Electric field Revisited

Electric field Revisited

Electricity  s b b  r r z a Cleanair 50 kV q b a + Dirty air -

Electricity Electric Fields Electric Charge • Electric forces affect only objects with charge • Charge is measured in Coulombs (C). A Coulomb is a lot of charge • Charge comes in both positive and negative amounts • Charge is conserved – it can neither be created nor destroyed • Charge is usually denoted by q or Q • There is a fundamental charge, called e • All elementary particles have charges thatare simple multiples of e Particleq Proton e Neutron 0 Electron -e Oxygen nuc. 8e ++ 2e

Charge Can Be Spread Out • Charge may be at a point, on a line, on a surface, or throughout a volume • Linear charge density  units C/m • Multiply by length • Surface charge density units C/m2 • Multiply by area • Charge density units C/m3 • Multiply by volume

Concept Question A box of dimensions 2 cm 2 cm  1 cm has charge density  = 5.0 C/cm3 throughout and linear charge density  = – 3.0 C/cm along one long diagonal. What is the total charge? A) 2 C B) 5 C C) 11 C D) 29 C E) None of the above – 3.0 C/cm 2 cm 5.0 C/cm3 1 cm 2 cm

The Nature of Matter + + + + + + + + + + + + + + + + • Matter consists of positive and negative charges in very large quantities • There are nuclei with positive charges • Surrounded by a “sea” of negativelycharged electrons • To charge an object, you can add some charge to the object, or remove some charge • But normally only a very small fraction • 10-12 of the total charge, or less • Electric forces are what hold things together • But complicated by quantum mechanics • Some materials let charges move long distances, others do not • Normally it is electrons that do the moving Conductors allow their charges to move a very long distance Insulators only let their charges move a very short distance

Some ways to charge objects – – + + – – + + – – – – + + – – + + + + • By rubbing them together • Not well understood • By chemical reactions • This is how batteries work • By moving conductors in a magnetic field • By connecting them to conductors that have charge already • That’s how outlets work • Charging by induction • Bring a charge near an extended conductor • Charges move in response • Separate the conductors • Remove the charge +

Coulomb’s Law • Like charges repel, and unlike charges attract • The force is proportional to the charges • It depends on distance q1 q2 • Other ways of writing this formula • The r-hat just tells you the direction of the force • When working with components, often helps to rewrite the r-hat • Sometimes this formula is written in terms of aquantity0 called the permittivity of free space

Concept Question • What is the direction of the force on the purple charge? • Up B) Down C) Left • D) Right E) None of the above +2.0 C 5.0 cm 5.0 cm –2.0 C 5.0 cm 7.2 N –2.0 C • The separation between the purple charge and each of the other charges is identical • The magnitude of those forces is identical 7.2 N • The blue charge creates a repulsive force at 45 down and left • The green charge creates an attractive force at 45 up and left • The sum of these two vectors points straight left

The Electric Field • Suppose we have some distribution of charges • We are about to put a small charge q0 at a point r • What will be the force on the charge at r? • Every term in the force is proportional to q0 • The answer will be proportional to q0 • Call the proportionality constant E, the electric field q0 r The units for electric field are N/C • It is assumed that the test charge q0is small enough that the other charges don’t move in response • The electric field E is a function of r, the position • It is a vector field, it has a direction in space everywhere • The electric field is assumed to exist even if there is no test charge q0 present

Electric Field From a Point Charge q q0 • From a single point charge, the electric field is easy to find • It points away from positive charges • It points towards negative charges - +

Electric Field from Two Charges • Electric field is a vector • We must add the vector components of the contributions of multiple charges + + + -

Electric Field Lines + • Electric field lines are a good way to visualize how electric fields work • They are continuous oriented lines showing the direction of the electric field • They never cross • Where they are close together, the field is strong • The bigger the charge, the more field lines come out • They start on positive charges and end on negative charges (or infinity) -

Gauss’s Law Electric Flux • Electric flux is the amount of electric field going across a surface • It is defined in terms of a direction, or normal unit vector,perpendicular to the surface • For a constant electric field, and a flat surface, it is easy to calculate • Denoted by E • Units of Nm2/C • When the surface is flat, and the fields are constant, youcan just use multiplication to get the flux • When the surface is curved, or the fields are not constant,you have to perform an integration

Electric Flux For a Cylinder A point charge q is at the center of a cylinder of radius a and height 2b. What is the electric flux out of (a) each end and (b) the lateral surface?  top s b b  r r z • Consider a ring of radius s and thickness ds a q b a lateral surface

Conductors and Gauss’s Law • Conductors are materials where charges are free to flow in response to electric forces • The charges flow until the electric field is neutralized in the conductor Inside a conductor, E = 0 • Draw any Gaussian surface inside the conductor In the interior of a conductor, there is no charge The charge all flows to the surface

Electric Field at Surface of a Conductor • Because charge accumulates on the surface of a conductor, there can be electric field just outside the conductor • Will be perpendicular to surface • We can calculate it from Gauss’s Law • Draw a small box that slightly penetrates the surface • The lateral sides are small and have no flux throughthem • The bottom side is inside the conductor and has no electric field • The top side has area A and has flux through it • The charge inside the box is due to the surface charge  • We can use Gauss’s Law to relate these

Sample problem An infinitely long hollow neutral conducting cylinder has inner radius a and outer radius b. Along its axis is an infinite line charge with linear charge density . Find the electric field everywhere. b end-on view perspective view a • Use cylindrical Gaussian surfaces when needed in each region • For the innermost region (r < a), the total charge comes entirely from the line charge • The computation is identical to before • For the region inside the conductor, the electric field is always zero • For the region outside the conductor (r > b), the electric field can be calculated like before • The conductor, since it is neutral, doesn’t contribute

Where does the charge go? + – + – – + + – – + – + – + – + + + + – – – – + – + – + How can the electric field appear, then disappear, then reappear? + • The positive charge at the center attracts negative charges from the conductor, which move towards it • This leaves behind positive charges, which repel each other and migrate to the surface end-on view • In general, a hollow conductor masks the distribution of the charge inside it, only remembering the total charge • Consider a sphere with an irregular cavity in it cutaway view q

Electric field Revisited

Electric field Revisited

Presentation Transcript

Electric Field

Electric Field

Electric Field

Electric Charge and Electric Field

Electric Field

Electric Field

Electric Force and Electric field

Electric Field

Electric Field

Electric Field

Electric Field

Electric field

Electric field

Electric Field

Electric Field

Electric Field

Electric Field

Electric field