Lesson 4 Electric Field Theory (Looks pretty cool, not an electric field.)

Slides:

Advertisements

Similar presentations

Electric Fields The space around a magnet is different than it would be if the magnet werent there. A paperclip will move without you ever touching it!

Advertisements

P30 Unit B – Forces and Fields

Electric Forces and Fields

…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,

TOC 1 Physics 212 Electric Force Dependence on Amount of Charge Dependence on Distance Magnitude of the Coulomb Force Direction of the Coulomb Force Coulomb.

IB Physics 12 Mr. Jean October 10 th, In class discussion: 1.Briefly explain the following with relation to charged particles or points of mass.

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.

Charge Coulomb’s Law 1 TOC Dependence on Amount of Charge Dependence on Distance Magnitude of the Coulomb Force Direction of the Coulomb Force Coulomb.

Electric Forces Physics A Static #3.

Equipment Clear Tape Forces and Fields (6) In the most fundamental equations about the universe, we find fields. Black holes, the Aurora Borealis, and.

Unit 10: Electric Fields An electric force is a field force. Recall the difference between a field force and a contact force. ◦ Field forces act through.

Electric Field Physics Mrs. Coyle.

Electrical & Gravitational Force. Newton’s Universal Law of Gravitation Every object in the universe attracts every other object with a force that for.

 The gravitational force between two masses, m1 & m2 is proportional to the product of the masses and inversely proportional to the square of the distance.

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.

Electric Field. Analogy The electric field is the space around an electrical charge just like a gravitational field is the space around a mass.

Electric Fields Fields: Action at a distance Remember in the lab, a charged balloon was able to attract small pieces of paper without touching them?Remember.

Electricity Fields. electric charges can exert forces on each other A force is that it is a push or pull. What exactly is causing the push or pull between.

Electrostatics Properties of Electric Charges.

Electric Charge O All ordinary matter contains both positive and negative charge. O You do not usually notice the charge because most matter contains the.

Electrical Charges and Coulomb’s Law

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.

Chapter 18 Summary Essential Concepts and Formulas.

Electric Force SWBAT describe the electric force conceptually and solve for the force mathematically. Luke, use the force! I can’t, I don’t have enough.

SACE Stage 1 Physics Electric Fields. Introduction Consider two charges, the force between the two charged bodies is inversely proportional to the square.

S-113 Define these terms A.Charge B.Potential Difference (Voltage) C.Current (Amps) D.Resistance.

Electrostatics Review EQ: What causes you to get an “electric shock” when you walk across the carpet on a cold winter’s day and reach for the door knob?

Electrostatic Forces Homework: Complete handout. Magnitude of Force According to Coulomb’s Law  The magnitude of force exerted on a charge by another.

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.

Electric Charge and Electric Field

Forces and Fields Lesson 4

More Fields Electric Fields at a Location vs. Electric Fields around a Point Charge.

21-1 Creating and Measuring Electric Fields

Example : ( Physics Classroom ) Two balloons are charged with an identical quantity and type of charge: -6.25nC. They are held apart at a separation distance.

Electric Fields Chapter What do you already know about charged particles? Like charges repel. Opposite charges attract. Electric charges exert a.

Coulomb’s Law Electrostatic Force.

Electric Charges Conduction: Transfer of a charge easily. Induction: Influence transfer of a charge. (polarization of a charge) Insulator: Does not transfer.

1.Electrostatics Electric Field. The Electric Field is defined as the force on a test charge (small positive charge), divided by the charge: EE F F Electric.

Electric field. How is one charge able to exert an electrical force on another charge even though the two charges are not in contact with each other?

Electrostatic Forces and Electric Fields Your Guide to the Universe.

Physics Electrostatics: Electric Fields at a Point Science and Mathematics Education Research Group Supported by UBC Teaching and Learning Enhancement.

Electric fields around point charges Direction of E field is: Away from positive Toward negative.

Electric Fields, Electric Potential Energy & Electric Field Intensity.

Electric Forces and Fields Electric Force. Coulomb’s Law Electric force – the force of attraction or repulsion between objects due to charge –Electric.

