Magnetic Fields, Deuterium and curved tracks

AI Thread Summary
The discussion focuses on calculating the time required for a deuteron to complete half a revolution in a magnetic field. The initial calculations involved determining the velocity and period using the cyclotron frequency formula. After some adjustments, the correct expression for the time to complete half a revolution was found to be m_D/(2eB). Additionally, the conversation shifted to finding the potential difference needed to accelerate the deuteron, leading to the use of kinetic and electric potential energy equations. Ultimately, the participants confirmed the accuracy of the derived formulas and calculations.
TFM
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[SOLVED] Magnetic Fields, Deuterium and curved tracks

Homework Statement



A deuteron (the nucleus of an isotope of hydrogen) has a mass of m_D and a charge of e. The deuteron travels in a circular path with a radius of r in a magnetic field with a magnitude of B.

Find the time required for it to make 1/2 of a revolution.

Homework Equations



Cyclotron frequency: \omega = \frac{v}{R}

The Attempt at a Solution



IO have already calculated the velocity in the previous part to be:

\frac{reB}{m_D}

Frequncy is 1/Period, so I get

period = \frac{1}{\frac{v}{R}} = \frac{R}{v}

= \frac{r}{\frac{reB}{m_D}}

Which I have rearranged to get:

\frac{m_D}{eB}

Sincve this is for one whol revolution, I multiplied it by a half to get:

\frac{m_D}{2eB}

Which Mastering Physics says is wrong, but also says:

Your answer is off by a multiplicative factor.

Any Ideas?

TFM
 
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T = 2*pi/omega
 
So that would make:

period = \frac{2\pi}{\frac{v}{R}} = \frac{2\piR}{v}

and this the fraction would be:

\frac{2\pi m_D}{2eB}

Does this look more right?

TFM
 
Does the above look correct now?

TFM
 
Yes.
 
Thanks,

The next part of the question asks:

Through what potential difference would the deuteron have to be accelerated to acquire this speed?

But I am niot sure what formula to use.

Any suggestions,

TFM
 
Use equation of equivalence of potential and kinetic energy (potential energy turns to kinetic)
 
Kinetic Energy:

K.E. = \frac{1}{2}mv^2

Electric Potential:

U= q_0V

Equate:

\frac{1}{2}mv^2 = q_0V

V = \frac{mv^2}{2q_0}

Is this correct?

TFM
 
Putting in my values I get

\frac{4 \Pi^2m_D^3}{\frac{4e^2B^2}{2e}}

Does this look correct?

TFM
 
  • #10
Nope, there is no place for pi here v=omega*r.

using omega=eB/m you should get it
 
Last edited:
  • #11
I looked at the wrong part :redface: - i had already found the speed to be:

v = \frac{reB}{m_D}

so putting in this v, I get:

V = \frac{m_D(\frac{r^2e^2B^2}{m_D^2})}{2e}

is this better?

TFM
 
  • #12
This should be correct.
 
  • #13
Indeed it is correct.

Thanks, michalll :smile:

TFM
 

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