Since interference is a matter of distance, shouldn't the dark and bright spots swap places if the screen is gradually moved backward or forward? The change in position on the screen must not of course be explainable by the magnification factor. edit: I understand that both waves would keep relatively the same distance to each other, but what if we rotated the screen left or right, and changed their relative distance to it? Would the dark and bright spots swap their locations?
there’s a million videos on UA-cam explaining this experiment. But there is not a single UA-cam video actually demonstrating this experiment. Can you please repeat the original experiment in a video?
If you mean exactly like Thomas young did it that would be fun and a challenge though I do DO the experiment in my more thorough video. ua-cam.com/video/cUmIL2hbgR4/v-deo.html
Just learned about this today in class
Nice vedio
Thank you!
Since interference is a matter of distance, shouldn't the dark and bright spots swap places if the screen is gradually moved backward or forward? The change in position on the screen must not of course be explainable by the magnification factor.
edit: I understand that both waves would keep relatively the same distance to each other, but what if we rotated the screen left or right, and changed their relative distance to it? Would the dark and bright spots swap their locations?
there’s a million videos on UA-cam explaining this experiment. But there is not a single UA-cam video actually demonstrating this experiment. Can you please repeat the original experiment in a video?
If you mean exactly like Thomas young did it that would be fun and a challenge though I do DO the experiment in my more thorough video.
ua-cam.com/video/cUmIL2hbgR4/v-deo.html
@@PhysicsHigh I’m sorry. I was referring to the experiment where they proved that light is a particle.
@@dosomething3they proved it was a particle and a wave right?
Sorry Paul, it's all bunk.