Electric Force and Electric field 1. There are two types of electric charge (positive and negative)

IB Physics 12 Topic 5 – 2 Electro-statics & fields.

An electric field is said to exist in a region of space if an electric charge placed in that region is subject to an electric force.

Warm-Up: April 6/7, 2016  A black sphere with charge of 3.3 µC is pulled towards a gold sphere 4.7 cm away. The attractive force is 6.2 N. What is the.

Electric Fields Aim: How do charged objects exert a force on each other?

Charge (q) Comes in + and – Is conserved total charge remains constant Is quantized elementary charge, e, is charge on 1 electron or 1 proton e =

Property of space around a charged object that causes forces on other charged objects Electric Field.

Electric Field Physics Mrs. Coyle.

Electric Force Holt: Chapter 17-2 Pages

Physics Section 16.2 Apply Coulomb’s Law

Electrostatic force & Electric Fields

Electric Fields Chapter 14.1.

Electric Fields and Potential

Electric Field Physics Gillis.

Electric Fields and Potential

Electric Field Physics Mr. Dellamorte.

Electric Field.

Coulomb’s Law.

Describe Gravity in terms of force, mass, and distance

Electric Fields Physics Chapter 22 A.

Lesson 3: Electric Fields

Electrical Energy and Current

Force and Electric Fields

Electric Fields.

Electric Force Holt: Chapter 17-2 Pages

Presentation transcript:

Lesson 4 Electric Field Theory (Looks pretty cool, not an electric field.)

Objectives define vector fields. compare forces and fields. explain, quantitatively, electric fields in terms of intensity (strength) and direction, relative to the source of the field and to the effect on an electric charge.

Write the parts in slimer green

Recall: The Gravitational Field An imaginary field which exists around all bodies in all directions. Shows the direction of the force of gravity. Only exists in theory, in practice, it does not really exist (although we can calculate the magnitude). Field lines are a vector quantity.

The Electric Field All electrically charged objects (can be positive or negative) create electric fields. The magnitude and direction of fields are represented by field lines. The greater the density of the lines, the greater the field. The electric field is the direction a positive test charge would move when placed in the field.

Direction of the Electric Field Field lines move towards negative charges. Remember: the field lines move in the same direction as a positive test charge would! Field lines move away from positive charges.

The density (number of lines) indicates the relative magnitude of the field. Electric fields are greatest at points or sharp edges.

Electric Fields Applet A Really Cool Electric Fields AppletA Really Cool Electric Fields Applet 3-D nature of vectors

Field Strength Fields are vectors, they have magnitude and direction. Now that we know how to find the direction of the field, we need a way to find the magnitude. We have two formulas to calculate the field strength or field intensity at any point in space.

1 st E-field Formula E = F e q Where: E = absolute value of electric field strength F e = electric force acting on the test charge q = magnitude of test charge This is the definition of the electric field strength: the amount of electric force per unit of charge acting on a body.

Look familiar? This equation looks pretty similar to the equation for finding the gravitational field at any point… E = F e g = F g q m All of physics is related in one way to another! Another example of the appeal of GUTs!

Unit of Electric Fields The unit of the electric field is newtons per coulomb (N/C), another reminder of the first-principles definition of the term: the amount of electric force (N) per unit of charge (C).

Inverse Square Law Notice from the applet that the magnitude of the E field is stronger when closer to the charge, weaker when farther away. Electric fields obey the inverse square law. We can manipulate the general equation for the electric force to gain a second equation for determining electric field.

Take F e = kq 1 q 2 and divide by q on both sides. r 2 E = kq where: E = magnitude of the r 2 electric field. k = coulomb’s constant q = magnitude of the charge on the charge producing object. Second Electric Field Equation

Examples A positive test charge (q = 4.0 μC) is placed in an electric field. The force on the charge is 0.60 N left. What is the magnitude and direction of the E-field at the location of the test charge?

Find the electric field at point B.

What is the electric field at a point half- way in between a charge of μC and a charge of 3.00 μC if the charges are 44 cm apart?