Table of contents

0. Math Review31m
- Math Review
  31m
1. Intro to Physics Units1h 29m
2. 1D Motion / Kinematics3h 56m
3. Vectors2h 43m
4. 2D Kinematics1h 42m
5. Projectile Motion3h 6m
6. Intro to Forces (Dynamics)3h 22m
7. Friction, Inclines, Systems2h 44m
8. Centripetal Forces & Gravitation7h 26m
9. Work & Energy1h 59m
10. Conservation of Energy2h 54m
11. Momentum & Impulse3h 40m
12. Rotational Kinematics2h 59m
13. Rotational Inertia & Energy7h 4m
14. Torque & Rotational Dynamics2h 5m
15. Rotational Equilibrium3h 39m
16. Angular Momentum3h 6m
17. Periodic Motion2h 9m
18. Waves & Sound3h 40m
19. Fluid Mechanics4h 27m
20. Heat and Temperature3h 7m
21. Kinetic Theory of Ideal Gases1h 50m
22. The First Law of Thermodynamics1h 26m
23. The Second Law of Thermodynamics3h 11m
24. Electric Force & Field; Gauss' Law3h 42m
25. Electric Potential1h 51m
26. Capacitors & Dielectrics2h 2m
27. Resistors & DC Circuits3h 8m
28. Magnetic Fields and Forces2h 23m
29. Sources of Magnetic Field2h 30m
30. Induction and Inductance3h 38m
31. Alternating Current2h 37m
32. Electromagnetic Waves2h 14m
33. Geometric Optics2h 57m
34. Wave Optics1h 15m
35. Special Relativity2h 10m

35. Special Relativity

Inertial Reference Frames

Physics

35. Special Relativity

Inertial Reference Frames

Previous problemNext problem

Problem 45b

Textbook Question

To initiate a nuclear reaction, an experimental nuclear physicist wants to shoot a proton into a 5.50-fm-diameter ¹²C nucleus. The proton must impact the nucleus with a kinetic energy of 3.00 MeV. Assume the nucleus remains at rest. Through what potential difference must the proton be accelerated from rest to acquire this speed?

Verified step by step guidance

Determine the relationship between the kinetic energy of the proton and the potential difference it must be accelerated through. The work-energy principle states that the work done on the proton by the electric field is equal to its kinetic energy. This can be expressed as:

K = q \cdot \Delta V

, where

K

is the kinetic energy,

q

is the charge of the proton, and

\Delta V

is the potential difference.

Rearrange the formula to solve for the potential difference:

\Delta V = \frac{K}{q}

. Here,

K = 3.00 \ \text{MeV}

(convert this to joules for consistency in SI units), and

q

is the charge of the proton, which is

1.602 \times 10^{-19} \ \text{C}

Convert the kinetic energy from MeV to joules. Use the conversion factor

1 \ \text{MeV} = 1.602 \times 10^{-13} \ \text{J}

. Multiply

3.00 \ \text{MeV}

by this factor to get the kinetic energy in joules.

Substitute the values of

K

(in joules) and

q

(in coulombs) into the formula

\Delta V = \frac{K}{q}

to calculate the potential difference.

Ensure the units are consistent and verify the calculation. The resulting potential difference will be in volts, which represents the energy per unit charge required to accelerate the proton to the given kinetic energy.

Verified video answer for a similar problem:

This video solution was recommended by our tutors as helpful for the problem above

Play a video:

Was this helpful?

Key Concepts

Here are the essential concepts you must grasp in order to answer the question correctly.

Kinetic Energy

Kinetic energy is the energy possessed by an object due to its motion, calculated using the formula KE = 1/2 mv², where m is mass and v is velocity. In nuclear physics, the kinetic energy of particles like protons is crucial for understanding their ability to overcome potential barriers, such as the Coulomb barrier in nuclear reactions.

Potential Difference

Potential difference, or voltage, is the work done per unit charge to move a charge between two points in an electric field. It is directly related to the kinetic energy gained by a charged particle when accelerated through an electric field, expressed as KE = qV, where q is the charge and V is the potential difference.

Coulomb Barrier

The Coulomb barrier is the energy barrier due to electrostatic repulsion that charged particles must overcome to get close enough for nuclear reactions to occur. In this context, the proton must have sufficient kinetic energy to overcome this barrier to successfully impact the nucleus of the carbon atom.

Watch next

Master Inertial Reference Frames with a bite sized video explanation from Patrick

Start learning

Related Videos

Related Practice

Textbook Question

Identify the unknown isotope $X$ in the following decays. $^{7} Be + e^{-} \to X + ν$

views

Textbook Question

The radium isotope ²²³Ra, an alpha emitter, has a half-life of 11.43 days. You happen to have a 1.0 g cube of ²²³Ra, so you decide to use it to boil water for tea. You fill a well-insulated container with 100 mL of water at 18℃ and drop in the cube of radium. How long will it take the water to boil?

views

Textbook Question

There is evidence that low-energy x rays have an RBE slightly greater than 1. Suppose that 10 keV photons with an RBE of 1.2 are used to make a chest x ray. A 60 kg person receives a 0.30 mSv dose from a chest x ray that exposes 25% of the patient's body. How many x ray photons are absorbed in the patient's body?

views

Textbook Question

All the very heavy atoms found in the earth were created long ago by nuclear fusion reactions in a supernova, an exploding star. The debris spewed out by the supernova later coalesced into the gases from which the sun and the planets of our solar system were formed. Nuclear physics suggests that the uranium isotopes ²³⁵U and ²³⁸U should have been created in roughly equal numbers. Today, 99.28% of uranium is ²³⁸U and only 0.72% is ²³⁵U. How long ago did the supernova occur?

views

Textbook Question

A typical electron in a piece of metallic sodium has energy −E₀ compared to a free electron, where E₀ is the 2.36 eV work function of sodium. At what distance beyond the surface of the metal is the electron’s probability density 10% of its value at the surface?

views

Textbook Question

What is the wavelength, in nm, of a photon with energy (a) 0.30 eV, (b) 3.0 eV, and (c) 30 eV? For each, is this wavelength visible, ultraviolet, or infrared light?

views

Textbook Question

What is the energy, in keV, of 75 keV x-ray photons that are backscattered (i.e., scattered directly back toward the source) by the electrons in a target?

views

Textbook Question

55 keV x-ray photons are incident on a target. At what scattering angle do the scattered photons have an energy of 50 keV?

views

Show more practices

Download the Mobile app

Privacy

Do not sell my personal information

Accessibility

Patent notice

Sitemap