Electrical energy & Capacitance

Transcription

1 Electrical energy & Capacitance PHY232 Remco Zegers Room W109 cyclotron building

2 work previously A force is conservative if the work done on an object when moving from A to B does not depend on the path followed. Consequently, work was defined as: W=PE i -PE f =-ΔPE this was derived for a gravitational force, but as we saw in the previous chapter, gravitational and Coulomb forces are very similar: F g =Gm 1 m 2 /r 122 with G=6.67x10-11 Nm 2 /kg 2 F e =k e q 1 q 2 /r 122 with k e =8.99x10 9 Nm 2 /C 2 Hence: The Coulomb force is a conservative force PHY232 - Remco Zegers - Electrical Energy & Capacitance 2

3 work & potential energy consider a charge +q moving in an E field from A to B over a distance D. We can ignore gravity (why?) What is the work done by the field? What is the change in PE? If initially at rest, what is its speed at B? E W AB =Fdcosθ with θ the angle between F and direction of movement, so W AB =Fd W AB =qed (since F=qE) work done BY the field ON the charge (W is positive) ΔPE=-W AB =-qed : negative, so the potential energy has decreased Conservation of energy: ΔPE+ΔKE=0 ΔKE=1/2m(v f2 -v i2 ) 1/2mv f2 =qed v= (2qEd/m) PHY232 - Remco Zegers - Electrical Energy & Capacitance 3

4 work & potential energy II Consider the same situation for a charge of q. Can it move from A to B without an external force being applied, assuming the charge is initially (A) and finally (B) at rest? W AB =-qed ; negative, so work must be done by the charge. This can only happen if an external force is applied Note: if the charge had an initial velocity the energy could come from the kinetic energy (I.e. it would slow down) If the charge is at rest at A and B: external work done: -qed If the charge has final velocity v then external work done: W=1/2mv f2 + q Ed PHY232 - Remco Zegers - Electrical Energy & Capacitance 4

5 Conclusion In the absence of external forces, a positive charge placed in an electric field will move along the field lines (from + to -) to reduce the potential energy In the absence of external forces, a negative charge placed in an electric field will move along the field lines (from - to +) to reduce the potential energy PHY232 - Remco Zegers - Electrical Energy & Capacitance 5

6 question P Q a positive charge initially at rest at P moves to Q. Will it follow the shortest route (as indicated by the dashed arrow) a) yes b) no Will the change in potential energy of the charge at Q be different depending on which path is taken from P to Q? a) yes b) no c) depends on whether the velocity of the charge at Q is different depending on the path d) depends on the external forces applied PHY232 - Remco Zegers - Electrical Energy & Capacitance 6

7 question 2m Y 1m X a negatively charged (-1 μc) mass of 1 g is shot diagonally in an electric field created by a negatively charge plate (E=100 N/C). It starts at 2 m distance from the plate and stops 1 m from the plate, before turning back. What was the initial velocity in the direction along the field lines? PHY232 - Remco Zegers - Electrical Energy & Capacitance 7

8 answer PHY232 - Remco Zegers - Electrical Energy & Capacitance 8

9 Electrical potential The change in electrical potential energy of a particle of charge Q in a field with strength E over a distance d depends on the charge of the particle: ΔPE=-QEd For convenience, it is useful to define the difference in electrical potential between two points (ΔV), that is independent of the charge that is moving: ΔV= ΔPE/Q=- E d The electrical potential difference has units [J/C] which is usually referred to as Volt ([V]). It is a scalar (just a number) Since ΔV= -Ed, so E= -ΔV/d the units of E ([N/C] before) can also be given as [V/m]. They are equivalent, but [V/m] is more often used. PHY232 - Remco Zegers - Electrical Energy & Capacitance 9

10 Electric potential due to a single charge V V=k e q/r + r 1C the potential at a distance r away from a charge +q is the work done in bringing a charge of 1 C from infinity (V=0) to the point r: V=k e q/r If the charge that is creating the potential is negative (-q) then V=k e q/r If the field is created by more than one charge, then the superposition principle can be used to calculate the potential at any point PHY232 - Remco Zegers - Electrical Energy & Capacitance 10

11 example m +1C -2 C r a) what is the electric field at a distance r? b) what is the electric potential at a distance r? PHY232 - Remco Zegers - Electrical Energy & Capacitance 11

