The h Bar - 2019-08-21

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1:30 AM

Hello everyone
I am an undergraduate physics student looking to become an experimental physicist, and I am looking for some advice as to how to do well in the laboratory.
In a week I will begin a course called "Advanced experimental physics", where my group and I will have to do complex experimental physics (at least compared to the usual basic things done in the undergraduate levels). We will be monitored by my university's top researchers in the field, so we would like to make a good impression.

3 hours later…

4:32 AM

@NickHeumann Without knowing the details of your area or experiment... and I am a computational person who has had to do a lot of head scratching and questioning of experimental people... I would want to see that you A) understand the importance of boundary/initial conditions in order to generate repeatable and reliable measurements, and B) understand and want to quantify the assumptions and uncertainties that go into every measurement made

If A and B are done, and you can clearly communicate your setup and results, then anybody in the world should be able to replicate your results -- either experimentally or computationally (ideally -- simulations probably have a long way to go to get things right, but the better you can answer A and B, the fewer excuses we have for being wrong)

Since this is a lab course, I would want to see some thought into the design of experiment also. How much depends on how the course is set up. But, if you want to measure X, you should have put some thought into all the things that influence X and how you can control and measure each of those things

1 hour later…

5:39 AM

8 hours ago, by ACuriousMind

How could you ever measure "infinity"?

The problem of physical infinity is that given finite resources, there is really no way to distinguish it from some humongous quantities

You have to somehow stumble upon the axioms that justify it in the first place, of which give contradictions if the object is finite to prove it is a candidate of physical infinity

Infinity thus behave like a counterfactual concept. Lacking a framework to model them, they are literally only describable as something that does not satisfy the behaviour of finite objects

5:55 AM

@ACuriousMind Very long ruler

On physical infinity
Suppose I have a box which has volume 3 cm3 and inside, there is another box which measured to have volume 3 cm3
This will be an example of something that has a self injection that is not a surjection
We can go further and test whether the space is eulidean by checking how parallel lines behave near the boxes. If the space is euclidean, then it is more plausible that the box behave like infinity at least for objects of size less than 3cm3

2 hours later…

8:15 AM

I am trying to find the expression which is similar to the hamiltonian but it seems that I am missing something here,

$\hat{\phi}(x) = \int \frac{d^3k}{(2 \pi)^3} \, \frac{1}{ \sqrt{2 E_{k}}} \left( \hat{a}_{k} + \hat{a}^{\dagger}_{-k} \right) e^{i k \cdot x}$
$\hat{\pi}(x) = \int \frac{d^3k}{(2 \pi)^3} \, \sqrt{\frac{E_{k}}{2}} \left( \hat{a}_{k} - \hat{a}^{\dagger}_{-k} \right) e^{i k \cdot x}$

$\hat{P}^{i} = -\int d^3x \, \hat{\pi}(x) \, \partial_{i} \hat{\phi}(x)$

what I got is
$P = \frac{1}{2} \int \frac{d^3p}{(2\pi)^3} \, p^i \left( \hat{a}_{p}^{\dagger} \hat{a}_{p} + \hat{a}_{p} …

How to get rid of the second, third, and the forth terms?

Hm

I think I solved the first 3 chapters of Peskin in some notebook

Lemme see if I still have it

I appreciate that!

user image

does this help

It's something about how the integral behaves under change of sign of $p$

Actually

I think I might have asked on PSE about that?

In the Hamiltonian case, I found that

$\hat{a}_{p}^{\dagger} \hat{a}_{p} \text{must equal} \hat{a}_{-p}^{\dagger} \hat{a}_{-p}$

I found this physics.stackexchange.com/questions/24716/…

but I didn't understand how it works.

