1. Fall 2004 Charge ECE 2317: Applied Electricity and Magnetism Prof. Valery Kalatsky Dept. of Electrical & Computer Engineering University of Houston TitleTitle

2. HistoryHistory History Charge was discovered by the Ancient Greeks (about 600BC) who found that rubbing fur on various substances, such as amber, would build up an electric charge imbalance. The Greeks noted that the charged amber buttons could attract light objects such as hair. The Greeks also noted that if they rubbed the amber for long enough, they could even get a spark to jump. The word electricity derives from ηλεκτρον, the Greek word for amber.

3. More HistoryMore History More History Two glass rods rubbed with silk and placed near one another were observed to repel each other. On the other hand, if a resin (plastic) rod rubbed with fur is placed near one of the glass rods, the force was attractive. Benjamin Franklin (mid 1700’s) is credited with naming electrical charge; that appearing on the glass rod was designated positive and that on the resin (plastic) rod, negative.

4. Benjamin FranklinBenjamin Franklin Dr. Benjamin Franklin (January 17, 1706 — April 17, 1790) American journalist, publisher, author, philanthropist, abolitionist, public servant, scientist, diplomat, and inventor. One of the leaders of the American Revolution He was well known also for his many quotations and his experiments with electricity

5. Electric ChargeElectric Charge Electric Charge Plastic rubbed with fur becomes negatively charged, glass rubbed with silk becomes positively charged.

6. Electric ChargeElectric Charge The phenomena of two objects sticking together can be explained by the notion that objects when rubbed can gain a net electric charge. Electric Charge There are two types of charge, labeled positive ( + ) and negative ( - ), with the following basic property: Like charges of the same sign repel each other. Unlike charges of the opposite sign attract each other.

7. Electric ChargeElectric Charge Electric Charge Detailed experiments have established the following fundamental characteristics of electric charge: e = 1.602 x 10 -19 Coulombs (C) Charge is never created nor destroyed - it is conserved. This basic unit of charge is conventionally denoted by e : Charge always comes in an integral multiple of a basic unit - it is quantized. The charge is conventionally denoted by q or Q Electric Charge = Charge

8. AtomAtom proton: q = e = 1.602 x 10 -19 [C] electron: q = -e = -1.602 x 10 -19 [C] 1 [C] = 1 / 1.602 x10 -19 protons = 6.242 x 10 18 protons In an atom, the charge on an electron is - e and that on a proton is + e. Hydrogen Helium Atom 1 Coulomb is a HUGE charge

9. t 1) Volume charge density  v [C/m 3 ] vv VV uniform cloud of charge density QQ Charge Density: Volume VV QQ

10. t  v ( x,y,z ) dV non-uniform cloud of charge density dQ non-uniform (inhomogeneous) volume charge density Charge Density: Volume x, y, z – coordinates of the volume element

11. t Charge Density: Volume  v ( x,y,z ) dV dQ so or

12. t Charge Density: Surface 2) Surface charge density  s [C/m 2 ]  s ( x,y,z ) non-uniform sheet of charge density QQ SS non-uniform uniform

13. t Charge Density: Surface  s ( x,y,z ) dQ dS

14. t Charge Density: Line 3) Line charge density  l [C/m]  l ( x,y,z ) non-uniform line charge density QQ ll non-uniform uniform + + + + + + + +++ + + + +

15. t Charge Density: Line ++ +  l ( x,y,z ) QQ ll + + + + + + + + + + +

16. t x y z a  v = 10 [ C/m 3 ] Find: Q Example: Uniform Distribution

17. t z x y a  v = 2r [ C/m 3 ] Find: Q Example: Non-Uniform Distribution

18. tt z x y a  v = 3/r [ C/m 3 ] Quiz: Non-Uniform Distribution Find: Q

19. t