Alternating Current

Question 1

Uses of Alternating Current

Answer 1

• over 99% of electrical energy used worldwide is produced by generators in the form of alternating current
• can be used to transport electricity at very high voltages (~400kV UK national grid) and therefore low currents reducing energy loss by heating
• these high voltages are then transformed to lower voltages with almost no energy loss for home usage (UK 240V)

Question 2

AC Generator

Answer 2

-consists of a coil of area A with N turns rotating in a uniform magnetic field B
-the magentic flux Φb is given by:
Φb = N ∫ |B . ^n dA => Φb = NBA cosθ
-let the coil rotate with constant angular speed ω:
θ = ωt + 𝛿 , where delta is an arbitrary phase angle
-we can calculate emf generated across the terminals using Faraday’s Law:
ε = - dΦb/dt = - dBNAcos(ωt + 𝛿)/dt
= NBAωsin(ωt + 𝛿) = εmax * sin(ωt + 𝛿)

Question 3

Ohm’s Law

Answer 3

V = IR

Question 4

Current Flow

Description

Answer 4

• current in a conductor is driven by an electric field inside the conductor
• the electric field exerts a force on the charges within the material and the free charges then move and carry the current I
• as there is current flowing, the conductor is not in electrostatic equilibrium
• as there is an electric field across the conductor there is a change of electric potential ΔV across the material (written as V for neatness)

Question 5

Resistors

Description

Answer 5

• conductors with resistance R

- treated as perfect ohmic materials

Question 6

Capacitors

Solid Spherical Conductor - Capacitance

Answer 6

-by Gauss’s law, electric potential:
V = Q / 4πεoR
-rearrange for capacitance:
Q/V = 4πεoR = C

Question 7

Capacitors

Description

Answer 7

• C is the capacitance and it is a measure of the capacity to store charge for a given potential difference
• units are Farads (F)
• a capacitor is a system of two conductors carrying equal but opposite charge Q

Question 8

Capacitors

Parallel Plate Capacitors - Capacitance

Answer 8

-using Gauss’s Law:
V = Ed = σ/εo * d = Qd/Aεo
Q/V = Aεo/d = C

Question 9

Capacitors

Parallel Plate Capacitors - Energy Stored

Answer 9

-work, W, has to be done to charge a capacitor and this goes into increasing the potential energy, U, of the capacitor
-consider a parallel plate capacitor with stored charge q and potential difference V across the plates
-move a small amount of charge dq from the negative plate to the positive plate:
dW = dU = Vdq
-since q = CV:
dU = q/C dq
-integrate
U = ∫ dU = ∫ q/C dq = 1/2 * Q²/C = 1/2 QV = 1/2 CV²

Question 10

Where is the potential energy of a capacitor stored?

Answer 10

• when a capacitor is charged, an electric field is created between the two plates
• electromagnetic waves are just electric and magnetic fields and they transport energy
• this suggests that the energy in a capacitor is stored in its electric field

Question 11

Capacitors

Parallel Plate Capacitors - Energy Desity

Answer 11

-starting from potential energy U:
U = 1/2 CV²
-sub in for C = εoA/d : 
U = 1/2 εoA/d V² 
-sub in for V=Ed :
U =  1/2 εoA/d (Ed)²
-for energy density, divide by volume which is Ad between the two plates
ue = 1/2 εoA/d (Ed)² 1/Ad
-simplify
ue = 1/2 εo E²

Question 12

Capacitors

Solid Spherical Conductor - Energy Stored

Answer 12

-start with electric field:
E = Q / 4πεor²
-from this electric potential is given by:
ΔV = - ∫ |E . d|l
-calculate the work done taking a small charge dq from infinity and adding it to the sphere which is currently at charge q:
dW = dU = dq ΔV = dq * q/4πεoR
-integrate between final total charge Q and 0
U = ∫ dq * q/4πεoR = 1/2 Q²/4πεoR

Question 13

Capacitors

Solid Spherical Conductor - Energy Density

Answer 13

-take the expression for energy density for a parallel plate capacitor:
u = 1/2 εo E²
-consider a shell of thickness dr, a distance r from the centre of a solid sphere, the volume dV is given by:
dV = 4πr²dr
-using u for a parallel plate capacitor, dU stored in that volume is;
dU = u dV = u 4πr²dr = 1/2 εo E² * 4πr²dr
-sub in E = Q / 4πεor² and simplify:
dU = 1/2 εo (Q/4πεor²)² * 4πr²dr
dU = 1/2 Q²/4πεor² dr
-integrate over all space, i.e. from infinity to the edge of the sphere at r=R
U = ∫ 1/2 Q²/4πεor² dr = 1/2 Q²/4πεoR
-this matches the direct derivation of potential energy of a solid conducting sphere, therefore the energy density of electric field equation is general

Question 14

Transient Current

Definition

Answer 14

• a current that changes over time before a steady state is reached is termed a transient current
• e.g. a transient flows after a switch that completes a circuit is closed

