A cyclotron, designed to accelerate protons, has a magnetic field of 0.450 T magnitude in a region of radius 1.20 m. What are the values of (a) the frequency of the cyclotron, (b) the maximum speed acquired by the protons, (c) the acceleration experienced by the protons and (d) the magnetic force exerted on the protons?
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A cyclotron, designed to accelerate protons, has a magnetic field of 0.450 T magnitude in a...
A cyclotron designed to accelerate proton has a magnetic field of magnitude 0.450 T over a region of radius 1.02 m. What are (a) the cyclotron frequency and (b) the maximum speed acquired by the protons?
Tutorial Exercise A cyclotron designed to accelerate protons has a magnetic field of magnitude 0.575 T over a region of radius 1.30 m. (a) What is the cyclotron frequency? (b) What is the maximum speed acquired by the protons? Part 1 of 4 - Conceptualize Cyclotrons can be used to produce radioactive substances used in diagnosis and treatment. We expect the angular frequency to be on the order of millions of radians per second. We expect the maximum speed of...
A cyclotron uses a magnetic field of 0.575 T to accelerate protons. It has a maximum radius of 0.600 m. (proton mass 1.673x10-27 kg, proton charge 1.602x10-19 C) a. Derive an expression for the frequency of the alternating voltage on the dees of the cyclotron. b. What is the frequency of the voltage? c. What is the maximum kinetic energy of the protons as they emerge from the instrument? d. What is the equivalent accelerating voltage?
A cyclotron (figure) designed to accelerate protons has an outer radius of 0.354 m. The protons are emitted nearly at rest from a source at the center and are accelerated through 614 V each time they cross the gap between the dees. The dees are between the poles of an electromagnet where the field is 0.832 T. The black, dashed, curved lines represent the path of the particles. Alternating AV D2 After being accelerated, the particles exit here. North pole...
A cyclotron for accelerating protons has a magnetic field of 0.2 T and a radius of 1.6 m. The frequency of the cyclotron is?
pls answer q 5-9 17. A cyclotron (Fig. 28.16) designed to accelerate protons has an outer radius of 0.350 m. The protons are emitted nearly at rest from a source at the center and are accelerated through 600 V each time they cross the gap between the dees. The dees are between the poles of an electromagnet where the field is 0.800 T. (a) Find the cyclotron frequency for the pro- tons in this cyclotron. Find (b) the speed at...
The magnetic poles of a small cyclotron produce a magnetic field with magnitude 0.85 T. The poles have a radius of 0.40 m, which is the maximum radius of the orbits of the accelerated particles. a) What is the maximum energy to which protons (q = 1.60×10 -19C, m = 1.67×10-27 kg) can be accelerated by this cyclotron? Give your answer in electron volts and in joules. b) What is the time for one revolution of a proton orbiting at...
The magnetic poles of a small cyclotron produce a magnetic field with magnitude 0.83 T . The poles have a radius of 0.36 m , which is the maximum radius of the orbits of the accelerated particles. Part A What is the maximum energy to which protons (q=1.60×10−19C, m=1.67×10−27kg) can be accelerated by this cyclotron? Give your answer in joules. Part B What is the maximum energy to which protons (q=1.60×10−19C, m=1.67×10−27kg) can be accelerated by this cyclotron? Give your...
A cyclotron (figure) designed to accelerate protons has an outer radius of 0.339 m. The protons are emitted nearly at rest from a source at the center and are accelerated through 612 V each time they cross the gap between the dees. The dees are between the poles of an electromagnet where the field is 0.736 T. BAA The black, dashed, curved lines represent the path of the particles. Alternating AV D After hoine An illustration and a photo show...
A cyclotron (figure) designed to accelerate protons has an outer radius of 0.333 m. The protons are emitted nearly at rest from a source at the center and are accelerated through 618 V each time they cross the gap between the dees. The dees are between the poles of an electromagnet where the field is 0.792 T. please copy the question in chegg in order to see the figure i didn't know how to upload its the same figure