Presentation is loading. Please wait.

Presentation is loading. Please wait.

Accelerating Charge Through A Potential Difference.

Published byMarylou Horn Modified over 8 years ago

Similar presentations

Presentation on theme: "Accelerating Charge Through A Potential Difference."— Presentation transcript:

1 Accelerating Charge Through A Potential Difference

2 - + Distance d Difference in potential (potential difference ∆V) This potential energy is converted totally to kinetic energy by the time the charge strikes the oppositely charged plate Directly from the definition of potential (V=W/Q) The potential energy given to a charged particle by an electric field is given by W = ∆ VQ where ∆V is the potential difference that the charge falls through

3 - + Distance d Difference in potential (potential difference ∆V) Notice that energy given to the charged particle has no dependence at all on the distance d between the plates. It is only dependent on the charge of the particle and the potential difference between the plates

4 1.Calculate the final kinetic energy of 1) an electron 2) a proton accelerated in opposite directions through a p.d. of 5kV. 2.Calculate the maximum velocity of each. - + 5 000 V Because W=VQ the potential energy that they have due to the field is the same before the start of their journey. This becomes kinetic energy as they are about to strike the opposite plate. How can we calculate the final velocity of each of them?

5 - + Difference in potential (potential difference ∆V) The force on the charged particle is constant within the field. F=QE (because the field is uniform E i.e. it has the same value at each point) Also As F=ma (And the mass of the particle remains the same the acceleration of the particle is also constant F Force on the particle Distance within field r Acceleration of particle Distance within field r

6 + - Constant Acceleration due to the field Horizontal motion (constant velocity) A charged electron which enters a uniform electric field at right angles to it accelerates at right angles to the field. There is no component of this acceleration in the horizontal direction The resulting path of the electron is parabolic

Download ppt "Accelerating Charge Through A Potential Difference."

Similar presentations

Motion of Charged Particles in a Uniform Electric Field

Motion of Charged Particles in a Uniform Electric Field
Lecture 9 Review.

Lecture 9 Review.
>80>80>90>70>70>60>60>50>50>29>40>40 Average 66.4 Median 69 High 96 Low 29.

>80>80>90>70>70>60>60>50>50>29>40>40 Average 66.4 Median 69 High 96 Low 29.
Chapter 23 home work.

Chapter 23 home work.
Chapter 25 Electric Potential

Chapter 25 Electric Potential
Problem 2 Find the torque about the left hand segment on the loop as a function of θ, the angle the plane makes with the horizontal plane.

Problem 2 Find the torque about the left hand segment on the loop as a function of θ, the angle the plane makes with the horizontal plane.
Example 6: Electric field on disk’s axis z Example 2 Consider a constant, vertical electric field somehow created in a limited region of space. An electron.

Example 6: Electric field on disk’s axis z Example 2 Consider a constant, vertical electric field somehow created in a limited region of space. An electron.
Kinetic energy Vector dot product (scalar product) Definition of work done by a force on an object Work-kinetic-energy theorem Lecture 10: Work and kinetic.

Kinetic energy Vector dot product (scalar product) Definition of work done by a force on an object Work-kinetic-energy theorem Lecture 10: Work and kinetic.
Electric Fields Electric fields are created by electric charges. Any object with a charge has an electric field around it. Opposite charges attract each.

Electric Fields Electric fields are created by electric charges. Any object with a charge has an electric field around it. Opposite charges attract each.
Norah Ali Al-moneef king Saud unversity

Norah Ali Al-moneef king Saud unversity
Centripetal force on charges in magnetic fields

Centripetal force on charges in magnetic fields
Electric Potential Energy A charge q in an electric field behaves similarly to a mass m in a gravitational field. The electric force F = qE is conservative.

Electric Potential Energy A charge q in an electric field behaves similarly to a mass m in a gravitational field. The electric force F = qE is conservative.
Mechanics Motion Equations and Graphs Combining and Resolving Vectors Force and Acceleration Gravity and Free-Body Diagrams Projectile Motion Work and.

Mechanics Motion Equations and Graphs Combining and Resolving Vectors Force and Acceleration Gravity and Free-Body Diagrams Projectile Motion Work and.
1 My Chapter 17 Lecture Outline. 2 Chapter 17: Electric Potential Electric Potential Energy Electric Potential How are the E-field and Electric Potential.

1 My Chapter 17 Lecture Outline. 2 Chapter 17: Electric Potential Electric Potential Energy Electric Potential How are the E-field and Electric Potential.
The Magnetic Field The force on a charge q moving with a velocity The magnitude of the force.

The Magnetic Field The force on a charge q moving with a velocity The magnitude of the force.
The force on a charge q moving with a velocity The magnitude of the force.

The force on a charge q moving with a velocity The magnitude of the force.
Electric Potential Energy and the Electric Potential

Electric Potential Energy and the Electric Potential
Physics 121 Practice Problem Solutions 09 Magnetic Fields

Physics 121 Practice Problem Solutions 09 Magnetic Fields
Chapter 6 Motion of Charged Particles in Electric Fields.

Chapter 6 Motion of Charged Particles in Electric Fields.
How Are Electric And Magnetic Fields Used To Steer Particles In The Large Hadron Collider?

How Are Electric And Magnetic Fields Used To Steer Particles In The Large Hadron Collider?

Similar presentations

Ads by Google