Good morning sir @JohnRennie

@user8718165 morning :-)

@JohnRennie sir I want to ask you some questions...are you busy now?

@user8718165 Yes ... ?

@user8718165 That was "yes what's the question" not "yes I'm busy"

@JohnRennie Okay sir.....got it :-)

@JohnRennie $q_p=q_v+\Delta n_g RT$

What are $q_p$, $q_v$ and $\Delta n_g$?

Sir its written when $q_p=q_v$ then $\Delta n_g=0$ and example given is the reaction $C+O_2\to CO_2$

@JohnRennie Sir I'll send you the picture :-)

@JohnRennie imgur.com/83FSr5B

OK. That's makes sense, though I'm not sure what the point of it all is.

@JohnRennie there are a few sums based on that....but those are more or less easy...I'm confused with the 3rd point...though previously there was 1 mole of $O_2$ and after reaction its 1 mole of $CO_2$ but won't that 1 $CO_2$ mole just take up more space and hence volume will increase?

No, because the number of moles of gas isn't changing and (at a given temperature) the volume is proportional to the number of moles of the gas. Assuming ideal behaviour, but both oxygen and carbon dioxide are pretty close to ideal.

@JohnRennie sir molecule size is increased right? I'm not getting this...help sir :-(

The size of the gas molecule is tiny compared to the spacing between gas molecules, so the size of the molecule doesn't make any difference.

@JohnRennie sir in kinetic molecular theory they say that the molecules aren't perfectly hard spheres and their size isn't negligible...Please tell me sir if that's right

@JohnRennie sir

For an ideal gas the size of the molecules is negligibly small, and that gives us the ideal gas equation of state $PV=nRT$.

@JohnRennie yes sir...got it

@JohnRennie KMT talks 'bout real ones....

We can take into account the sizes of the molecules, and that modifies the equation of state e.g. the Van der Waals equation of state.

@JohnRennie okay sir...got it ...thank you soo much :-)

But for gases like oxygen and $CO_2$ the ideal gas is a very good approximation.

@JohnRennie okay :-)

That's why there is no volume change, or more precisely a negligbly small volume change, in your reaction.

@JohnRennie got it sir! thank you so much for your help. You saved me a lot of time :-)

hii :-) @JohnRennie

@user8718165 hi

@JohnRennie hi.

@Nobodyrecognizeable morning :-)

Do you want to look at that triode problem?

@JohnRennie the triode calculation.

@JohnRennie yep.

It's actually simple, I just made a silly mistake in my approach to it.

@JohnRennie OK.

We can't just write $E=IZ$ because the complex impedance $Z$ is a function of frequency so it's different for the AC and DC parts of the current.

@JohnRennie OK.

We have to write $E = I_0 Z(0) + IZ(\omega)$ where $I_0$ and $Z(0)$ are the DC current and impedance and $I$ and $Z(\omega)$ are the AC current and impedance.

Is that OK as a starting point?

@JohnRennie OK. Do you always have to load the mathjax ie after one message of mathjax to read it?

There are different MathJax scripts. I use a script that turns MathJax on so I only have to load it once. But if I leave and reenter the room I have to run it again. But once started it automatically converts new posts to MathJax.

But there are are some scripts that just convert what's on the screen, and if new posts are made you have to manually run it again to convert the new posts.

@JohnRennie what if you close and use a new tab instead of leaving the room?

@user8718165 then I have to rerun the script to restart the MathJax rendering.

Or if I just press F5 to refresh the screen that requires me to restart the script.

@JohnRennie yes....that's irritating :-(

@Nobodyrecognizeable anyhow, shall we get back to the problem?

@JohnRennie javascript:(function(){if(window.MathJax===undefined){var script = document.createElement("script");script.type = "text/javascript";script.src = "https://cdn.mathjax.org/mathjax/latest/MathJax.js?config=TeX-AMS_HTML";var config = %27MathJax.Hub.Config({%27 + %27extensions: ["tex2jax.js"],%27 + %27tex2jax: { inlineMath: [["$","$"],["\\\\\\\\\\\(","\\\\\\

@JohnRennie yes.

@JohnRennie what is the dc impedance.

@Nobodyrecognizeable OK. The point of the question is that when we write $E = I_0 Z(0) + IZ(\omega)$ what we are going to find is that $I_0 Z(0) \gg IZ(\omega)$ so the voltage across the resistor-capacitor pair is mostly DC.

We discussed the ac impedance.