12 question a proton is moving in the direction of the electric field. During this process, the potential energy and its electric potential a) increases, decreases b) decreases, increases c) increases, increases d) decreases, decreases PHY232 - Remco Zegers - Electrical Energy & Capacitance 12

13 example a particle (q 1 ) with a charge of +4.5μC is fixed in space. From a distance of 3.70 cm, a particle (q 2 ) of mass 6.9 g and charge 3.10 μc is fired with initial velocity of 60 m/s towards to fixed charge. What is its velocity when it is 1 cm away from q 1? PHY232 - Remco Zegers - Electrical Energy & Capacitance 13

14 +1 +1 A -2 question 1) the electric potential at A is a) zero b) non-zero 2) the electric field at A is a) zero b) non-zero 3) a + particle at A would a) move b) not move B ) the electric potential at B is a) zero b) non-zero 2) the electric field at B is a) zero b) non-zero 3) a + particle at B would a) move b) not move PHY232 - Remco Zegers - Electrical Energy & Capacitance 14

15 loncapa do problems 1 (partially material from previous chapter) 2,3,4,5,6,7,8,12 from set 2 PHY232 - Remco Zegers - Electrical Energy & Capacitance 15

16 equipotential surfaces compare with a map PHY232 - Remco Zegers - Electrical Energy & Capacitance 16

17 Q A capacitor d symbol for capacitor when used in electric circuit Q is a device to create a constant electric field. The potential difference V=Ed is a device to store charge (+ and -) in electrical circuits. the charge stored Q is proportional to the potential difference V: Q=CV C is the capacitance, units C/V or Farad (F) very often C is given in terms of μf (10-6 F), nf (10-9 F) pf (10-12 F) Other shapes exist, but for a parallel plate capacitor: C=ε 0 A/d where ε 0 =8.85x10-12 F/m and A the area of the plates PHY232 - Remco Zegers - Electrical Energy & Capacitance 17

18 electric circuits: batteries The battery does work (e.g. using chemical energy) to move positive charge from the terminal to the + terminal. Chemical energy is transformed into electrical potential energy. Once at the + terminal, the charge can move through an external circuit to do work transforming electrical potential energy into other forms Symbol used in electric circuits: + - PHY232 - Remco Zegers - Electrical Energy & Capacitance 18

19 Our first circuit 10nF 12V The battery will transport charge from one plate to the other until the voltage produced by the charge build-up is equal to the battery charge example: a 12V battery is connected to a capacitor of 10 nf. How much charge is stored? answer Q=CV=10x10-9 x 12V=120 nc if the battery is replaced by a 300 V battery, and the capacitor is 2000μF, how much charge is stored? answer Q=CV=2000x10-6 x 300V=0.6C We will see later that this corresponds to 0.5CV 2 =90 J of energy, which is the same as a 1 kg ball moving at a velocity of 13.4 m/s PHY232 - Remco Zegers - Electrical Energy & Capacitance 19

20 capacitors in parallel A C 1 =10nF C 2 =10nF B At the points the potential is fixed to one value, say 12V at A and 0 V at B 12V This means that if the capacitances C 1 and C 2 are equal they must have the same charge stored and the total charge stored is Q=Q 1 +Q 2. We can replace C 1 and C 2 with one equivalent capacitor: Q 1 =C 1 V & Q 2 =C 2 V is replaced by: Q=C eq V since Q=Q 1 +Q 2, C 1 V+C 2 V=C eq V so: C eq =C 1 +C 2 This holds for any combination of parallel placed capacitances C eq =C 1 +C 2 +C 3 + The equivalent capacitance is larger than each of the components PHY232 - Remco Zegers - Electrical Energy & Capacitance 20

21 A C 1 =10nF 12V C 2 =10nF capacitors in series B The voltage drop of 12V is over both capacitors. V=V 1 +V 2 The two plates enclosed in are not connected to the battery and must be neutral on average. Therefore the charge stored in C 1 and C 2 are the same we can again replace C 1 and C 2 with one equivalent capacitor but now we start from: V=V 1 +V 2 so, V=Q/C 1 +Q/C 2 =Q/C eq and thus: 1/C eq =1/C 1 + 1/C 2 This holds for any combination of in series placed capacitances 1/C eq =1/C 1 +1/C 2 +1/C 3 + The equivalent capacitor is smaller than each of the components PHY232 - Remco Zegers - Electrical Energy & Capacitance 21

