H.C. Verma is wrong!

Back in 2011 when I was preparing for my JEE, I followed HCV for physics and tried to derive every equation myself by understanding the concept. My derivation did not give me a 2 in the denominator and I tried discussing it with my lecturer. Sadly, they were all focused only on formulae that mattered in exams and didn't want to discuss it. Now I feel relieved that I was thinking along proper lines and can mark the highlighted doubt as closed (if I ever open my HCV book again)!
Thank you

I like how you force more on the intuition part rather than pen and paper proof , it at the end just starts to make sense.

Be so legendary that when you do even a small mistake people become shocked.

It enrages me that people in the comments hate mathematical proofs. They think that intuition matters more than the truth. Physics is not always intuition. Sometimes you need to get to the truth the way you are supposed to, the language of physics and probably science- mathematics! Just because people dont want to run their brains to a higher degree they despise mathematics.

There is another mistake realted angular velocity reagrding the radius ...hcv uses r but actually the frame is actually at 2r .
It is corrected by my teacher A reputed one senior faculty allen kota iid passout ..teaching since 21 years ❤
He even added that there are many other mistakes he can point out ..man he is a legend ..i mean he is a character of a person

To get that fraction of ts, you need the probability distribution of times between collisions P(t). The numerator would be the integral of P(t)*t^2 dt and the denominator would be the integral of P(t)*t dt. The denominator is exactly tau, so to get Feynmans result the numerator would have to be exactly 2 tau^2 which I'm not sure how he got because I would expect that to depend on the distribution.

The factor of 2 comes from rms time over mean time, as we know rms time is sqrt(2) times average time for sinsoidal curves hence the rms^2 is 2 times greater but for that we need to assume that distribution of the collision is a sinusoidal curve which might come from quantum wave function of electron in a substance, hence feynman probably got it right as he worked on field of quantum electrodynamics.

Mahesh sir because of u i got 94 in physics in my board exam tq

Really got a deep understanding after seeing this, rather listening to this, the intuition. Had to repeat watching this 2-3 times to understand better.
Thanks and please keep doing what you're doing 'cause many people aren't doing science the way it was and is meant to be.

I'm very, very confused. I understand why HCV approach is wrong, but the final answer IS correct. The assumption of Tau in HCV's lecture is actually 2 times of the tau in the feynmann lectures, as Tau in HCV is average time between successive collisions while in feynmann its since the last collision. Won't 2Tau(feynmann) = Tau(HCV)?
Please help I'm losing my mind over this

Maybe there is a statistical solution to the problem which gets the numerator to be twice that of denominator, leading to the removal of 1/2.

Also, the diagram in the video is slightly misleading.
Drift velocity is the average distance traveled per unit time "in the direction of current"...
So more accurately, L1, L2,... must represent the components of the respective distances along the current...
Only then, you can use L1 = ½a(t1)²
(Coz acceleration is in the direction of electric field which is again in the direction of current)
This derivation still works because this fact is already implicitly taken into account in the equations...

Prof. Verma mistakenly assumes = ^2; i.e. average of t-squared = square of average t, which is clearly not true. Assuming time-interval between successive collision is exponentially distributed, we get the first moment = tau and second moment = 2 tau^2.

my physics teacher (The Physics shelter on YT) also pointed this out in our class and also told that the correct approach is also discussed in E&M of purcell and morin

HC verma use equation of uniform motion L=ut+1/2at^2 and after collision electron has u=0 and it becomes L=1/2at^2.

Such a coincidence, I was studying this an hour back!

I had the same issues with this derivation back in 2021.
But yeah now I know. Thanks a lot.