Now, I check the notes

8:32 AM

My notes tend to be a bit shorthand :p

It's fine.

just here ...

user image

Apparently it integrates to zero because it's an even function

According to this gentleman

delta func. is even but P ...

it is an infinite number

Well you know

It's one of those QFT thing

Sweeping infinities under the rug

the same case as in the H

:D

8:40 AM

Because you're being very naughty and multiplying distributions together

Even though that is verbotten

3

Q: Schwartz impossibility result

I was wondering what made it impossible to define a product of distributions. Googling, I found two questions, one of which stated the following impossibility result: There is no associative algebra over $\mathbb{R}$ containing $\mathcal{D}'$ as a vector subspace and the constant function 1 a...

distribution-theory

v. naughty

So there is a contradiction between this $\delta_0 = 0$ and $\delta_0 $ = inf. number

I think this is correct here

Like the energy is infinite due to silliness, but I think the momentum is properly zero, because otherwise it wouldn't be rotationally invariant

Lemme try to think of a proper argument for it

Man those notes were rushed

It probably makes sense by considering it before integration

ie it's something like $$\int dx dy \delta(x - y) \delta(y)$$

I think

8:56 AM

@Slereah $\int dx dy \delta(x - y) \delta(y) = \int dx \delta(0) = \infty$ ?

Something like that

I forget exactly where the $\delta(0)$ thing comes from

I think it makes sense that it's zero if you keep the integral as $$\int \frac{d^3x}{2}\frac{d^3p}{(2\pi)^3}\frac{d^3k}{(2\pi)^3}$$

Well

It makes sense for a physicist anyway

A mathematician would surely frown

it comes from the commutator a_p a_p+

and the integral over k

sorry without mentioning "and the integral over k"

Well it's $$\int d^3x d^3 p d^3 k p^i e^{i(p-k)x} \delta(p-k)$$

Or something

Novalium Company

@PM2Ring or @JohnRennie - Does it matter how much surfactant (soap) I put in the solution of charged TiO2 and water? I'm planning to cut a piece of a solid soap that's used in the shower and bath.

Hm

is there a decent handwave to say that this is zero

9:09 AM

@NovaliumCompany if you're using water you shouldn't need any surfactant.

@Slereah So, I want to clarify what I have understood. to get rig of delta, either we interpret it ( $\delta(0)$) as inf. number ignore it as usual, or, we perform the integral over $p$ (product of distributions with $\delta(0)$ to give zero. Am I right?

I'm not sure yet

Let me think it over

see the thing is

That the energy is infinite doesn't matter too much

Since, unless considering GR, we can only measure differences in energy

and you can renormalize the Lagrangian anyway

Without changing the dynamics

But having the momentum not be exactly zero is weird, because the vacuum is supposed to be invariant under rotation

So I think this should be zero in a stronger sense

this isn't a super rigorous argument because QFT nonsense but it's just a gut feeling

Wait

\begin{eqnarray}
\int d^3x d^3 p d^3 k p^i e^{i(p-k)x} \delta(p-k) &=& \int d^3x d^3 p p^i e^{i(p-p)x} \\
&=& \int d^3x d^3 p p^i
\end{eqnarray}

Hm

Still not great

But if you're integrating $p^i$ it's just a linear integral

$$\int dp\ p = \lim_{x \to \infty}[p^2/2]^x_{-x}$$

Which is indeed zero

And the other integrals are just a constant which you can set to zero

I think that's a decent argument

9:30 AM

I couldn't understand where this $x\delta (x)=0.$ come from?

Well a dumb argument for it is that $\delta(x) = 0$ outside of its support $\text{supp}(\delta) = \{ 0 \}$, and $x = 0$ on that support

So it is zero everywhere

ok

So this is the argument of what we discussed earlier?!

$p\delta (p=0)=0$

without performing the integral

@Slereah once again, the claimed result $\delta(0) = 0$ is wrong from math.stackexchange.com/questions/1357877/…, right?

Oh $\delta(0)$ isn't a well-defined quantity

but yes it is very much not $0$

But I couldn't recognize what this post is talking about?

Well the thing is

In QFT, operators are actually distributions

9:43 AM

Could you please in few words give a summary

But to obtain the stress energy tensor in QFT, you need to multiply operators

ie $H \approx \pi^2$ and such

But as this post says, it's not mathematically well-defined to multiply two distributions together

This is why we get really weird results

Ah hah!

