T is the period of the cyclotron motion. This is power input because it is a rate of increase of energy. Find an expression for r(t), the radius of a proton's orbit in a cyclotron, in terms of m, e, B, P, and t. Assume that r= 0 at t = 0.

College Physics
11th Edition
ISBN:9781305952300
Author:Raymond A. Serway, Chris Vuille
Publisher:Raymond A. Serway, Chris Vuille
Chapter1: Units, Trigonometry. And Vectors
Section: Chapter Questions
Problem 1CQ: Estimate the order of magnitude of the length, in meters, of each of the following; (a) a mouse, (b)...
icon
Related questions
Question

Hello, please I really need help with part D and part E I really don't understand understand those two problems I have done all of the other parts I just need help with that one, please I need help with part D and part E and can you label them 

**Problem 3:** A proton in a cyclotron gains \(\Delta K = 2e \Delta V\) of kinetic energy per revolution, where \(\Delta V\) is the potential between the dees. Although the energy gain comes in small pulses, the proton makes so many revolutions that it is reasonable to model the energy as increasing at the constant rate \(P = \frac{dK}{dt} = \frac{\Delta K}{T}\), where \(T\) is the period of the cyclotron motion. This is power input because it is a rate of increase of energy. Find an expression for \(r(t)\), the radius of a proton’s orbit in a cyclotron, in terms of \(m, e, B, P,\) and \(t\). Assume that \(r = 0\) at \(t = 0\).

---

a) Using the formula for the radius of the cyclotron orbit, \(r = \frac{mv}{qB}\), work out a formula for the kinetic energy \(K\) of the proton in terms of \(m, e, B,\) and \(r\).

b) Show that equation \(\frac{dK}{dt} = P\) results in the following differential equation for \(r\) as a function of \(t\): 
\[ r \frac{dr}{dt} = \frac{Pm}{e^2B^2}.\] 
Make sure to show all the steps that lead to this equation.

c) This differential equation can be solved by separating the variables. For that, rewrite it as \(r \, dr = \frac{Pm}{e^2B^2} \, dt\) and integrate both sides. The expression on the left side should be integrated from \(r = 0\) (center) to \(r(t)\) (an intermediate radius at the moment of time \(t\)), while the expression on the right side should be integrated from \(0\) to \(t\). From here, obtain the expression for \(r(t)\) in terms of \(m, e, B, P,\) and \(t\).

d) Express the power input of the cyclotron, \(P = \frac{\Delta K}{T}\), in terms of \(m, e, B,\) and \(\Delta V\).

e) A relatively small cyclotron is
Transcribed Image Text:**Problem 3:** A proton in a cyclotron gains \(\Delta K = 2e \Delta V\) of kinetic energy per revolution, where \(\Delta V\) is the potential between the dees. Although the energy gain comes in small pulses, the proton makes so many revolutions that it is reasonable to model the energy as increasing at the constant rate \(P = \frac{dK}{dt} = \frac{\Delta K}{T}\), where \(T\) is the period of the cyclotron motion. This is power input because it is a rate of increase of energy. Find an expression for \(r(t)\), the radius of a proton’s orbit in a cyclotron, in terms of \(m, e, B, P,\) and \(t\). Assume that \(r = 0\) at \(t = 0\). --- a) Using the formula for the radius of the cyclotron orbit, \(r = \frac{mv}{qB}\), work out a formula for the kinetic energy \(K\) of the proton in terms of \(m, e, B,\) and \(r\). b) Show that equation \(\frac{dK}{dt} = P\) results in the following differential equation for \(r\) as a function of \(t\): \[ r \frac{dr}{dt} = \frac{Pm}{e^2B^2}.\] Make sure to show all the steps that lead to this equation. c) This differential equation can be solved by separating the variables. For that, rewrite it as \(r \, dr = \frac{Pm}{e^2B^2} \, dt\) and integrate both sides. The expression on the left side should be integrated from \(r = 0\) (center) to \(r(t)\) (an intermediate radius at the moment of time \(t\)), while the expression on the right side should be integrated from \(0\) to \(t\). From here, obtain the expression for \(r(t)\) in terms of \(m, e, B, P,\) and \(t\). d) Express the power input of the cyclotron, \(P = \frac{\Delta K}{T}\), in terms of \(m, e, B,\) and \(\Delta V\). e) A relatively small cyclotron is
Expert Solution
trending now

Trending now

This is a popular solution!

steps

Step by step

Solved in 5 steps with 5 images

Blurred answer
Knowledge Booster
Ferromagnetism
Learn more about
Need a deep-dive on the concept behind this application? Look no further. Learn more about this topic, physics and related others by exploring similar questions and additional content below.
Recommended textbooks for you
College Physics
College Physics
Physics
ISBN:
9781305952300
Author:
Raymond A. Serway, Chris Vuille
Publisher:
Cengage Learning
University Physics (14th Edition)
University Physics (14th Edition)
Physics
ISBN:
9780133969290
Author:
Hugh D. Young, Roger A. Freedman
Publisher:
PEARSON
Introduction To Quantum Mechanics
Introduction To Quantum Mechanics
Physics
ISBN:
9781107189638
Author:
Griffiths, David J., Schroeter, Darrell F.
Publisher:
Cambridge University Press
Physics for Scientists and Engineers
Physics for Scientists and Engineers
Physics
ISBN:
9781337553278
Author:
Raymond A. Serway, John W. Jewett
Publisher:
Cengage Learning
Lecture- Tutorials for Introductory Astronomy
Lecture- Tutorials for Introductory Astronomy
Physics
ISBN:
9780321820464
Author:
Edward E. Prather, Tim P. Slater, Jeff P. Adams, Gina Brissenden
Publisher:
Addison-Wesley
College Physics: A Strategic Approach (4th Editio…
College Physics: A Strategic Approach (4th Editio…
Physics
ISBN:
9780134609034
Author:
Randall D. Knight (Professor Emeritus), Brian Jones, Stuart Field
Publisher:
PEARSON