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#physicsfactlet

1 Beitrag1 Beteiligte*r0 Beiträge heute
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j_bertolotti

#PhysicsFactlet
It's a foggy day here in Albion, so let's talk about light (multiple) scattering!
Fog is composed of micrometre sized water droplet that can scatter light. This has two main effects: some of the light that was supposed to reach your eyes don't (because it is scattered away), and some of the light that was not supposed to reach you gets scattered into your eyes.
The denser is the fog and the further an object is from you, the more likely light is to be scattered away before it reaches your eyes. The amount of unscattered light (i.e. the one your eyes can use to form a sharp image) goes down exponentially (Lambert-Beer law), so an object in the fog gets dimmer pretty quickly. On the other hand there is a chance that light that was never meant to reach you is now scattered into your eyes, but since it arrives from a largely random direction, mixed up with a lot of other scattered light, your brain perceived it as a white blur on top of everything else. And since far away object were already dim, this white halo can easily overpower them, so you can't see them anymore.

Photo of a street on a foggy day. Nearby objects are clearly visible, while objects further away becomes gradually dimmer and blurrier.
#Physics#Optics#ITeachPhysics
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j_bertolotti

#PhysicsFactlet
Light propagates in a straight line (actually it is more complicated than that, but this is good enough for us here) and we see only the light that comes to our eyes. As a result you usually don't see the light going from its source to the objects it illuminates.
Unless it is misty, in which case light can scatter on the water droplets and you can "see" the light's path ("Tyndall effect").

Photo of a house illuminated by a streetlamp. Due to the mist, the cone of light is well visible.
#Physics#Optics#EverydayPhysics
Öffentlich
j_bertolotti

#PhysicsFactlet
Do you want an interpretation of quantum mechanics that doesn't really work that well in practice, but that would look fantastic for your Sci-Fi novel? I have for you "Many interacting words" (not to be confused with the similarly named "Many worlds interpretation").
In this interpretation the universe is 100% classical, but instead of being one universe there is a VERY large number of them, all classical and weakly interacting with each other. In particular each particle is classical, but is repelled by its "copies" in the other universes. This is able to replicate a lot of the most weird effects of quantum mechanics. For instance, classically a particle is not able to overcome a potential barrier if it doesn't have enough energy to do so, but in this interpretation the particle would be repelled by its copies, so it has a non-zero chance of getting enough of a kick to jump on the other side of the barrier, producing the phenomenon we usually call "quantum tunnelling".
Another effect replicated by this model is the "zero point energy" i.e. the fact that the lowest energy a particle can have is not zero, but a bit higher than that. In this interpretation this comes to be because the particle (which is classic) would like to sit at zero energy, but so do all of its "copies", and they repel, so none of them can really sit at zero energy.
If you want, in this interpretation the very fact we see quantum effects is evidence of parallel universes!
journals.aps.org/prx/abstract/

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#Physics#QuantumMechanics
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j_bertolotti

Not a #PhysicsFactlet, but a full beginner-friendly tutorial on how to use speckle correlations for imaging through a scattering medium, complete with a step-by-step guide on how to set up your first experiment and analyse the data (including a full code in Mathematica and one in Matlab to analyse the data, and all the raw data used to generate the plots to make your tests):
#Physics #Optics #Photonics #ITeachPhysics
iopscience.iop.org/article/10.

Öffentlich *
j_bertolotti

#PhysicsFactlet How does a fridge magnet works?
You can qualitatively think of most magnetic materials as made of a lot of tiny smaller magnets, each with a "North" and a "South" pole. North and South attract, while North/North and South/South repel.
Magnetic materials come in a lot of flavours, but the two we are interested in now are ferromagnets and paramagnets.
Ferromagnets, have all their tiny magnets interacting strongly with each other in a way that makes them all nicely aligned and stable. (Yes, this is a simplification. Run with it.)
Paramagnets (like the steel of your fridge) also have all the tiny magnets, but their interaction is weak enough that their orientation is largely due to thermal random fluctuations. That is, until a ferromagnet gets close enough. Then the field of the ferromagnet is strong enough to (at least locally) orient the tiny magnets to align with the ferromagnet ones. Now the paramagnet is showing a lot of "South" poles to the "North" part of the ferromagnet, and a lot of "North" poles to the "South" part of the ferromagnet, so the two attract and the fridge magnet stay put!
#Physics #ITeachPhysics #Magnets #Visualization

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