Hi Mahesh! Wonderful video again. I think none of them are 'wrong' per se. Actually, the motion of electrons in a material is a very complex quantum mechanical problem. We have to come up with approximations in order to predict experimentally measurable quantities (like conductivity for example).
H.C. Verma chooses a lesser sophisticated model for his calculation, and the one chosen by Feynman (Drude Model) is the just a more sophisticated model. But both of them are still models. They are simplications of the quantum mechanical problem using equations from classical physics. Now, the 'test' for a model is how well it can explain an experiment. As far as I know, people only roughly measure the order of magnitude in case of drift velocities, and for metals both the models work well. Both of them fail in case of other materials. Nevertheless, Feynman's model is indeed more sophisticated and has a subtle catch like you mentioned, which people usually miss. Thanks for making this video!

i cannot speak to the physics, but i can confirm your statistics are perfect: the only way to make Σt²/Σt come out Verma's way is if the variance of t is 0. that's not just sufficient but also necessary

a great teacher knows how to teach you well, but a legendary teacher knows where you can mistakes

I was searching for a video on drift video derivation, I had a test next week and I suddenly remembered this video(I had seen this video for timepass and due to the thumbnail, I had not studied Electric current yet)

Thanks for sharing this valuable information. By thinking so, you actually managed to change the way I look over the derivations in my textbook. Now I can think out of the box.❤

I derived the equation in slightly different way and I got result without that 2 in the denominator.. That's what I have been teaching to my students.. If you provide your email so that I can send you the derivation to check by yourself, whether it is right or wrong? By the way it was nice explanatory video.

Hi Mahesh. The part where you have made sigma( u t ) = 0
Can we also not say that each new ut also contains the memory of previous acceleration v = u + at
Also the summation of t squares looks like can be done using rms value calculations

well if you are dealing with this problem in this quantum state, then you can't take the acceleration due to electric field common for all the motions , you will have to take the components of acceleration along the direction of motion to use it in the newton's equation as you did at 11:22 ,so its better to solve it larger dimentions as in hcv

I don't know much but the 1st problem you raised is insignificant as by taking the average time we are also considering the average distance. Therefore, the ratio ultimately remains almost the same with some negligible error (probably). I might be wrong. I am just in class 12. Sorry for the inconvenience caused.

Did Resnick Halliday made the same mistake? As Prof. Verma often mentions he referred Resnick Halliday before writing Concepts of Physics

t1^2 can be represented as T(tau) +x1(letting the variable be any real number here )
If we do this, then we can clearly see that you cannot just divide the taus becasue there are constants(zero power polynomials) that arise when we calculate (T+x)^2. while t1+t2+t3.... may equal N*T, the above doesnt have to equal tau.

I wish I had a Physics teacher like him when I was in my high school. My high school teacher couldn’t explain properly and would scold the class if the students were not able to understand. Teachers should owe up if they don’t know something and try to find solution instead of insulting students. Afterall students want to learn and it is their responsibility to teach them properly and with care.

Use L-Hopital's rule to solve the time equation...you will get 2×tau

Sir there was a question of kinematics earlier of three particles on the corner of equilateral triangle. Sir you had done that question using relative motion but I want to know other ways to do that question too. Please If you can reupload and show us other ways to do that problem that would be very beneficial for me. Thankyou.

Thank you for taking me back to high school.

Sir I have a doubt
At 9:14 it's an avg time that mean most of electron collide exactly at 6 min not before it is'nt it. Therefore if we apply 2nd eq of motion for all electrons then it shouldn't be wrong, right?

I too realized the discrepancy while I was preparing for JEE. I followed the physics book by DC Pandey where the correct derivation was there and also a comment on how some books derive the equation with a factor of half. Although theoretically not having the half made more sense to me, I believe there is no real way (not inferred from this formula*) to measure the relaxation time for electrons.

can you link a proof for 18:20 ? I tried to find it online, didn't find it

u1t1 u2t2..might not add up to 0. Since the motion is not biased we cant have any biased initial velocity (from the point an elecyron strikes a lattice) so u1+u2+...un should be 0..not their sort of weighted timed mean.

I'd be quite interested in knowing how the term you obtained (in place of tau) could be proven to be equal to twice the average time. Any hints, please?

Glad this video came in my recommendation
I was so confused between these formula what to use in exam

With arbitrary collision statistics, the general drift velocity is proportional to E(T^2)/E(T), where T is the random variable denoting the time between successive collisions. This follows from a simple application of the Strong Law of Large Numbers. This quantity is at least E(T) thanks to Jensen's inequality. Now, assuming T is exponentially distributed with mean t, this works out to be 2t.