22 question Given three capacitors of 1 nf, an capacitor can be constructed that has minimally a capacitance of: a) 1/3 nf b) 1 nf c) 1.5 nf d) 3 nf PHY232 - Remco Zegers - Electrical Energy & Capacitance 22

23 a more general case: what is the equivalent C C 3 C 4 C 5 C 6 STRATEGY: replace subgroups of capacitors, starting at the smallest level and slowly building up. C 1 C 2 12V step 1: C 4 and C 5 and C 6 are in parallel. They can be replaced by once equivalent C 456 =C 4 +C 5 +C 6 PHY232 - Remco Zegers - Electrical Energy & Capacitance 23

24 step II C 3 C 456 C 1 C 2 12V C 3 and C 456 are in series. Replace with equivalent C: 1/C 3456 =1/C 3 +1/C 456 so C 3456 =C 3 C 456 /(C 3 +C 456 ) C 1 and C 2 are in series. Replace with equivalent C: 1/C 12 =1/C 1 +1/C 2 so C 12 =C 1 C 2 /(C 1 +C 2 ) PHY232 - Remco Zegers - Electrical Energy & Capacitance 24

25 step III C 3456 C 12 C V 12V C 12 and C 3456 are in parallel, replace by equivalent C of C =C 12 +C 3456 PHY232 - Remco Zegers - Electrical Energy & Capacitance 25

26 problem C 4 C 3 A C 5 B C 1 =10nF C 2 =20nF C 1 C 2 C 3 =10nF C 4 =10nF C 5 =20nF What is V ab? 12V PHY232 - Remco Zegers - Electrical Energy & Capacitance 26

27 energy stored in a capacitor Q V V Q the work done transferring a small amount ΔQ from to + takes an amount of work equal to ΔW=VΔQ At the same time, V is increased, since V=(Q+ΔQ/C) The total work done when moving charge Q starting at V=0 equals: W=1/2QV=1/2(CV)V=1/2CV 2 Therefore, the amount of energy stored in a capacitor equals: E C =1/2CV 2 ΔQ Q PHY232 - Remco Zegers - Electrical Energy & Capacitance 27

28 example A parallel-plate capacitor is constructed with plate area of 0.40 m 2 and a plate separation of 0.1mm. How much energy is stored when it is charged to a potential difference of 12V? PHY232 - Remco Zegers - Electrical Energy & Capacitance 28

29 Q Q capacitors II d A material κ vacuum air glass 5.6 paper 3.7 water 80 the charge density of one of the plates is defined as: σ=q/a The equation C=ε 0 A/d assumes the area between the plates is in vacuum (free space) If the space is replaced by an insulating material, the constant ε 0 must be replaced by κε 0 where κ (kappa) is the dielectric constant for that material, relative to vacuum Therefore: C=κε 0 A/d PHY232 - Remco Zegers - Electrical Energy & Capacitance 29

30 why does inserting a plate matter? molecules, such as water, can/is be polarized when placed in an E-field, the orient themselves along the field lines; the negative plates attracts the positive side of the molecules near to positive plate, net negative charge is collected; near the negative plate, net positive charge is collected. If no battery is connected, the initial potential difference V between the plates will drop to V/κ. If a battery was connected, more charge can be added, increasing the capacitance from C to Cκ PHY232 - Remco Zegers - Electrical Energy & Capacitance 30

31 problem An amount of 10 J is stored in a parallel plate capacitor with C=10nF. Then the plates are disconnected from the battery and a plate of material is inserted between the plates. A voltage drop of 1000 V is recorded. What is the dielectric constant of the material? PHY232 - Remco Zegers - Electrical Energy & Capacitance 31

32 problem An ideal parallel plate capacitor is connected to a battery and becomes fully charged. The capacitor is then disconnected and the separation between the plates is increased in such a way that no charge leaks off. The energy stored in the capacitor has a) increased b) decreased c) not changed d) become zero PHY232 - Remco Zegers - Electrical Energy & Capacitance 32

33 Remember Electric force acting on object 1 (or 2): F=k e q 1 q 2 /r 12 2 Electric field due to object 1 at a distance r: E=k e q 1 /r 2 Electric potential at a distance r away from a charge q 1 : V=k e q 1 /r PHY232 - Remco Zegers - Electrical Energy & Capacitance 33

34 loncapa do problems 9,10,11,13,14,15 from set 2 PHY232 - Remco Zegers - Electrical Energy & Capacitance 34