@JohnRennie OK.

The DC impedance is given by the AC impedance in the limit $\omega \to 0$, but we don't need to do that since the impedance of a capacitor is infinite for DC i.e. DC won't flow through a capacitor. So for DC the impedance is just $R$.

Is that clear, or do you want to do the calculation to show it's just $R$?

@JohnRennie OK.

@JohnRennie so we neglect the capacitor.

@Nobodyrecognizeable yes.

@JohnRennie OK now for ac.

The equation for the DC impedance looks like $1/Z = 1/R + 1/\infty$ so we get $Z=R$.

We are told the current is $1 + 0.5\cos\omega t$ (in milliamps) where $\omega=2000$, so the DC voltage is just $E_0 = 2000mV$. I'll write it in mV since we're given the current in mA.

@JohnRennie OK.

@Nobodyrecognizeable for the AC let's first compare the impedance of the resistor and capacitor to see how they compare.

@JohnRennie jwc and R.

R>>>wc ie. 2000>>>>2

The resistor is $2000$ ohms and the capacitor is $1/j\omega C$. We are told $\omega = 2000$ and $C = 10^{-4}$ so $Z_c = 1/0.2j$ or $|Z| = 5$. OK so far?

@JohnRennie OK.

So for the AC we can ignore the resistor to a good approximation since it's so much larger than the capacitor. Then the AC voltage is just $E = IZ_c$.

@JohnRennie OK.

$|I| = 0.5$ and $|Z| = 5$ so $|E| = 2.5mV$.

@JohnRennie OK.

Compare that to $E_0 = 2000mV$ and we can immediately see that the AC component of the voltage is a thousand times smaller than the DC component, which is what your book is saying.

@JohnRennie yep. But in case of ac why did we ignore the resistor?

@JohnRennie the voltage would be more if we included that.

The impedance is $1/Z = 1/R + 1/Z_c$ and if $R \gg Z_c$ that means $1/R \ll 1/Z_c$. Yes?

@JohnRennie OK so it would be less than 5 OK.

@JohnRennie is there anyway you could try my other old questions too?

Yes. Including the resistor would make the total impedance less than $5$, but only slightly less.

You can do the full calculation if you want, and you'll get basically the same answer.

@JohnRennie yep.

@JohnRennie is there anyway I could get all my answers to previous questions?

@Nobodyrecognizeable the only outstanding question I remember is that one about the two coils, but I don't understand what the question is asking so I don't know how to answer it.

@JohnRennie are those coils touching themselves?

Ie their emf should be same?

@Nobodyrecognizeable I think it's just a transformer i.e. two coils wound on the same former. So the secondary voltage is just the primary times the ratio of the number of turns.

@JohnRennie OK. I think you'll get it if you try it.

@JohnRennie OK. Have a nice day professor. Goodbye. Please try if you find time.

@Nobodyrecognizeable Bye

@user8718165 the HP 22m is a really nice monitor.

For chrome users, try this: chrome.google.com/webstore/detail/se-chat-mathjax/…

it works very well. Never have to check settings / scripts, nothing.

No need to refresh, etc.

@McSuperbX1 it works :-)

:D

@JohnRennie okay sir...Its beautiful too as you suggested :-)

@McSuperbX1 starred it 😎

@user8718165 have you got it now?

@JohnRennie no sir....By saturday :-)

That's a long time to have to wait ...

@JohnRennie how fast is it in the UK? It should be much faster :-P

dang monitors today are so pretty

@user8718165 in the UK delivery is usually one or two days, but then the UK is much smaller than India so the stuff doesn't have as far to travel.

I still rock my 4:3 Sony 2006 monitor lol

@JohnRennie that's pretty fast...:-)

What is the defintion of 'mean velocity'?

And how is 'modulus of mean velocity' different?

Apparently mean velocity is same as average speed, by looking at Irodov's solutions

And modulus of mean velocity is average velocity..?

Mean speed normally just means total distance travelled divided by total time taken.

and mean velocity?

total displacement divided by total time?

Mean velocity is just the vector.

So it's the vector from the start to the end point divided by the total time.

so the displacement, in other words.

It's always slightly ambiguous whether it means net displacement or total distance travelled.

The context will normally make it clear which is meant.

So what do you think mean velocity means here, with respect to context?

I thought mean velocity meant displacement/time :/

I guess I can ignore this little issue

I understood the question - got tied up in the grammar.