Ok we need more of these for all concepts in HCV

Why don't we use 1st eq of motion to prove professor's assumption wrong as the equations of motion are only valid for straight line and professor has implemented the equation wrongly, we could use v=u+at where 'u' is the initial velocity which we can assume to be zero just after a collision, and we get v=at where v would be the drift velocity (of that particular time interval ) and further we could find the average d. Velocity

just realized you're the voice behind Indian SyllabusKhan academy videos.

But there is a mean free distance between collisions that depends on the density of the conductor.

Can U please make a video Schrodinger wave eqn to explain it to 11th standard students...I mean it's there in the syllabus (Idk why they want to add as much syllabus as they can and don't give us time to allow to even think properly)...it's been many days I have been stucked in that topic..I don't understand what does this eqn tell us...does it tell probability?does it tell energy??does it tell momentum??does it tell the shape of orbital??does it tell the size of orbital?does it tell the orientation of orbital??.

I liked your videos on khan academy india but they haven't been arranged in a playlist so I don't know which one to watch after the first 4 videos of this topic(current electricity). Neither on the site nor in youtube playlists. Going back to HCV for now 😅

Basically we get the more accurate answer if we differentiate wrt T instead of divide by a fixed value T. Is that it?

Why so complications?
Force= charge × Electric field
F= eE
Now as per Newton's law of motion Force is change in momentum.
mu/t=eE
u = eEt/m
It is as simple as this. No need for integration and statistics average. Though I didn't study HC Verma during school days.

Some math that made the process slightly more rigorous in my head:
What has really stumped us is that sum-of-squares term. But if t1, t2, t3, ... tn are all independent random variables following the same statistical distribution, then there's a nice way to express that sum-of-squares term:
(t1²+t2²+...tn²)/n=(variance of t's)+(mean time 'tau')². This comes from the definition of the variance when used to describe random variables.
Further, we can assume that the t's follow an EXPONENTIAL distribution with average value tau. This is a decent assumption because in the real world, many 'waiting times' follow this distribution. In this case, t1, t2, ... tn are the times that we have to wait between collisions.
In an exponential distribution, the variance is numerically equal to the mean, squared.
This means that the sum of squares of t's = n*( tau²+tau²)! That's where the factor of 2 comes from!
This isn't anything novel that wasn't covered in the video, but hopefully the math made it slightly more rigorous :)

Sir why are we applying the equations of motion here? I mean how are we sure of the fact that acceleration of particles is constant, like if we try to delve deeper into this problem can't we say that the electron, as it moves through the conductor would experience a number of different forces like repulsive force due to other electrons and attractive forces due to positive kernels and in the interval between the collision shouldn't these forces vary?

I didn't find any contradictions here.
The invariant between the original model and the simplified model is the total displacement of an electron.
Take acceleration due to electric field (E) = a = (eE)/m, time between collosions = t1,t2,.... for total of 'n' collisions of a single electron.
Then, L(displacement) = sum of displacements along field = 1/2 * a * Sigma(ti^2) (i = 1,2,3,...,n)
So assuming a common time (I think HCV does the mistake of calling it average time, because people usually associate average with 'mean') 'tau' between successive collisions to get the simplified picture,
L (displacement) = n * 1/2 * a * tau^2
We should have the same displacement for both scenarios:
This gives: tau = sqrt(Sigma(ti^2)/n) (i = 1,2,3,...,n) , i.e. tau = RMS value of actual time intervals (not the mean)
The vd (drift velocity) = total displacement/total time = L/(n*tau) = 1/2 * a * tau
This also solves the problem of L being small displacement between successive collisions, as now we're talking about total displacement over n collisions. (although individual displacements also work, like given in the book, because all of them are equal in the simplified model)
I don't think HCV is assuming t1=t2=t3=...tn, it just fails to derive the value of 'tau' and calls it the average value, which leads to this ambiguity.
The only confusion could be calling the RMS value of something as its average, when the common assumption is average implies 'mean'.
The true mean that we're calculating is that of the individual displacements. So 1/2 * a * tau^2 is the average (mean) displacement between collisions.
Let me know if there's anything wrong with this.

wonderful derivation sir.... I had no answer for this dilemma for many years.... NCERT gives right value....

