What Is the Average Velocity of Electrons in a Copper Wire Carrying 1.0A?

AI Thread Summary
The discussion centers on calculating the average velocity of electrons in a copper wire carrying a current of 1.0 A. The formula used relates current (I) to electron density (ρ), charge per electron (e), drift velocity (v), and cross-sectional area (A). Participants confirm that the correct average velocity is approximately 2 x 10^-5 m/s, aligning with the book's answer. There are some calculation errors noted, particularly in unit conversions and the application of the formula. Ultimately, the consensus is that the average drift velocity can be derived correctly using the provided values and equations.
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Copper has approximately 10^29 free electrons per cubic meter. What is the approximate average velocity of electons in a 1.0 mm radius wire carrying 1.0A?

resisivity, p of copper = 1.68 * 10^-8 ohms meter

The answer in the book apparently is 2 * 10^-5 m/s.

Please help by showing all your work. Your attempts will be greatly appreciated.
 
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the answer is 2 * 10^-5 m/s.
please read this before posting...
https://www.physicsforums.com/showthread.php?t=28 :-p
 
i have tried it many times and it did not reach tat ans.
 
the current I is equals to free electrons density \rho times charge per electrons e times drift velocity v times cross section area A
I=\rho e v A
ring the bell?
since you have everything except v, this is one equation with one unknown... solving it is straight forward...
you must be careful on the unit conversion, it is a little bit tricky...
the area is not given directly, but you have radii, the area shold be piece of cake
charge of electron is on the back of your textbook... if not, look it up on internet
show me your calculation ...
 
Within 1 sec, e drifted for length L

L = v * 1 sec = v

total e drifted within 1 sec is 1 Ampere.

1.0 A = 6.24*10^18 e = 10^29 * v * (π * (0.001)^2)

v = 2 * 10^-6 m/s

therefore, does not match with the ans in the book.
 
Within 1 sec, e drifted for length L

L = v * 1 sec = v

total e drifted within 1 sec is 1 Ampere.

1.0 A = 6.24*10^18 e = 10^29 * v * (π * (0.001)^2)

v = 2 * 10^-6 m/s

therefore, does not match with the ans in the book.

what the hack are you doing here?
 
I=\rho e v A
\rho is the free electronss density
e is the charge per electron...
A is the cross section area
I is the current
plug in all number and solve for v...
 
it appears that I have punched in the wrong notation the whole time. ths for ur help.
 
I don't know why, but i just can't seem to get the answer :(

the formula i use is

I = NaQv

so V = I / NAQ

A (cross sectional area) = (0.001)^2 multiplied by Pi
Q = 1.6 * 10^-19
N= 10^29
I = 1

is this right so far?

Regards,
Mo
 
  • #10
Yes,it's identical to what the OP did.You should get the same answer.2\times 10^{-5}m \ s^{-1}

Daniel.
 
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