Question 15

RC Circuit

Description

Answer 15

-consider a capacitor with capacitance C in a circuit with a resistor of resistance R, a battery with emf ε and a switch S

Question 16

Solenoid - Self Inductance

Answer 16

-consider a solenoid of n turns per unit length carrying current I
-the current produces a magnetic field B inside the coil given by Ampere’s Law:
B = μo n I = μo (N/l) I
-magnetic flux through the coil:
Φ = NBA = N( μo (N/l) I )A
-multiply by length l to simplify;
Φ = N( μo (N/l²)AI l = (μon²lA)I
-the flux is proportional to current I, so we can write
Φ = LI
-where L = μon²lA is the self inductance of the coil

Question 17

Self Inductance

Answer 17

L = Φ/I

• a constant of proportionality, where L = μon²lA
• units are the henry (H) where H=Tm²/A

Question 18

Inductor

Description

Answer 18

-in a circuit we can add a component with inductance L. this component is called an inductor
-Faraday’s Law gives
ε = - dΦ/dt = -dLI/dt = -L dI/dt
-when the current through in an inductor changes the magnetic flux through the inductor changes which induces an emf in the inductor that opposes the change (Lenz’s Law)

Question 19

Mutual Inductance

Answer 19

-when two circuits are close to each other, the magnetic flux through one circuit depends on the current in both circuits and we can define a mutual inductance M such that
Φb,1 = L1I1 + MI2

Question 20

RL Circuit

Description

Answer 20

• resistor of resistance R and inductor of inductance L connected to a battery ε
• at time t=0 the switch is closed, on closing a current I will start to flow
• if I and dI/dt are positive then current increases in the direction of I
• a changing current in the inductor will induce an emf of magnitude L dI/dt that acts to oppose the change
• hence a positive dI/dt will induce an emf that tries o drive a current in the negative sense, so there will be a voltage drop across the inductor
• there is also a potential drop across the resistor of -IR:

Question 21

RL Circuit

Power Equation

Answer 21

-starting with Kirchoff's Loop rule:
ε - IR - L dI/dt = 0
-multiply each term by I and rearrange:
Iε = I²R + IL dI/dt
power output of battery = power dissipated as heat in the resistor + power into inductor

Question 22

Inductor - Work Done

Answer 22

-to calculate the total work done W in setting up a current I flowing in the conductor start with power:
P = IL dI/dt
-since P=dW/dt, rearrange for dW:
dW = I (LdI)
-integrate between final current I and 0 for total work done
W = 1/2 LI²
-this energy must be stored in the magnetic field generated by the inductor

Question 23

Inductor - Energy Density

Answer 23

-work done equals potential energy stored
U = W = 1/2 LI²
-sub in L = μon²lA :
U = 1/2 μon²lA I²
-since B = μo n I, sub in I = B/nμo
U = 1/2 μon²lA (B/nμo)²
-divide by the volume within a solenoid, V=Al to get energy density
um = U/lA = 1/2 μon² (B/nμo)² = 1/2 1/μo B²

Question 24

Is energy stored in an inductor?

Answer 24

-it is easy to see that energy is stored in a capacitor since you can connect a charged capacitor to a circuit and it will power a current
-imagine a RL circuit with a switch positioned such that it is possible to bypass the battery
-move the switch so that it disconnects the battery from the inductor
ε - IR - L dI/dt = 0 becomes 0 - IR - L dI/dt = 0
-multiply by I and rearrange:
-LI dI/dt = I²R
power lost by inductor = power used to heat resistor
-this is true for all t so every joule lost by the inductor goes to doing something, in this case, heating the resistor
-without the inductor we could not have retrieved this energy and the difference between the inductor and the resistor is the magnetic field

Question 25

Capacitor Energy Density - General Result?

Answer 25

ue = 1/2 εo E²

-does turn out to be a general result

Question 26

RC Circuit

Kirchoff’s Loop Rule

Answer 26

-at t=0 the switch is closed
-you can calculate I as a function of t by using Kirchhoff’s Loop Rule:
ε - Vr - Vc = 0
-where Vr is the potential drop across the resistor and Vc the drop across the capacitor
-sub in expressions fro Vr and Vc:
ε - IR - Q/C = o
ε - dQ/dt R - Q/C
-this is a first order differential equation that can be solved for Q:
Q = Cε (1 - e^(-t/RC))

Question 27

RC Circuit

Q and I as functions of time

Answer 27

-Kirchoff’s loop rule produces a differential equation that can be solved for Q:
Q = Cε (1 - e^(-t/RC))
-sub into I = dQ/dt
I = ε/R * e^(-t/RC)

Question 28

RL Circuit

Kirchoff’s Loop Rule

Answer 28

ε - Vr - εL = 0
ε - IR - L dI/dt = 0
-solve for I
I = ε/R [1 - e^(-tR/L)]