First time watching your video! Very intuitive! Thank you

No Mahesh your argument is totally fine. ProfHC Verma can also make mistakes he is a human
I also found some errors in his book
The problem is for over many years no one tried to correct it

The derivation can be done by using the first equation of motion for n collisions of an electron and then averaging it out. It gives what Feynman derived.

Hi makesh sir plz write physics textbook for class 11 and class 12 Surely ur book will be next halliday and Resnick book

13:27 this inference is wrong, the summation of displacements results in zero when there is no Electric field, but if there is an overall net electric field the summation cant be assumed to be zero, just because 2 expression look same in structure doesn't mean they will evaluate to same value.

I think I am still confused about something, Comparing the derivations in both cases,
The feynman lectures assumed the following - "It is just the acceleration F/m (where m is the mass of the S-molecule) times the average time since the last collision. Now the average time since the last collision must be the same as the average time until the next collision, which we have called τ"
The fenman lectures said this before that line about τ - "If we start to observe an S-molecule at some instant we may expect that it is somewhere between two collisions. In addition to the velocity it was left with after its last collision it is picking up some velocity component due to the force F. In a short time (on the average, in a time τ) it will experience a collision and start out on a new piece of its trajectory. It will have a new starting velocity, but the same acceleration from F."
Meanwhile for Hc verma the τ is defined as - " If τ be the averge time between successive collisions"
I feel like in Feynman's definition the τ represents that if you are looking at a particle at a given instance, the avg time until the next collision and the time since the last collision is τ. The highest probility will be that you are looking at the particle when it right between the the past and the next collision. if you look at it like that, then the time between successive collisions will be 2τ, now if you take this value and plug it through hc verma's derivation(which assumed τ to be the time b/w successive collisions), you get L = (1/2)(F/m)(2τ)^2, for the drift velocity, you divide L by 2τ and you get v = (1/2)(F/m)(2τ) = Fτ/m.
I think the problem lies in the assumtions sorrounding what τ represents, one assumes that it is the avg time until the next collision and time since the past collision, meanwhile the other assumes it as the time b/w 2 collisions, this why hc verma has a 1/2 in the value, hence his τ(time b/w succesive collisions) becomes τ/2 which then represents the time since the last collision and till the next collision.

It should be (Expected length) / time, rather than Expected drift velocity per collision. Meaning you only need to do E(t1^2+....) / E(t1+...) and not E(t1^2+..../t1+...). At least both of these can't give same answer either.

Excellent work and please keep up the good work. The problem is that a large cross-section of world population continues to live with tribal mindset and herds mentality even today. And we human beings are not to be blamed for this - indeed we lived the life of herdsmen and tribes million years back. This gives rise to cult following. Once somebody becomes a CULT - he becomes a GOD - other members of the tribe won't allow you to question that CULT - that's why you get to Jaggi Vasudev, Ramdev etc.
Two years back I got into an argument with some kids over a TH-cam video by H.C. Verma - question was regarding the magnetic effect of a moving charge. I found H. C. Verma's explanation rather naive and incomplete and I have seen many such flaws (of Prof Verma) before. I commented that Prof Verma loves Physics and probably wants to learn Physics, but he is NOT an expert. This irked some kids - some of them appeared and probably about to appear at IIT JEE. They immediately started to throw their weight around by flaunting their IIT JEE ranks and all - which of course I won't cross-verify. I off course won't throw my weight around saying I completed my B.Tech in so and so year - did my Masters in so and so year - happened to work in so and so Semiconductor MNC Majors in so and so places and in so and so positions and took part in so and so R&D projects and that my son is a student at so and so IIT at that point in time. Honestly, when I wrote IIT in 1998 paper pattern was 40 X 2 + 15 X 8 in three hours - my son thinks it was tougher then paper-wise may not be competition wise. And anyway, an IIT rank itself isn't a testimony of one's understanding of Physics.
I just tried to be humble. But finally I had to say that Prof Verma is more of a HYPE and a CULT. And it is extremely difficult to convince others that CULT-FOLLOWING isn't a good idea.

