Presentation is loading. Please wait.

Presentation is loading. Please wait.

Electric Fields Electric fields are created by electric charges. Any object with a charge has an electric field around it. Opposite charges attract each.

Published byEmmeline Stanley Modified over 8 years ago

Similar presentations

Presentation on theme: "Electric Fields Electric fields are created by electric charges. Any object with a charge has an electric field around it. Opposite charges attract each."— Presentation transcript:

1 Electric Fields Electric fields are created by electric charges. Any object with a charge has an electric field around it. Opposite charges attract each other; like charges repel. An electric field is a region in which a charge experiences a force. We can represent electric fields by using electric field lines. As with gravitational fields, the lines will indicate 2 things about the field: 1.Its direction - from the direction of the field lines 2.How strong the field is – from how close the field lines are to each other Uniform electric fields have the same strength field at all points. An electric field between oppositely charged plates is a uniform magnetic field. A radial electric field spreads outwards in all directions. The electric field around a point charge is a radial field. The electric field strength at a point is the force per unit charge exerted on a positive charge at that point. Units for electric field strength are NC -1

2 Uniform Electric Fields In a uniform field, the field strength is the same at every point. The field lines are parallel and evenly spaced. Electric field strength is directly proportional to the voltage of the plates and inversely proportional to the separation between the plates. The force on a charge in a uniform electric field: hence An electric field between oppositely charged plates is a uniform field.

3 Coulomb’s Law Any two point charges exert an electrical force on each other that is proportional to the product of their charges and inversely proportional to the square of the distance between them.

4 Radial Electric Fields Radial magnetic fields spread outwards in all directions. For a radial field, the electric field strength depends on the distance r from the point charge Q. There is an inverse square relationship – field strength decreases as you get further from the point charge. This is shown by the fields lines: they get further apart from each other as you move away from the point charge. Electric field strength for a radial field:

5 The effect of a uniform magnetic field on the motion of charged particles e- ++++ - --- The electron is moving to the right. Its initial horizontal velocity will not be affected because there is no component of the electric field in this direction. It will therefore accelerate upwards, curving towards the positive plate, following a parabolic trajectory.

6 Comparing Gravitational and Electric Fields Gravitational FieldsElectric Fields Arises from massesArise from electric charges Only gravitational attraction; no repulsion Both electrical repulsion and electrical attraction are possible as there are both positive and negative charges Field strength is force per unit mass: g= f/m Field strength is force per unit positive charge: E = F/Q Uniform gravitational fields have parallel gravitational field lines Uniform electric fields have parallel electric field lines Radial gravitational fields : force is given by F = –GMm/r 2 Radial fields have radial electric field lines diverging outwards. The force is given by Coulomb’s law: F= Qq/4πε o r 2 For a radial field: Force and field strength obey an inverse square law with distance For a radial field: force and field strength obey an inverse square law with distance

Download ppt "Electric Fields Electric fields are created by electric charges. Any object with a charge has an electric field around it. Opposite charges attract each."

Similar presentations

Electrostatics Ch 32 & 33.

Electrostatics Ch 32 & 33.
Chapter 12: Electric Field Lines and Electric Charges

Chapter 12: Electric Field Lines and Electric Charges
…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.
Coulomb’s Law. Coulomb’s Law… = the relationship among electrical forces, charges, and distance. It is like Newton’s law of gravity. But, unlike gravity,

Coulomb’s Law. Coulomb’s Law… = the relationship among electrical forces, charges, and distance. It is like Newton’s law of gravity. But, unlike gravity,
Universal Forces Chapter 12.4. Electromagnetic Forces Electric Forces Magnetic Forces They are the only forces that can both attract and repel.

Universal Forces Chapter Electromagnetic Forces Electric Forces Magnetic Forces They are the only forces that can both attract and repel.
Static Electricity Chapter 19.

Static Electricity Chapter 19.
Reading Quiz The voltage (or electric potential) of a battery determines how much work the battery can do on an electric charge. how much net electric.

Reading Quiz The voltage (or electric potential) of a battery determines how much work the battery can do on an electric charge. how much net electric.
Nadiah Alenazi 1 Chapter 23 Electric Fields 23.1 Properties of Electric Charges 23.3 Coulomb ’ s Law 23.4 The Electric Field 23.6 Electric Field Lines.

Nadiah Alenazi 1 Chapter 23 Electric Fields 23.1 Properties of Electric Charges 23.3 Coulomb ’ s Law 23.4 The Electric Field 23.6 Electric Field Lines.
Coulomb’s Law Physics 102 Professor Lee Carkner Lecture 10.

Coulomb’s Law Physics 102 Professor Lee Carkner Lecture 10.
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.
Electrical & Gravitational Force. Newton’s Universal Law of Gravitation Every object in the universe attracts every other object with a force that for.

Electrical & Gravitational Force. Newton’s Universal Law of Gravitation Every object in the universe attracts every other object with a force that for.
ELECTRICITY & MAGNETISM (Fall 2011) LECTURE # 4 BY MOEEN GHIYAS.

ELECTRICITY & MAGNETISM (Fall 2011) LECTURE # 4 BY MOEEN GHIYAS.
Physics Electrostatics: Electric Field Diagrams Science and Mathematics Education Research Group Supported by UBC Teaching and Learning Enhancement Fund.

Physics Electrostatics: Electric Field Diagrams Science and Mathematics Education Research Group Supported by UBC Teaching and Learning Enhancement Fund.
Electromagnetic Force

Electromagnetic Force
Electrostatic Force Coulomb’s Law. Charges Two charges of the same type repel one another ++ The two charges will experience a FORCE pushing them apart.

Electrostatic Force Coulomb’s Law. Charges Two charges of the same type repel one another ++ The two charges will experience a FORCE pushing them apart.
Fields Model used when force act a distance. Quantity / unit measure.

Fields Model used when force act a distance. Quantity / unit measure.
My Chapter 16 Lecture Outline.

My Chapter 16 Lecture Outline.
e-e- e-e- e-e- e-e- e-e- e-e- e-e- e-e- e-e- e-e- p+p+ p+p+ p+p+ Connecting two parallel plates to a battery produces uniform electric field  the electric.

e-e- e-e- e-e- e-e- e-e- e-e- e-e- e-e- e-e- e-e- p+p+ p+p+ p+p+ Connecting two parallel plates to a battery produces uniform electric field  the electric.
Book Reference : Pages 86-88 1.To understand what we mean by “point charge” 2.To consider field strength as a vector 3.To apply our knowledge of equipotentials.

Book Reference : Pages To understand what we mean by “point charge” 2.To consider field strength as a vector 3.To apply our knowledge of equipotentials.
Part 3.  The electric field can push AND pull charges  Because there are two types of charges (+ and -)  The gravitational field can only pull  Only.

Part 3.  The electric field can push AND pull charges  Because there are two types of charges (+ and -)  The gravitational field can only pull  Only.

Similar presentations

Ads by Google