I would guess the mean velocity is defined as $\int \mathbf v(t)dt/\int dt$

So in this case the mean velocity is a vector pointing from the point $i$ to the point $f$ and with a magnitude equal to the distance $if$ divided by the total time taken.

Okay.

Thanks.

@JohnRennie Hi there!

@JohnRennie Hello sir!

@Dante @YUSUFHASAN hi. Sorry, I was working.

How are you going? :-)

doing*

@Dante pretty good :-) How's life now you no longer have the JEE hanging over your head?

Peaceful 😂

I bet! :-)

Haha

I had a simple doubt from vectors

@Dante Yes ... ?

@JohnRennie hi.

Sigh, Im not able to upload the image

Put it on Imgur?

I tried to upload the pic directly, i will try imgur now

@Dante how did your jee go?

@JohnRennie hi.

@Nobodyrecognizeable I scored really low. But I don't wanna talk about it please.

@Dante sorry.

Chill

imgur.com/a/xfuSKDS

@Dante brother...remember never let your marks affect your self–confidence and personality :-)

I just wanted to ask, how is it obvious from the gradient expression that vector points out in radial direction?

@user8718165 Yeah, I know that. That's why I didn't want to talk about it. All that matters is what I do next.

@Dante you're great going...:-)

@Dante yes that's the way.

Thanks :) I wish you do great ahead :)

@Dante the potential depends only on $r$ not $\theta$ or $\phi$, so it is spherically symmetric.

@Dante the equation is for a sphere. And a gradient is always normal to the surface. Now you know why it's radial.

@Dante That means the field must be spherically symmetric as well.

@JohnRennie hi.

@Nobodyrecognizeable hi

@JohnRennie 6.

a is done just multiplied by volume.

@JohnRennie This question wasn't from electrostatics

Now magnetic charge densities are : surface charge density $k=M.\hat{n}$ and volume charge density is $\rho =\nabla. M$

@JohnRennie ^^

but I think I get the point

Just not crystal clear tome

@Dante if the field is spherically symmetric it can only change in the radial direction.

@Dante this is magnetic properties of matter. Somewhere similar to polarisation.

It can't change in any other direction because then it wouldn't be spherically symmetric.

@JohnRennie great point.

@Dante do you get it now?

Wait..

i get it. Thank you both!

@JohnRennie Just wanted to ask a personal question: How much time did it take you to go from school to PhD, and did you like studying upto PhD? Was it worth it?

@YUSUFHASAN I took a year off after school to work and save some money, so I started my degree a year after leaving school and the degree lasted three years. Then I went straight into doing a PhD and that also lasted three years.

I loved doing the PhD. It was the best time of my life without doubt.

All the way through school and a degree you're basically being lectured at and you have to learn what you're told then try and regurgitate it in an exam.

But once you start the PhD you are deciding what you need to do and how to do it. For the first time you're doing what you decide to do not what someone is telling you to do.

@JohnRennie So the time taken for a PhD in the UK is around 3 years,after which you can take up a job as a research scientist in a company,right? And,did it(the PhD)get frustrating at some point? What did u do about it?

I was lucky in that my PhD went very well and I never found myself at a roadblock.

All PhD students have a supervisor who is supposed to help you when things get sticky. The supervisor will be an experienced scientist. Some supervisors are better than others in this respect so it depends who it is.

But in a way hitting a roadblock is not a bad thing because that does happen in real life and figuring out how to deal with it is an important part of learning to be a scientist.

@JohnRennie Ohh...So we really can't fix the time in which a PhD is done,right? But avg time for that in UK is 3 years,I had heard..

It depends on the country. In the UK in my time (the 1980s) PhDs were three years. You could take longer, and some people did, but the funding was only for three years so you had no money after that.

In the US it's rather different as I get the impression PhDs can go on a lot longer.

Ok.

So I won't regret doing a PhD,right,sir?

The best reason for doing a PhD is that you really, really want to.

It's quite a hard life. I spent the three years of my PhD with barely enough money to live. I didn't buy any new clothes for three years. That was OK because I enjoyed doing the research so much, but if you weren't enjoying the research then you'd probably get fed up pretty quickly.

Ok

Thnx for the advice sir! :)

It was absolutely amazing. I met loads of amazing people and got to play with cool technology. I used a Rutherford backscattering accelerator and also worked at a synchrotron, both of which were amazing.

Cool... I hope I get that level of passion one day :)

You're just starting your degree, yes?

