earlier this year I tried to work out what resources there are for learning high level maths with limited eyesight

myria.math.aegean.gr/~atsol/newpage-en/software/braille

DG,analysis etc in braille sound... fun /s

in condensed matter theory is the laundau levels stuff kind of disjoint from the band structure stuff?

@naturallyInconsistent but what does this even mean tho? so i have my conduction electrons in my metal and each electron is just existing throughout the entire lattice??

@Relativisticcucumber Just to be sure, are you discussing about electron in lattices and Bloch waves?

@Mr.Feynman yes my q is about this

@Mr.Feynman i thought its a wave packet which is not delocalized over all of space?

@Relativisticcucumber the sentence after the comma is about plane waves

The packet is not delocalized in general

Focus on single plane waves for the time being

oh, yes

im w u

@Relativisticcucumber Okay. Those correspond to free particles. Free=momentum (operator) is conserved=space translation invariance

Now, the case of the lattice is a little different. An electron (let's consider only one) in a periodic lattice will be in a less symmetric situation than a free electron

But nonetheless symmetric

As we have discussed other times, what I'm talking about is the content of Bloch's theorem. The content of the theorem is intuitively explained by comparing to the free particle case

@SillyGoose I think in (intro) books indeed most often the free electron case is discussed, but some also discuss the case for an electron in a solid (e.g. in the semi-classical framework)

$$\text{Free electron}\to\text{Plane waves}$$

$$\text{Electron in a lattice}\to\text{Bloch waves}$$

And the idea is (Bloch's theorem) that, just like the setting is a less symmetric (no continuous translation invariance) version of the free particle case, the Bloch waves are a modified version of the plane waves, as you know plane waves modulated by a periodic function

This should explain why they are delocalized

@TobiasFünke you are correct. The only problem I have is that in a lecture we take things which are necessary and related to the exercise sheet, mandatory to be solved, otherwise I cannot enter the exam. So, I will have to read the lecture notes, and then the notes in the book, which correspond to the topic of discussion

in class

And if I were to look for it in the book, I would just jump from x chapter to y, to z, leaving all the theory in between

But ultimately you are right

@imbAF may I ask in which country you study? and at which level? bachelor or master (or something completely different)?

germany masters currently

I see. And did you do your bachelor at the same university?

yeah

and which course is it? (sorry if I've asked before; I forgot)

which course?

@imbAF I mean the course/lecture you are referring in this post.

theoretical particle physics

and condensed matter theory

are what I am doing rn

I see

I chose these

gauge

@Mr.Feynman ?

shhh, I'm trying to lure ACM

you'll scare him

hahah

@Mr.Feynman You called?

Gauge is your bat signal, isn't it? :P

lol it worked

@ACuriousMind are you still on your way to work?

You disappeared after that :P

I was hoping ACM wasnt texting and driving on the autobahn

@Mr.Feynman ...any rational observer would conclude that I "disappeared" after I arrived at work :P

@qwerty No need to worry, I have neither a car nor a driver's license

@qwerty Lol, he's not the kind of person. He could risk making a typo if he also had to distract to drive

@ACuriousMind Not gonna lie, using the information I had on your workplace, I thought you were walking down the hallway of your house at the time of writing

I'm not sure what that means

@ACuriousMind +1 :). me neither. if we are lucky we get a functional DB in x years though

Yeah, it's not as clear as I hope. You usually work from home

@ACuriousMind I am guessing it means we might think you work from home a lot

To be honest the most confusing thing about it was that I live in a flat, not a house :P

and there's no hallway in it

Is a flat not a house, though?

@Mr.Feynman A flat is in a house, but it's not my house!

perhaps another assumption based on your job description lol

Ah, okay apparently I didn't make a distinction. I call house whatever building someone lives in :P

to be pedantic I would say a flat or apartment is a kind of housing not a house but honestly I don't think it normally causes much confusion...

Yeah, I got confused because there is really no distinction in Italian. You have specific words for various types of residence, but I just call everything "casa"

Does "domicile" sound any better?

the distinction is very strong in German - if I told someone we were going to "my house" and then we end up at this apartment building instead of a house in which only I (and family or roommates) live, they would be very confused

Aaaah, Germans

it makes you sound like an official letter from the queen, uh I guess king, of England

Incidentally, I'm not very precise with daily language. For most of my life I have called hoods "hats" (of course in Italian) because the words are similar

@ACuriousMind what about Bauhaus? that means building house right?

And every time I hear that word I have to think a little

@qwerty lol

not really

@qwerty Then imma say "your place", ain't that better, pal?

Since apparently I was being too royal :P

It's a proper name (either of a hardware store chain or of the art school) and doesn't really mean anything outside of that

@ACuriousMind yeah I knew it from art but I was told it meant "building house" lol

well, the literal translation is indeed "building house" or so

Tobias, are you German?

yep

Then ritual question

Have you ever heard someone say this? :P

:D sure

YAY

I have defeated you, 2023 ACM

I heard that so many times already... and I even think I shouted it --without even owning a car :d

@imbAF Let me finish our discussion by recommending Nolting's many-body book, first chapter, if you want to learn second quantization (including things like Fock space, the symmetrization postulate and so on). It is available in English and German. And as I've said some hours ago, I think it is a quite good book; especially the first chapter

@TobiasFünke ???