I see

So, mathematically QFT is not acceptable since the indefiniteness of product distributions?

Novalium Company

@JohnRennie I have this mixture of charged TiO2 particles and water. I'm planning to remove as much water as possible (by increasing the surface area by spreading the solution on a plate and letting it on the sun for a few hours) and I also thought I should put some surfactant so it can form miscelle around the TiO2 particles and they don't evaporate with the water and also later when I put them in baby oil and add black paint, the miscelles should stop the black dye to cover up the TiO2 particles

Well there are ways to get around that

But my point is, the way QFT is done, it's a bit non-rigorous

so you have to watch out for some issues

@Slereah If we think is this way, even $\delta_0 x = 0$ is wrong?

9:51 AM

Well even $\delta(0)$ doesn't make sense

Because distributions aren't defined on individual points of space

The proper way to do it is to have a regularizer

Like $$\delta_\varepsilon(x) = \frac{1}{\varepsilon \sqrt{\pi}} e^{-(\frac{x}{\varepsilon})^2}$$

and then, at the very end of the process, take the limit $\varepsilon \to 0$

but dragging around the regularization through the whole process is a huge pain

Always,there should such ansatz exist to solve problems

otherwise you end up with this kind of abstract nonsense

user image

poooff...

@Slereah Do you have Mathpix?

I don't know what that is

it is math snipping tool

it allows you to snapshot any figure to latex format

unfortunately this great tool is broken nowadays

since their latest update

@Slereah What kind of tool you use to save time when you write latex in SE?

10:03 AM

user image

The proper way to write the Hamiltonian :p

@Student404Mus I use my own two hands

:)

user image

This is why you pretend $\delta(0)$ makes sense :p

What is the reference of these images?

arxiv.org/pdf/0807.0289.pdf

there's also methods for dealing with this in like

Schwarz's QFT book

in the regularization chapter

I see

10:29 AM

user image

Just when you thought tensors are hard enough in general relativity, computational chemist took it one level higher

I have absolutely no idea what this indices flooding equation is trying to say

and seriously, "globally contravariant" brain shuts down

2 hours later…

12:53 PM

@Slereah can i ask you a question

Novalium Company

1:06 PM

Guys, I glued together a container $1 cm^3$ of plexiglass but I'm struggling to insulate it so water doesn't leak. If I cover it whole in hot glue, the transparency gets lost.

@yuvrajsingh shoot

1:33 PM

@Student404Mus In $\frac{1}{2} \int \frac{d^3p}{(2\pi)^3} \, p^i \left( \hat{a}_{p}^{\dagger} \hat{a}_{p} + \hat{a}_{p} \hat{a}_{-p} - \hat{a}_{-p}^{\dagger} \hat{a}_{-p} - \hat{a}_{-p}^{\dagger} \hat{a}_{p}^{\dagger} + [\hat{a}_{p},\hat{a}_{p}^{\dagger}] \right) $ for the first and third term you have
$$
\frac{1}{2} \int \frac{d^3p}{(2\pi)^3} \, \left( p^i \hat{a}_{p}^{\dagger} \hat{a}_{p} - p^i \hat{a}_{-p}^{\dagger} \hat{a}_{-p} \right) = \frac{1}{2} \int \frac{d^3p}{(2\pi)^3} \, \left( p^i \hat{a}_{p}^{\dagger} \hat{a}_{p} + p^i \hat{a}_{p}^{\dagger} \hat{a}_{p} \right) = \int \fra…

How to deal with problem of constrained @Slereah

To get rid of the $\delta$ you treat it as an infinite constant just as for the Hamiltonian $H$, recall $P^{\mu} = (H,P^i)$ so you're just working out the oscillator expansion of the components of the four-momentum operator

1:55 PM

@NovaliumCompany having been in that situation before (albeit with a slightly larger cube) we used a spray glue type deal...i think it was called flex seal? which worked pretty well.

