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13:29
Sometimes I like to this if QMechanic has edited my question then that question is blessed :P
I try not to edit it after that :P
13:52
@MoreAnonymous Doing otherwise would be outrageous and unforgivable :P
 
2 hours later…
Mad
Mad
16:04
If not every function in $L_2 (a,b) $ is physically relevant and do not fullfil the scalarproduct positive definity (equal to zero when the function is equal tozero) then why dont we just take a subset from $L_2$ and use those functions instead of saying everytime "oh those functions do not appear physically" but according to our rigor, they fit the requirements
Refering to quadratic integrable functions in quantum mechanics
Example: functions whos zero everywhere except in singularities, then the integral is zero but not the function. Griffiths even notes this as a footnote and says these functions dont appear in the physics, yet they are part of $L_2$
@Mad $L^2$ does not actually consist of functions
in order to make it into a proper Hilbert space, it is a quotient space of all square-integrable functions modulo the relation "$f=g$ except on a set of measure zero"
Mad
Mad
Alright
16:59
Trying to come up with some relatively simple polarization lab activities
And it seems like doing anything directly with circular polarization is pretty tough
Which I guess makes sense? You can get cheap linear polarizers, but to go from there to circular polarization requires a quarter wave plate
Which by definition is a rather precise object (exactly 90 degrees of phase difference)
And therefore a bit pricey
Mad
Mad
17:21
Laptop screens, old computer screens
Hmm, do those produce circularly polarized light or just linear? My impression was the latter
 
2 hours later…
19:04
so here's a bit of polarization physics which i'm confused by. i'm playing with little plastic linear polarizers: if i line them up orthogonally, i get zero transmission as per malus's law
i'm playing with various materials around the lab to see what they do, and in particular i grabbed a dinky little protractor: it's one entire semicircle, i.e., nothing cut out of it
if i put it in series with one of my polarizers, i don't see anything interesting: the intensity seems to remain the same as either is rotated.
so that makes it sound like it's doing nothing to the polarization: unpolarized light remains unpolarized
but then i took a pair of perpendicular polarizers and placed the plastic protractor in between them. if i rotated the protractor now, then it went from zero transmission when aligned with the first polarizer, to some transmission when at 45 degrees to both, to zero transmission again when aligned with the second
at which point i be confused. it's as though it's acting like a linear polarizer when exposed to polarized light, but not when exposed to polarized light?
my first thought was optical activity but it doesn't seem like the protractor is simply rotating the plane of polarization. so maybe it's actually just creating elliptically polarized light
@Semiclassical plastic is often birefringent; what you're seeing is that the protractor rotates your polarization
that was the first suggestion i had from someone else
if that's the case, though, then i'd expect that i could rotate the second polarizer to create extinction if i rotate it
and that doesn't really seem to be the case
it's a little ambiguous, b/c the rotation due to optical activity is frequency-dependent
if it's not manufactured for that purpose, the birefringence isn't homogeneous
eh, it seems pretty spatially homogeneous here---there's no stress lines when i insert it between the crossed polarizers
19:17
it is definitely not isotropic, tho
(i do have some other polarizers that have parts cut out of them, and i do see clear stress lines for those.)
the tricky bit of this is that, since all i have are linear polarizers, i can't really detect any circular polarization directly
can you post any pictures?
good idea
 
2 hours later…
21:06
@Semiclassical Watching crystals grow between crossed linear polarisers in a binocular microscope is mesmerising.
i believe you
I can't remember what salt we used when we did it at school. Maybe Epsom Salts (magnesium sulfate), which crystallises pretty quickly.
Some 3D movie systems use circular polarisation, so it shouldn't be too hard to get cheap circular polarisers.
i looked a little, most seem a bit pricey
tho it's confusing that you have CPL filters
aka circular polarization / linear filters
so linear polarizers but circle shaped
hmm, maybe i'm misunderstanding the links
21:29
There are some cheap sources, especially if you buy in bulk. But the cheap suppliers generally don't give details of how well their filters perform. These guys have good stuff, but they aren't cheap apioptics.com/product/apncp37-010t-std
One fun thing to do with a linear polariser is to look at the Moon when it's at First or Last Quarter phase. The sky is maximally polarised 90° from the Sun.
Wikipedia has lots of diagrams, some animated. en.wikipedia.org/wiki/Rayleigh_sky_model
21:47
I do think the challenge is to what extent I can characterize polarization by use of linear polarizers alone
If I use the correspondence to spin-1/2 msmts in QM, I suspect it’s like trying to differentiate a pure state from a mixed state if all you can measure are the x- and y-components of spin
Which seems dubious—how could you even distinguish spin-up (along z-axis) from spin down?
 
2 hours later…
23:40
\o @Loong

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