Presentation is loading. Please wait.

Presentation is loading. Please wait.

Charged Particles in Electric Fields Lesson 6. Behaviour of Particles and Newton’s Laws An electric field shows the direction and relative magnitude of.

Published byEileen Robbins Modified over 9 years ago

Similar presentations

Presentation on theme: "Charged Particles in Electric Fields Lesson 6. Behaviour of Particles and Newton’s Laws An electric field shows the direction and relative magnitude of."— Presentation transcript:

1 Charged Particles in Electric Fields Lesson 6

2 Behaviour of Particles and Newton’s Laws An electric field shows the direction and relative magnitude of an electric force. (Field theory, E = F/q) The electric force will cause an acceleration. (Newton's Second Law) An acceleration will cause an object to start moving one direction or another. (Newton's First Law) So, if we place a charged particle in an electric field, it will start to accelerate!

3 Recall the two categories of fields: 1.Non-uniform fields – Produced by single point charges or spheres – The field changes as the position of the test charge changes – Described by the equation **In a non-uniform field, the field strength is constantly changing. This makes a full analysis of the motion beyond our scope (needs calculus).

4 2. Uniform Fields – Produced by parallel plates field – has the same strength everywhere – Described by eqns:

5 Examples Two parallel plates are connected to a battery as shown. The battery supplies a potential of 2000 V. A sphere of mass 3.0 x 10 -15 kg and q = +2.6 x 10 -12 C is placed on the +ive plate and released. Ignoring gravity, a) what is the motion of the sphere?

6 b) if the separation between the plates is 4.5 cm, what is the electric field strength?

7 Examples A small charge of mass 5.0 x 10 -4 kg traveling at 350 m/s goes into a parallel plate capacitor as shown. The separation between plates is 5.50 cm and the potential difference between plates is 1000 V. The test charge has a q = +3.00 μC. a) Which plate is the positive plate in the capacitor?

8 b) Assuming the charge enters at the top of the capacitor how far from the entrance will the charge hit the bottom plate?

9 c) What is the final velocity of the particle when it hits the bottom plate?

Download ppt "Charged Particles in Electric Fields Lesson 6. Behaviour of Particles and Newton’s Laws An electric field shows the direction and relative magnitude of."

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.
Chapter 21 Electric Charge and Electric Field. Charles Allison © 2000 Question An  particle with a charge +2e and a mass of 4m p is on a collision course.

Chapter 21 Electric Charge and Electric Field. Charles Allison © 2000 Question An  particle with a charge +2e and a mass of 4m p is on a collision course.
…and all the pretty variations… F = k q 1 q 2 r2r2 E = k q 1 r2r2 U = k q 1 q 2 r V = k q 1 r.

…and all the pretty variations… F = k q 1 q 2 r2r2 E = k q 1 r2r2 U = k q 1 q 2 r V = k q 1 r.
Electric Energy and Circuits. Electrostatic Equilibrium No net motion of charge is occurring within a conductor Meets the following conditions ▫Electric.

Electric Energy and Circuits. Electrostatic Equilibrium No net motion of charge is occurring within a conductor Meets the following conditions ▫Electric.
CH 19-3. Review -- Gravitational Potential Energy and Gravitational Potential Earth If a ball is released from rest, it will move in the direction of.

CH Review -- Gravitational Potential Energy and Gravitational Potential Earth If a ball is released from rest, it will move in the direction of.
Scalar quantities have magnitude only. Vector quantities have magnitude and direction. Examples are: Scalar quantities: time, mass, energy, distance, speed.

Scalar quantities have magnitude only. Vector quantities have magnitude and direction. Examples are: Scalar quantities: time, mass, energy, distance, speed.
The Magnetic Force and the Third Left Hand Rule

The Magnetic Force and the Third Left Hand Rule
Review 2.

Review 2.
General Physics II, Lec 11, Discussion, By/ T.A. Eleyan 1 Review (Electrostatic)

General Physics II, Lec 11, Discussion, By/ T.A. Eleyan 1 Review (Electrostatic)
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.
Electrostatics #3 The Electric Field

Electrostatics #3 The Electric Field
Electric Fields. Fields Matter contains atoms and molecules A VERY large number together make up large masses like planets which can produce gravitational.

Electric Fields. Fields Matter contains atoms and molecules A VERY large number together make up large masses like planets which can produce gravitational.
Electric Charge and Electric Field

Electric Charge and Electric Field
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.
Chapter 22 Gauss’s Law. Charles Allison © 2000 21-10 Motion of a Charged Particle in an Electric Field The force on an object of charge q in an electric.

Chapter 22 Gauss’s Law. Charles Allison © Motion of a Charged Particle in an Electric Field The force on an object of charge q in an electric.
ELECTRICITY & MAGNETISM (Fall 2011) LECTURE # 4 BY MOEEN GHIYAS.

ELECTRICITY & MAGNETISM (Fall 2011) LECTURE # 4 BY MOEEN GHIYAS.
MAGNETISM MAMBO.

MAGNETISM MAMBO.
Chapter 17 Electric Potential Energy and the Electric Potential.

Chapter 17 Electric Potential Energy and the Electric Potential.
Electric Fields What is an Electric Field?. Answer Me!!! Explain what you think this drawing means? What is the significance of the arrows?

Electric Fields What is an Electric Field?. Answer Me!!! Explain what you think this drawing means? What is the significance of the arrows?

Similar presentations

Ads by Google