honestly🤣

So that’s one concept you will not have trouble remembering. Goal Achieved !

Hell Sas, you are welcome, and I am glad I could avoid you headaches! As I told another viewer, providing these videos is my little contribution (I feel gratitude, so I enjoy paying back some of the gifts nature gave me)

Thank you very much Krithika for your encouragements!

Hi Artemis. Your comment expresses exactly what I am trying to do here: To put students on the right track so that they can fly with they own wings. I am truly glad my explanation improved your understanding of polarization. Good luck with your studies!

Wow thank you Sam, for these very encouraging words! I do not know if my power of teaching is 4 x 10^26 Watts, haha, but if it can help students to avoid the pain I went through when I was a student, that is enough to make me happy!

Hi Sacco, yes, simple things around us, usually taken for granted, are actually quite amazing when you look at them in more detail... Thx for your feedback!

Wow, thank you Karl for this really kind comment! *** Blush*** It really motivates me to produce more videos like this one. I am glad to have improved your understanding of electric and magnetic fields. Maybe you can try the videos that didn't hit it at first and see if they appear clearer now.

Thank you so much for your kind words vogahl! It's appreciated :-)

Hi Mapato, thank you, greetings to you too, from the other side of the world (Being a GenX, how far the Internet has gone remains an amazement for me. It is so common in everyday's life nowdays, that we don't realise it anymore... and take it for granted, but if you think about it, it is truely amaxing!)

Yes Alice ;-), Physics can be a real box of wonders!

Thank you for your kind words Ageu!

Hey. Thank you. I am glad you enjoyed the video.

Thank you Driftin! Maybe you can show the videos to your teacher -)

Merci Arnaud, I am glad my videos clarified things for you :-)!

Thank you D. That's why I am teacher :-)!

Hi Puniyani, thank you for your words of encouragement! ❤

You are warmly welcome @mwerensteijn!

You are welcome Manav, I am glad you enjoyed my work :-)!

I fully agree, that is why I do what I do ;-)

Thank you Hakeem,. I am glad you enjoy my work!

Thank you for your kind words Dennis. My experience as a teacher has shown me that every students, even the weakest one, can grasp notions that are considered like difficult (for example electric potentials). Society / scholar system is very elitist, too elitist for my taste. So progressively I developed teaching strategies to render these notions accessible to all. And when I have some time, I produce a video presenting a notion for which I developed this pedagogy for my real life students. I am glad it helps you understand a little more the universe we live in!

Thank you Aisha for your kind words :-)

Merci Shual. My video replacing text books, maybe not haha! But seeing it at as a good complement, or starting point, yes. The idea with my videos is to read the text book after seeing the video: the goal is to provide a basis of conceptual understanding so that the viewer can dig deeper by himself.

Thank you for your kind words Minh!

Thank you for kind word and encouragment!

Thank you :-)

@@PhysicsMadeEasy Thank you!

Thanks Sailor! You seem to like sailing. Try that: Buy yourself a polariser (like a polarising filter for phorography). When you enjoying your freedom sailing at sea under a a shiny sun, look at the flickering reflections of the sunlight on the water waves. Then look under the polariser, and rotate it. You will see some of these reflection disappear. Welcome to the world of Brewster's angle!

Glad you liked it!

I am glad you enjoyed my work! Welcome to Physics Made Easy :-)!

Thank you Nimisha! How's your one-man show initiative going? I haven't seen any new video on your channel :-(

My oven and my (bass) guitar let you know that you are welcome :-)

Thank you :)

Hi, you are warmly welcome. I am glad you enjoyed my work!

I try to make Physics Easy while keeping things rigorous. Thank you for letting me know it works :-)!

Thank you , and I am glad you enjoyed my work :-)

You are welcome Tamer!

haha, yes it's always a lot of fun walking around the house wondering what to use out of my everyday stuff to help at the visualization of a concept. I was pretty proud of the idea of the oven rack to polarize a mechanical wave :-).

You are welcome Jassim. I hope my videos help you in physics!

Thank you Edro, I am glad you enjoyed it!

Thank you so much, it is the most time consuming part of producing the video: I am glad you enjoyed it.

You are welcome Moritz :-)

Thank you Muneeb

Merci Elorm, I am glad if the video helped you understand Polarisation!

Hey Andres, I am glad it helped you!

Thank you Khadija

According to Maxwell equations, a fluctuation of E in space, generates a fluctuation of B in time (and vice versa) perpendicular to the plane where the electric field fluctuates. Therefore, one implies the other. The origin is actually the electric field, the magnetic field being just a consequence of special relativity. When we talk about one, we imply the other. So for simplicity, when discussing linear polarization at the level of the video, it is not really necessary to discuss the magnetic field. the latter is implied.

Thank you Harlan for the encouragement!

Thank you Chiranjit :-)

Hi, interesting questions jdr... Hi jdr, Question 1 : Light is a transversal wave, so the direction of oscillation is perpendicular to the direction of transfer of energy (= direction of propagation). So to your question : « can an oscillation propagate horizontally while oscillating vertically in relation to the axis it travels along? »… Yes, light always does ! Note that there are waves where the oscillation is parallel to the direction of propagation, these are called longitudinal waves. Sound in an example of such wave… Question 2 : When a beam of light hits an interface, some of the beam reflects and some of it refracts. Such interface could be air/water for example. Both refraction and reflexion are generated by the same oscillating charges. The two beams interfere at source. When the incident light arrives at Brewster’s angle (incident angle such as reflected and refracted rays are 90 degrees apart), the interference leads to the cancellation of a component of the electric field vector (the one perpendicular to the surface). Loosing a component leads automatically to linear polarisation. So for light arriving at this angle, yes, the surface of the water acts like a polariser! As for metal, their electronic structure does that metals do not refract light… so there cannot be any interference here, thus no polarisation of the reflected light.