This explanation is incomplete. You are right that due to the effect of variance, HC Verma's value is an underestimate. But there is no reason why the correction factor is multiplying by 2! The correction factor can be a any arbitrarily large positive number. Proof:
Correction factor is [(t1^2 + t2^2 .... t^n))/n divided by [(t1 + t2 + .... tn)/n]^2
suppose t1 = t2 =t3... = tn = 1 (distribution with 0 variance); then correction factor is 1.
But suppose t1 = 1 while t2 ... tn is 0. (distribution that maximizes variance).
Then correction factor is (1/n) / (1/n^2) = n
n can be made arbitrarily large is unbounded.
All you've proved is that drift velocity lies somewhere between HC Verma's answer and Infinity. You've not proved that twice of HC Verma's answer is correct.

Drift veocity is average of drift velocity of large number of electrons and for each electron a is qE/m
this can be checked in "drift velocity and collision time" by Donal M Title American General of physics.
Lastly in my humble opinion in science we are all learning it is about betterment not about being right and wrong.

yea thankfully our teacher explained this to us, and he told us that its not 1/2

The point of contention is due to the use of different equations of motion to derive the drift velocity.

If we take infinite electrons at a single time and find drift velocity
We get average final velocity of these infinite electrons as eEt/m but this average final velocity.
Of we want to find out the drift velocity (which is the average velocity during the whole free path
To find that we have to find average of inital average velocity and final average velocity.
Means that drift velocity will be equal to (initial average velocity + final average velocity )/2
= (0 + eEt/m)/ 2
So the correct drift velocity will be
eEt/2m

- or + depends on charge of charge carrier.
For electrons it is -

I studied the same topic 5 minutes ago and just opened TH-cam to see this recommended lol

I'd summarize this as: avg(f(t_i)) is the same as f(avg(t_i)) ONLY if f is linear! Linearity. That's the first thing they tell you in Maths to be able to change the order of the operations! :D The distance calculation (double integral of acceleration) is a square of a, definitely not linear!

i would love to see the QM derivation of the Sommerfeld model. The problem is really that the classical physics is insufficient and the best we can do classically is to first establish the simple instantaneous velocity function as being qE/me times t . Now we can take the Expectation (averaging) but we have to then employ a "mean free path time". But this is problematic in QM and of course one needs to account for the fact that Expectations under any distribution obey: E[t^2]= E[t]^2 + var[t]. Getting the distribution right is where the real work s and this is why Sommerfeld makes the proper correction over the original Drude model.

I would debate of not doing Vd = L1 + L2 + L3 +.....
Since you cannot add them directly because they are vectors, you need to consider their direction and add for which you need to perform parallelogram addition for every two set (L1 + L2) of distance, get it's resultant and add to L3 and it's resultant to L4 etc. ..

I think, he uses the equation of motion, s = ut + 1/2 at²
Even if we assume that he's correct by saying that sum of all u will become 0, but in such case, we will find S rather V (v is drift velocity while S would be displacement)
In order to find the correct formula using the formula HC verma derived, we just keed to differentiate both side with respect to time
S = 1/2 a × t²
dS/dt = 1/2 a × d(t²)/dt
V = 1/2 a × 2t = a × t
Then we can replace a by eE/m

Please make a video to show the full calculation of 9.13.
I will explain why Verma sir has written 1/2....will wait for you reply

Can you solve it rigorously that how did you get that 2t term as in chat gpt i got the result that if t1 is not equals to t2 and so on then there's no direct proof

I ask this dout when i m in current electricity but that time i did not get the satisfactory answer but now i am quite clear about it🙏

