Albert Einstein's Theory of Relativity, 2011)

8. Relativistic mass and rest mass


"It is true that the gravitational mass of an object does not change. That is, the gravitational attraction of an object does not increase due to the fact that the object is moving close to the speed of light." (Relativistic Mass and Energy, 2015)

"What does change is the more an object's speed approaches the speed of light, the greater the force necessary to increase the object's speed even further." (Relativistic Mass and Energy, 2015)

"Another way to describe this phenomena is to introduce the concept of relativistic mass, and to say that the relativistic mass of the object increases." (Relativistic Mass and Energy, 2015)

"The relativistic mass can never be used to calculate the gravitational attraction of an object." (Relativistic Mass and Energy, 2015)

"The mass that an object has when it is at rest is what we call the object's 'rest mass' and its is the rest mass that we use to determine gravity, even when the object is in motion." (Relativistic Mass and Energy, 2015)

9. Traveling across the universe and back


"From Sarah's point of view, Adam will travel the length of the entire universe while Adam's clock moves forward by only a few seconds...  To Adam, the length of the universe passes in a few seconds because the length of the entire universe has shrunk to almost zero." (Albert Einstein's Theory of Relativity, 2011)

"For Adam to return back to Earth, he will eventually need to fire his rockets to turn around.... In order to believe that his spaceship is standing still, he needs to also believe that there is now a gravitational field present that is cancelling out the force from his rockets." (Twin Paradox in General Relativity, 2015)

"It is only during the very  brief moment when Adam is firing his rockets to turn around that he believes this external gravitational field is present." (Twin Paradox in General Relativity, 2015)

"During the very brief moment when he fires his engines, he sees time on Earth flowing so extremely fast that this far more than compensates for the fact that he sees time on Earth flowing slowly during the rest of his journey." (Twin Paradox in General Relativity, 2015)

"When Adam returns to Earth, they will both agree that more time has passed for Sarah, but they will disagree on the reason why." (Twin Paradox in General Relativity, 2015)

10. Cause of gravity


"The mass of the Earth warps spacetime. This causes the clocks near the Earth to run slower than clocks far away." (Gravitational Time Dilation causes gravitational 'attraction', 2016)

"Suppose we have an object that is initially at rest relative to the Earth. This object will move through time. But different parts of the object will want to move through time at different rates. As the object continues traveling through spacetime in a straight line, the object starts moving towards the Earth." (Gravitational Time Dilation causes gravitational 'attraction', 2016)

"Even if the Earth is not moving through space, it would still be moving through time. The path that the Earth takes through space and time is what we will call its 'world line'." (Gravitational Time Dilation causes gravitational 'attraction', 2016)

"The full picture is not accurately represented with the visualization that is typically given of the Earth causing an indentation in a rubber sheet. Aside from the fact that this image falsely implies that objects are more likely to be attracted to the South Pole, this visualization is incomplete in that it does not show time as one of the four dimensions." (Gravitational Time Dilation causes gravitational 'attraction', 2016)

Saturday, July 27, 2019

List of Eugene Khutoryansky physics videos


This post is a list of physics videos on Eugene Khutoryansky's YouTube channel. The sections are based on a physics outline I created in an earlier post which can be found at this link. A further explanation of this post can be found at this link.

Click here to view Eugene's channel

This post was last updated July 27th, 2019. There are 66 videos listed below organized into 20 sections:

1. Cosmology (3)
2. Astronomy (0)
3. Particles (1)
4. Elements (0)
5. Molecules (0)
6. Chemical reactions (0)
7. Thermodynamics (3)
8. Classical mechanics (4)
9. Fluid dynamics (1)
10. Special relativity (8)
11. Gravity (5)
12. Optics (5)
13. Sound (0)
14. Electromagnetism (22)
15. Quantum mechanics (10)
16. Strong force (1)
17. Weak force (1)
18. String theory (0)
19. Dark matter (0)
20. Dark energy (0)

1. Cosmology (3)


Big Bang in an infinite universe (4:22)
Infinite universe? (11:59)
Philosophy of physics (20:04)

2. Astronomy (0)


3. Particles (1)


Neutron generators using particle accelerators (5:41)

4. Elements (0)


5. Molecules (0)


6. Chemical reactions (0)


7. Thermodynamics (4)


Thermodynamics and the end of the universe (35:56)
Entropy: Why the 2nd Law of Thermodynamics is a fundamental law of physics (15:10)
Entropy is not disorder: micro-state vs macro-state (10:28)
Maxwell's demon - Why information is entropy (10:40)

8. Classical mechanics (4)


Physics: laws of motion - Newton and beyond (26:02)
Torque, levers and the universal law of rotation (16:58)
Momentum and angular momentum of the universe (10:47)
Euler-Lagrange equation explained intuitively (18:22)

9. Fluid dynamics (1)


Aerodynamics - How airplanes fly, maneuver and land (8:36)

10. Special relativity (8)


Albert Einstein's theory of relativity (16:18)
Nature of time and simultaneity (8:13)
Relativistic mass and energy (5:19)
Minkowski spacetime: spacetime in special relativity (7:37)
Einstein's relativistic train in a tunnel paradox: special relativity (11:18)
At the speed of light, what would you see? (4:38)
Trying to go faster than the speed of light (4:00)

11. Gravity (5)


Gravitational time dilation causes gravitational 'attraction' (4:49)
Gravity's effect on the flow of time in general relativity (11:02)
Twin paradox in general relativity (10:40)
Einstein's gravito-electromagnetism (12:44)
Einstein's field equations of general relativity explained (28:22)