Hi Pratiksha, I am glad o be of help!

Thank you Nitesh :-)

You are welcome Chenuka :-)

Thank you Moulik!

You are welcome Roma :-) I am glad you enjoyed it.

Hi Lawrence. Soundwaves are longitudinal waves: the oscillations of the particles of air are parallel to that of the direction of their propagation. This is why soundwaves cannot be polarised. On the other hand, Light can be polarised because it is a transversal wave (the oscillation is perpendicular to that of the direction of propagation) . I hope this helps!

Thanks for the prompt reply. Can show with a diagram why oscillations of the particles of air that are parallel to that of the direction of their propagation cannot be polarised.

​@@lawrencelam2333 I don't have a diagram, but maybe this will help: Imagine that you could trace a line along all the positions of an oscillating air particle. The particle oscillates from left to right, so that line would be horizontal. And it would be in the same direction as the propagation of the sound (the same direction than the longitudinal wave). Now place a polarizer in front of it, like in the video. The line you drew would cross the polarizer in one point only… The wave would just pass through unchanged, whatever the direction of the polariser’s axis…

Sometimes a teacher needs to get creative :-)

Thank you!

Merci Carolina, I am happy your enjoyed my work!

Hi Aamir, you should find what you need to an answer that question in my video: "What are waves?". kzbin.info/www/bejne/gqC1g3holqxmd7ssi=alXB8FrPioNMT-hb The amplitude is the difference between the highest position (what you call the top peak - the max y of the sine curve- which is also called a 'crest'), and the equilibrium position (y = 0). For an EM wave, it represents the maximum value of the oscillating electric field strength (check my video, what is an EM Wave) The bottom peak (called a trough), is also a maximum displacement (in the negative direction this time). For an EM wave, it represents the maximum negative value of the electric field strength. Thus, it also also represents the amplitude.

You are welcome Kathir

Thank you so much for your support Denisep!

If these are basic polarizing 3D glasses, all light should be stopped. But, maybe modern ones have a different way of working: there is some electronics in them that actually is synced to a signal that can make the polarisation axes of each lens flip in synchronicity with the movie...If this is true: the axis of pol between left and right may not necessarily be perpendicular in the absence of a sync signal. I am only speculating there... and I might be completely wrong, so you should check this by yourself on the web.

Hi Eduard,. Yes the polarization plane of the electric field can rotate through time (thus, through space). This is called circular polarization. More info here: en.wikipedia.org/wiki/Circular_polarization#:~:text=In%20electrodynamics%2C%20circular%20polarization%20of,the%20direction%20of%20the%20wave.

Hi David, That would be too long to explain in one comment. Rotation of the polarisation plane by molecules is called circular birefringence. I invite you to consult this wikipedia article that is pretty good: en.wikipedia.org/wiki/Optical_rotation Enjoy!

Hi Jaya, Within the scope of classical physics, Light is an oscillating electric field (See video what is an EM Wave). When an electric field oscillates, it automatically generates an oscillating magnetic field perpendicular to its oscillation plane. When you have one, you have the other. So to describe an EM wave, you just need to look at the electric field to describe it, because the magnetic field emerges naturally from it. The Magnetic components is only affected by a polariser because of how the electric field components are affected by that polariser... Example: if a polariser has a polarisation axis which is vertical, that means that only the vertical component of the oscillating electric field will be allowed to pass. This is equivalent to say that only the horizontal components of the magnetic field will be allowed to pass through.

When we are talking about a vertical polarisation axis, the term 'vertical' applies to the electric field: It means that only the vertical components of the electric fields will be allowed to pass through. The magnetic component of an EM wave emerges from the oscillation of the electric field. The oscillation of that magnetic field is in a plane perpendicular to that of the electric field oscillation. Therefore a vertical polarisation axis will allow the horizontal component of the magnetic field to pass through.

Are you saying that the polarizer is letting the electric component of the wave pass and blocking the magnetic component? Then, the magnetic component emerges after the electric component is past the polarizer? I'm basically trying to understand if the polarizer is temporarily removing one component of the wave as it passes through the polarizer.

@@kn0w0n3 Hi, In regards to the EM Wave itself, saying that the polariser acts directly on the MField, or that the MF is re-induced by the polarised EField is an equivalent statement. I would tend for the second one though based on of my understanding of Maxwell equations For me, what a polariser does is just cut the component of the electric field strength that is perpendicular to the polarisation axis...

Hi Ellios, if you have a magnetic wave (Magnetic Field density oscillating), that means that you also have an electric one that is induced (Maxwell equations). So that results is an EM wave propagating, or light :-). So, to answer your question, any light polariser is also, naturally, a magnetic wave polariser.

@@PhysicsMadeEasy Hi prof and thank you so much, I thought polarizers only polarize the electric part of the EM waves. because they only talk about what will happen to electric wave and I couldn't find a vid that explains what will happen to both waves...because the two waves always have to be perpendicular to each other in EM wave so I was wondering if... for example a polarizer only allows waves that are oscillating in vertical plane...so the outcome will be magnetic and electric waves that are oscillating in one plane so they are no longer perpendicular? sorry for writing too much and sorry if my Eng is not good

Hi Robert, i do not really understand what you are referring too. A polarizer is not a diffraction grating... (it does not disperse light into its frequency components, but only let pass through it a geometrical component of the oscillation of its electric field)

Beautiful way of explaining and making it easy to understand. Thank you sir