Both formulas are correct in their own senses and both are widely used. The problem is most physicists present them sloppily as they are based on approximate models. Feynman describing the one with ‘½’ factor as wrong is quite unwarranted. Under the classical assumption, ' = - Eeτ/m' is strictly correct if one defines 'τ' as simple (unweighted) mean time between collisions & all electrons are equally probable to scatter. Here 'τ' naturally equals the 'relaxation time', which is defined as the time needed for the drift velocity to drop to 1/e-th of its initial value after the field 'E' is switched off. And ' = - Eeτ/2m' is strictly correct if one defines 'τ' as self weighted mean time between collisions (with no additional assumption that electrons are equally probable to scatter). Here 'τ' doesn't necessarily equal the relaxation time. Note that there are different types of mean, but all of them are equal in order of magnitude. And physicists are interested only in this order of magnitude as the number is extreme (~10-¹⁴ s). So most physicists present drift velocity sloppily. It's ok to be a fan of Feynman (or Verma), but not a blind one. It's not proper to title & thumbnail the video 'H.C. Verma is wrong'.

I know I'm really late to the video to get a response but for some reason, a program I made to test out this factor of 2 seems to be giving me a different answer, and I'm perplexed as to why. If someone could offer an explanation, that would be great.
When I compute the parts of the equation pertaining to tau, I get feynman's value not to be twice verma's, but rather 4/3 times it. I'm using completely randomised intervals and as far as I can tell, the program is logically correct, so why the discrepancy?
Below is the program and some sample outputs. It was made in Python and uses the default "random" library :
Program :
```
import random
collision_count = 10000 # this value can be adjusted for n collisions
total_duration = 0
squared_duration = 0
for n in range(collision_count):
# generate a random time between collisions
t_n = random.random()
total_duration += t_n
squared_duration += t_n ** 2
verma_tau = total_duration / collision_count
feynman_tau = squared_duration / total_duration
# feynmann_tau should ideally be twice that of verma_tau
factor = feynman_tau/verma_tau
print(f" collisions : {collision_count}" +
f"
duration : {total_duration}" +
f"
verma : {verma_tau}" +
f"
feynmann : {feynman_tau}" +
f"
factor : {factor}")
```
Outputs :
#1
collisions : 100000000
duration : 49998360.500493824
verma : 0.49998360500493827
feynmann : 0.6666662707776526
factor : 1.3333762629497983
#2
collisions : 1000000
duration : 500194.6072459398
verma : 0.5001946072459398
feynmann : 0.6668238495570457
factor : 1.3331288260554481
#3
collisions : 10000
duration : 4996.37857230061
verma : 0.49963785723006104
feynmann : 0.6659245185748535
factor : 1.3328143753290993

Thank you for the explanation. Could you provide any reference that proves that the fraction you mention on minute 18:26 is equal to 2.tau?

Professor, if you could show some light on independent and identical distribution of these times and then whether we can assume the sum of squares to be actually n times tau^2 according to this rule of statistics.

I asked this discrepancy between hcv and Resnick to my teacher. He told me that actually both of them are wrong and don't agree experimentally. But for jee domain we take the Resnick formula.

15:18 the assumption "time gap between collision is equal" is mentioned in his book. And based on the the assumption he is quite correct, but yeah the assumption goes very far way from the actual values.

it v = ri while deriving u have to keep it mind it is not a fundamental law it work only in certain range so in approximation both derivation are correct

@Mahesh_Shenoy, @FloatHeadPhysics..
It was a nice video but i feel there is a small mistake in your derivation as well.
In this equation of drift velocity, (Vd=L/t), over a long period of time, "L" is the horizontal length covered by the electron (call it drift length). It cannot be equal to (L1 + L2 + L3 + L4.....).
It is not even the displacement, displacement would be a straight path connecting the starting and ending points of the electron, in the respective time period being considered.
It is just the horizontal length travelled in time "t".
I might be wrong, please correct me if i am.
Thank you!