@ACuriousMind I am from east Germany. Perhaps a cultural difference? :d

@ACuriousMind As I have explained many times, whenever someone slams the car door, you say that

might be, I don't think I've never heard anyone say that

interesting

but I indeed have never slammed a car door in East Germany :P

:D

don't try it

@Mr.Feynman how come you know, actually?

@TobiasFünke this guy

wir sind nicht aus zucker.

I see

I see, so you relate

As a matter of fact, not so long ago I had the exact same situation with an Italian friend of mine. It was only raining a little bit ("nieseln" we say), but he was making drama lol

@Mr.Feynman In which region do you live?

@TobiasFünke Can confirm, I'm the Italian friend (damn reddit memes)

It is time to purge the answer

@Mr.Feynman oh, I did not notice :( but it is okay if you don't want to tell

@TobiasFünke timing, just timing

nice :)

It's not about being scared of people on the internet or such things :P

:D I understand

The reason is that I have asked many stupid questions on SE and I feel very self-conscious about physics stuff

:d I see. but asking is better than just ignoring ones misunderstandings

Mhhh, sure thing. I just already have a self-haunting tendency

So I don't want to get Mr. Feynman too close to the real me

:D

@TobiasFünke Ok will get it

@TobiasFünke I'll reply here. Probably I didn't really understand the ISW back then, as I'd just been introduced to QM. Basically I was led by the idea that you could just do an infinite energy shift, making the problem equivalent, but it wasn't very evident to me back then that in reality all thosd infinities are just a neat way to state what the support of the wavefunction is

@Mr.Feynman OK.

It is funny how the infinite square well is used as an example in QM over and over again, but causes so much trouble

Is that caps intentional? :P

Can I ask here about an exercise that I solved? I want to know some additional thing about the topic

grammarly.com/blog/commonly-confused-words/ok-okay :p

@TobiasFünke well, the whole fact that people learn about QM in infinite dimensional settings where most of the things they do are just formal and require complicated functional analysis to back it up isn't good either

As ACM says, you could learn QM without infinite dimensional spaces, e.g. with spins

@Mr.Feynman well... but you need infinite-dimensional spaces in QM. One must just be aware of possible pitfalls, "paradoxes" etc., which almost always arise when one tries to carry concepts from finite-dimensional to infinite-dimensional spaces and alike...

Well yeah, of course the basic axioms of QM work on finite-dimensional spaces. I agree with that, and it also makes sense to start with this setting, I guess. But you cannot avoid infinite-dimensional spaces at all

@imbAF "Don't ask about asking, just ask"

Damn, I had to read an article about etymology because of a caps letter

@TobiasFünke of course you do need infinite-dimensional spaces, both for physical relevance and also for motivating the introduction of QM, given that only infinite l-dimensional spaces are the result of the quantization of a classical theory. Finite dimensional ones are useful to understand the machinery, though

@Mr.Feynman yes, agreed!

@Mr.Feynman ok sorry i think i have misstated my question

i get why these are mathematically solutions

but physically this is rather unintuitive to me for some reason

And that being said, I shall indulge in my nocturnal rest (@qwerty I hope I was royal enough)

@Mr.Feynman good night :)

i think because i expect if i drop an electron into a metal, i expect it to move around and eventually find a home hovering around a particular atom

and plane waves arent physical so this only furthers my confusion actually. tmu bloch waves actually are physical solutions

So I consider $T_{R_1}c_{\vec k,j}^\dagger=e^{ika}c_{\vec k,j}^\dagger$. This is the end of my calculation. I am giving the result only

Now, would it be accurate to say that because of the periodic boundary conditions

$k=\frac{2\pi n}{Na}$ where n=1,2,3...N-1

?

If so, how would things look like if I were to not consider the fact that $T_R\phi_0=\pji_{N-1}$ ?

1. You should apply $T_R$ to a state, not an operator or so. 2. What is $c^\dagger_{k,J}$?

it would be the creator operator that creates an electron on state $\psi(\vec x- \vec R_j)$

where $\vec R_j=j\vec R_1$ is the position of the j-th atom in the 1D lattice

but why the $k$? in the exercise you have operators with a $j$, and operators with $k$ --not both

and $R_1=(a,0,0)=a$ is the primitive basis vector

I do the following:

First of all $T_{R_1}\psi(\vec x - \vec R_j)=\phi(\vec x - R_{j-1})$

So essentially as you use the translation operator once, you consider the wave function of the electron in the j+1 position, but because x doesn't change while j-->j+1

the potential felt by the electron is the same as the potential it feels from the j-1 atom

would you agree with this?

sorry, I have to sleep now. Maybe someone else here can help you

but essentially you just have to act with $T_R$ on the corresponding linear combinations of the $|\phi_j\rangle$.

I did

good.

But I have to make a claim about the k - values wile keeping in mind the condition

for T_R

And I am not sure about my result, since I don't know how to cross check it

Cross checking? Well, if you get that it is indeed an eigenstate of $T_R$ plus if it is really an eigenstate of $H$, as the next exercise suggests...then chances are good you did the correct thing

@Mr.Feynman oops, sorry I didn't respond. I was arriving at work. have a good slumber!

i have constructed an argument that seems wrong $tr([A,B]) = tr(AB-BA) = tr(AB)-tr(BA) = tr(AB) - tr(AB) = 0$ via linearity and cyclicity of trace. what is going awry here?

@naturallyInconsistent im more of a functionalist myself

at this point i need pliers for my eyelids