12. Optics (5)


Waves: light, sound and the nature of reality (24:58)
Lenses, refractions and optical illusions of light (16:03)
Polarization of light (19:51)
Diffraction interference patterns with phasor diagrams (17:31)
Mirrors - Why don't we see reflections in white objects? (7:24)

13. Sound (0)


14. Electromagnetism (22)


Electromagnetism - Maxwell's Laws (48:30)
Voltage, current, electricity, magnetism (11:40)
Inductors and inductance (8:36)
Induction motors - Why and how an induction motor works (10:50)
Electric circuits: basics of the voltage and current laws (9:43)
Battery energy and power (5:56)
Electric potential: visualizing voltage (8:00)
Three phase electric power and phasor diagrams explained (5:51)
AC current impedance - Alternating voltage for inductors, capacitors (8:47)
AC to DC voltage rectifiers (5:14)
Voltage multiplier: generating over 100,000 volts DC (9:14)
Transistors- field effect and bipolar transistors (12:17)
Transformers - electric power transmission (9:42)
Resistors - Ohm's law is not a real law (5:52)
Transmission lines - signal transmission and reflections (4:59)
Capacitors and capacitance: capacitor physics and circuit operation (10:02)
Boost converters and buck converters: power electronics (13:59)
Resonance circuits: LC inductor-capacitor resonating circuits (7:18)
Op amp circuits: analog computers from operational amplifiers (11:38)
Grounding and shielding of electric circuits (7:26)
Logic gates from transistors and Boolean logic (14:00)
Zener Diodes in electric circuits (4:52)

15. Quantum mechanics (10)


Quantum mechanics (25:47)
Schrodinger's equation (8:58)
Quantum wave function visualization (11:23)
Quantum entanglement, bell inequality, EPR paradox (35:37)
Quantum measurements are entanglements (29:30)
Quantum spin - visualizing the physics and mathematics (22:56)
Quantum tunneling (6:20)
Probability - quantum and classical (22:48)
Delayed choice quantum eraser (26:32)
Quantum operators (21:46)

16. Strong force (2)


Nuclear physics (17:26)
Quarks, gluon flux tubes, strong force and quantum chromodynamics (12:39)

17. Weak force (1)


Weak nuclear force and standard model (15:38)

18. String theory (0)


19. Dark matter (0)


20. Dark energy (0)


Friday, July 26, 2019

List of largest known objects in the universe


Photo source: Wikimedia Commons, Richard Powell
Photo license: CC BY-SA 2.5

This post is a list of the largest known objects in the universe. The observable universe has a diameter of 93 billion light years (ly). The actual size of the universe is unknown. The picture above has some of the largest known superclusters, but is only a fraction of the observable universe. Our home supercluster, Laniakea is shown in yellow (520 million ly across). Source: Wikipedia

Largest cosmic structures


1. Hercules-Corona Borealis Great Wall (10 billion ly)
2. Giant GRB Ring (5.6 billion ly)
3. Huge-LQG (4 billion ly)
4. U1.11 LQG (2.5 billion ly)
5. Clowes-Campusano LQG  (2 billion ly)
6. Sloan Great Wall (1.3 billion ly)
7. BOSS Great Wall (1 billion ly)
8. Perseus-Pegasus Filament (1 billion ly)
9. Pisces-Cetus Supercluster Complex (1 billion ly)
10. Caelum Supercluster (910 million ly)

Largest galaxy superclusters


1. Pisces-Cetus Supercluster Complex (1 billion ly)
2. Caelum Supercluster (910 million ly)
3. Saraswati Supercluster (650 million ly)
4. Bootis Supercluster (620 million ly)
5. Horologium Supercluster (550 million ly)
6. Laniakea Supercluster (520 million ly)
7. Hyperion proto-supercluster (490 million ly)
8. Draco Supercluster (410 million ly)
9. SSA22 proto-supercluster (200 million ly)
10. Ursa Major Supercluster (200 million ly)

Largest galaxies


1. IC 1101 (4 million ly)
2. Hercules A (1.5 million ly)
3. Abell 2261 (1 million ly)
4. ESO 306-17 (1 million ly)
5. UGC 2885 (830 thousand ly)
6. Comet Galaxy (600 thousand ly)
7. Condor Galaxy (520 thousand ly)
8. ESO 44-46 (400 thousand ly)
9. Tadpole Galaxy (280 thousand ly)
10. Andromeda (220 thousand ly)
... Milky Way Galaxy (52 thousand ly)

Largest stars


1. UY Scuti (1,710 solar radii)
2. WOH G64 (1,540 solar radii)
3. Westerlund 1-26 (1,500 solar radii)
4. RSGC1-F02 (1,500 solar radii)
5. HD 143183 (1,470 solar radii)
6. RSGC1-F02 (1,430 solar radii)
7. VY Canis Majoris (1,420 solar radii)
8. KY Cygni (1,420 solar radii)
9. AH Scorpii (1,410 solar radii)
10. VV Cephei A (1,400 solar radii)
... Sun (1 solar radii)

Largest planets


1. GQ Lupi b (3.0 jupiter radius)
2. DH Tauri b (2.7 jupiter radius)
3. ROXs 42B (2.5 jupiter radius)
4. OTS 44 (2.3 jupiter radius)
5. Kepler-13 Ab (2.2 jupiter radius)
6. CT Chamaeleontis b (2.2 jupiter radius)
7. KOI-368.01 (2.1 jupiter radius)
8. WASP-79b (2.1 jupiter radius)
9. HAT-P-67b (2.1 jupiter radius)
10. XO-6b (2.1 jupiter radius)
... Earth (0.09 jupiter radius)