@yuvrajsingh Constrained what

Hamiltonians?

if you want the standard books on the topic it's like Dirac or Henneaux-Teitelbaum

2:15 PM

@bolbteppa I got it. Thank you very much

Dirac's probably a better intro

For a start it's not a brick of a book

Novalium Company

2:43 PM

@heather Can I just wrap it in normal transparent tape? Cuz I need a transparent solution.

Why is k = 1 in f = kma ?

@HardikSharma the units of force are defined to make $k=1$

@HardikSharma physics.stackexchange.com/questions/104101/…

This was asked on the main site. Let me see if I can find the question.

@JohnRennie already did

2:46 PM

Ah JMac beat me to it :-)

Novalium Company

I decided not to even participate :D

I knew I had seen it, so I just searched that before trying to answer them

Novalium Company

When finally someone asks a question I think I can answer, it turns out my brain is still not big enough

There hasn't been a single person in this chatroom which I'm smart enough to help :(

That seems like a really bad way to look at things. For one thing, most people at some point in their lives aren't able to help others with physics questions, because they still have to learn. At the same time, to feel confident in helping others you at least need to try at some point, or you'll never feel comfortable. Just don't oversell your knowledge if you're unsure

@JMac got it. Thanks a lot.

Novalium Company

2:51 PM

@JMac Understood

Looking it from the bright side it means I still have a lot to learn.

user image

Why my voltage multiplier Tinkercad circuit doesn't work?

2 hours later…

Novalium Company

4:27 PM

user image

I'm pretty sure this is supposed to output a much higher voltage. What's going on?

4:48 PM

Most likely, it's not taking the internal resistance of the devices correctly to charge the caps with the right RC

5:05 PM

How GitHub helps you, physicists?

5:23 PM

Using the normalization definition of the momentum state
$$
|\mathbf{p}\rangle=\sqrt{2 E_{\mathbf{p}}} a_{\mathbf{p}}^{\dagger}|0\rangle
$$

since (before normalization)

$$
\langle\mathbf{p} | \mathbf{q}\rangle=(2 \pi)^{3} \delta^{(3)}(\mathbf{p}-\mathbf{q})
$$

it follows that

$$ \langle\mathbf{p} | \mathbf{q}\rangle= 2 E_{\mathbf{p}}(2 \pi)^{3} \delta^{(3)}(\mathbf{p}-\mathbf{q}) $$

How someone could prove the result

$$ (1)_{1-\text { particle }}=\int \frac{d^{3} p}{(2 \pi)^{3}}|\mathbf{p}\rangle \frac{1}{2 E_{\mathbf{p}}}\langle\mathbf{p}| $$

The above result is the completeness relation after normalization

@Student404Mus You just apply that last expression to a $\lvert q\rangle$ and show that the result is the same $\lvert q\rangle$, i.e. it acts as the identity on that basis.

5:39 PM

ah ! I see

6:02 PM

@ACuriousMind Had you tried this web application before? snip.mathpix.com

nope

It help to save time when it comes to writting latex equations

you need only to copy to clipboard the snapshot of the equation you want then paste it in the script editor of latex (in the web application) and it's done

7:02 PM

0

Q: Help with book suggestions

If I am to ask for book suggestions on a certain topic, where should I ask? Should I ask on Physics Stack Exchange? If so, what tag should I use?

support resource-recommentation books

Novalium Company

7:54 PM

reddit.com/r/diyelectronics/comments/ctkluu/…

If anyone can help

1 hour later…

Novalium Company

9:11 PM

@JohnRennie What do you mean? I want to put surfactant so when the water evaporates the TiO2 particles don't go with it. Also, later on when I mix the TiO2 particles (now with micelles around then) and black dye in baby oil, the black dye doesn't cover the TiO2 particles.

2 hours later…

danielunderwood

10:44 PM

@Student404Mus you can see what your simulation/analysis code was and revert it to what it was before you broke it...if you use git properly. A lot of people also use it for sharing their code or finding other peoples' code

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Aug '1921

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