All of what you said makes complete sense mathematically.
When we average some values, we think that 'this average would be the value if all quantities were to be equal'.
So HC Verma has taken an average value to calculate the distance an electron would travel if collision times were equal.
Is not what Feynman doing too in his book by saying V=a*𝜏 (where 𝜏 is the value of avg. time we'd get if all times were equal)?
The logic is same and i thought about it the same way as both seemed equally correct. I thought maybe Newtonian mechanics break when dealing with electrons but no! because we assumed electron to be a particle. I also thought that both equations of motion connect then the derived formula for Vd must connect mathematically but they do not. { if d/t = (ut + 1/2 at^2)/t then how 1 result is half of the other- i wonder how a physicist did not think about this)
Now that i think, it makes sense - how did he average out (ut) but not the square of t instead averaged out t first then squared it.
According to my observation, all of the problem lies in not using the simplest forms for the physical quantities we are referring to (for example 𝜏)
Is it because symbols are just used for short notations and while explaining mathematically we must refer to the simplest form and most original definition of formulas and physical quantities we are using?
I am a newbie at Physics and go introduced to real Physics only by you Mahesh, so i am just thinking. I saw your comment in Verma's video and discovered that you have a channel too. Hope you read this.

I look at this video with so dumb look
How did I pass my exams I wonder😅

HC Verma is not wrong both the formulas are correct from their point of view
In HC Verma time is taken as a linearly increasing function due to which it's average comes out to be ½(time)
So, both the forms are correct

Amazing analysis @mahesh_shenoy.
Your analysis is rigorous and clearly explain all the assumptions taken by yourself and HCV.
It is clear that HCV derivation is correct only when time taken between each collision is same which is not true.
However it is still not clear why the formula by Feynman is correct. What are the assumptions taken by Feynman.
I feel that the question boils down to the statistical distribution of time taken between collision events. And suspect that if we assume different distributions we will get different answers corresponding to each distribution. My first guess is that the distribution of time taken between collisions is gaussian distribution. I think that we can get a more accurate answer from statistical mechanics. The question becomes more interesting if we try to calculate the drift velocity of a different class of particles i.e. bosons which follow a different statistical distribution.
In cold atom labs we can create bosonic state of matter and therefore this question is not entirely theoretical.
P.s. - Can you please suggest some resources for Feynman's derivation of drift velocity?

Our physics sir warned us about it

he has already made ideo on that actually what happens is that all these physicist try to model those quantum phenomens into very suffocative mathematics thats why these problems arises actually all these are just mere approximation of that quntum phenomenon.

12:44 all the electrons can drift automatically . But what if half of them drift the other way ? Then the current would be zero right? 👀

Bt there is a big mistake in other formula also... He is calculating drift velocity just before the collision... The e- has not travelled full distance between 2 collisions with this... This is the velocity gained till just b4 next collision... And to use this as avg is also wrong v=u+at❌

What if we start with v=u+at
and for each collision find out v and then average out v.
then
average v= [(u1+u2+.......) + a(t1+t2+......)]/N
(Here, N represents the no of collisions considered)
average v = 0 + a tau= a tau = ( e E / m) tau

The answer is given by HC Verma sir himself. He said that all these derivations are approximeted that Newtons law directly can be applied. But the reality is there quantum physics must be applied. So both the methodes are approximated and hence order is important and not the magnitude.

In the linked video, HC Verma directly addresses the issue of drift velocity from five years ago. I found this video suggested by TH-cam after watching the current one. The fact that the host failed to acknowledge Verma's input in his video significantly undermines his credibility. When using a provocative title that seems to leverage a legend's reputation, it's essential to acknowledge their contributions. Such omissions are simply theatrical.
m.th-cam.com/video/jEKUog6-LiA/w-d-xo.html#

I don't think this is a mistake to be honest, I think it is more like calculating the escape velocity of a rocket without taking air resistance in to account. The assumption that each each collision takes roughly the same time interval is probably an "ideal case scenario". We have to keep in mind that this book is meant for 12th grade students and diving deep into complexities of a topic like drift velocity, might not be necessary at that moment.

I got 23 in physics...
Out of 25.

I already like your video, but I will wait!

DC Pandey has also teased about this in his Understanding Physics series, just read it yesterday 😅

sir the most important part here is that we have mathematical conception of Ohms law and resistance of a conductor, here drift velocity or most probable vel or rms vel may have less importance

Rajwant sir of pw also pointed out same think

🕉 Satyameva Jayate: Truth and Honesty and Reality gets created when Good Thoughts, Good Deeds, Good Acts are allowed to achieve the small steps needed for the correct choices and correct decisions to be made. Satyameva Jayate

Just a little difference between instantaneous and avg velocity...