Yes... But i was having a few thoughts about the future.. so...

See how much you like doing the degree. You almost certainly have some project work to do in the final year and that will give you some idea of what doing a PhD is like.

Ok.... If I won't like it,then I can opt for some other options too,right,sir?

The other option is to get a job :-)

Ok... So what kind of jobs can i get with a natural science degree?

Most jobs are basically managerial. That is your employer needs something to be done and it's your job to do it. Whether it's a science job, or engineering or working for a bank, the job will require you to analyse the problem, work out a strategy for addressing it then get it done.

The skills involved will depend on the job, but skills can be learned when you need them.

So doing a science degree doesn't necessarily mean you can only get a science job. Employers will view a deree as evidence that you're a smart guy who can work hard.

And that makes you attractive as an employee.

It's impossible to say now what you'll find you enjoy doing in three or four years. I ended up working in an area (colloid science) that I didn't even know existed when I started my degree.

@JohnRennie So by managerial, do u also mean consultancy firms like McKinsey and Deloitte will be in my range?

Absolutely, yes.

I've just looked on the McKinsey web site and it says:

> Our undergraduates join us from many backgrounds—there is no single “right” major or course of study. Our people do share some common qualities including excellent academic performance, leadership abilities, and experience working on or off campus. We look for strong problem solvers with potential—we will teach you the rest.

Ohh.

. So it means that i have to keep a good academic performance in my degree fir these guys?

The best reason for getting a good degree is that you love studying physics (or whatever) and you want to do well at it.

@JohnRennie hi.

But another good reason is that it makes it easier to get a job with McKinsey :-)

@Nobodyrecognizeable hi

@JohnRennie can I ask the question.

?

@Nobodyrecognizeable yes

@JohnRennie Thank you sir... This info was a gr8 help for me... Wish you a good day! :)

If the ball has a uniform magnetisation desn't that mean the volume charge density is zero i.e. all the charge is on the surface?

@JohnRennie yep.

Ah, yes, it would because if $M$ is constant then div M is zero.

@JohnRennie you've taken my words.

I don't know which direction the magnetization is?

So surface charge for surface charge density what should I do?

I would divide the ball into cylinders centred on the axis of the ball. Then the charge will be the charge density multiplied by the area of the end of the cylinder, and the dipole will be the charge multiplied by the length of the cylinder.

I can draw a diagram if it will help.

@JohnRennie OK lemme read.

@JohnRennie but can you fit the cylinder so that it covers the sphere?

@JohnRennie ah crap. Fine sorry. Go on with the discussion. No need for the figure.

@JohnRennie are you here?

@JohnRennie there we go...

Something like this. This is a cross section so you're seeing the top and bottom slices through a cylindrical shell of inner radius $x$ and thickness $dx$

@JohnRennie yep.

The charge at the end will be $dQ = dA \sigma$ and the dipole will be $dp = y dQ$

If you work out an expression for $dp$ you then just integrate from $x = 0$ to $x = r$ to get the total dipole.

@JohnRennie so $dp=ydA\sigma$

No, $dp = y dQ = y \sigma dA$

And $\sigma = M \cdot n$

@JohnRennie so $ y\sigma dx dy$

@JohnRennie so is M radial?

No, as I've draw the diagram $\mathbf M$ is horizontal.

@JohnRennie so $\sigma =Mcos\theta$

Yes. And $dA$ is going to be something like $2\pi x dx /cos\theta$

The $\cos\theta$ will cancel so $dQ = 2\pi M x dx$

@JohnRennie what about the y?

You get $y$ from the equation for a circle. Actually let's call the length of the cylinder $2y$, because then we have $x^2 + y^2 = r^2$.

So $y = \sqrt{r^2 - x^2}$ and therefore the expression for $dp$ is:

@JohnRennie OK.

$$ dp = 4 \pi M \sqrt{r^2 - x^2} x dx $$

@JohnRennie so $4\pi Mr$

Hmm, I'm not entirely convinced by the form of that equation ut it's worth integrating it to see what happens.

Sorry.

@JohnRennie yep you are a champion. One day I hope to be a problem solver like you.

$$ 4 \pi M \tfrac{1}{3} (r^2 - x^2)^{3/2} $$

It's $4\pi Mr^3/3$ which exactly matches the answer.

:-)

@JohnRennie now I badly have to write the practicals. So have a nice day professor. If I am determined I'll come back tomorrow. Good bye.

Bye

@JohnRennie

How to progress?