Circuits

PHY2049: Chapter 27. 9. Series Circuit. →Simple series situation. ◇1 battery and two resistors R. 1 and R. 2. ◇Common current I. →Total voltage E = V...

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Circuits

PHY2049: Chapter 27

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What You Already Know ÎNature

of current

ÎCurrent ÎDrift

density

speed and current

ÎOhm’s

law

ÎConductivity ÎCalculating ÎPower

and resistivity

resistance from resistivity

in electric circuits

PHY2049: Chapter 27

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Chapter 27: Electric Circuits ÎWork,

energy and EMF

ÎSingle

loop circuits

ÎMultiloop

circuits

ÎAmmeters ÎRC

and voltmeters

circuits and time constant

PHY2049: Chapter 27

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Reading Quiz for Chapter 27 ÎThe

electric current is defined as:

‹ (1)

amount of charge per time ‹ (2) amount of charge per area ‹ (3) amount of charge per volume ÎWhen

resistors are connected in series

‹ (1)

the current in each resistor is different ‹ (2) the current in each resistor is the same ‹ (3) the voltage in each resistor is the same ÎWhich

of the following is not related to Kirchhoff’s Rules?

‹ (1)

conservation of charge ‹ (2) conservation of energy ‹ (3) conservation of momentum

PHY2049: Chapter 27

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EMF ÎEMF

device performs work on charge carriers

‹ Converts

energy to electrical energy ‹ Moves carriers from low potential to high potential ‹ Maintains potential across terminals ÎVarious

types of EMF devices

‹ Battery ‹ Generator ‹ Fuel

cell ‹ Solar cell ‹ Thermopile ÎExample:

Electrolytic reaction Magnetic field Oxidation of fuel Electromagnetic energy Nuclear decay

battery

‹ Two

electrodes (different metals) ‹ Immersed in electrolyte (dilute acid) ‹ One electrode develops + charge, the other – charge PHY2049: Chapter 27

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Common dry cell battery

PHY2049: Chapter 27

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Electrons in the wire ÎIf

the electrons move so slowly through the wire, why does the light go on right away when we flip a switch? ‹ Household

wires have almost no resistance ‹ The electric field inside the wire travels much faster ‹ Light switches do not involve currents ‹ None of the above

PHY2049: Chapter 27

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Electrons in the wire, part 2 ÎOkay,

so the electric field in a wire travels quickly. But, didn’t we just learn that E = 0 inside a conductor? ‹ True,

it can’t be the electric field after all!! ‹ The electric field travels along the outside of the conductor ‹ E = 0 inside the conductor applies only to static charges ‹ None of the above

PHY2049: Chapter 27

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Series Circuit ÎSimple

series situation

‹1

battery and two resistors R1 and R2 ‹ Common current I ÎTotal

voltage E = V1 + V2

= IR1 + IR2 ≡ IRs ‹ Rs = R1 + R2 ‹E

ÎSo

equivalent resistance is the sum

‹ Works

for any number of resistors ‹ Rs = R1 + R2 + R3 + R4 + …

PHY2049: Chapter 27

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Resistors in series ÎEMF

of battery is 12 V, 3 identical resistors. What is the potential difference across each resistor? ‹ 12

V ‹0 V ‹3 V ‹4 V

Current is the same, so voltage across each is the same

R

PHY2049: Chapter 27

R

R

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Resistors in series ÎIf

the light bulbs are all the same in each of these two circuits, which circuit has the higher current? ‹ circuit

A ‹ circuit B ‹ both the same ÎIn

which case is each light bulb brighter?

‹ circuit

A ‹ circuit B ‹ both the same

A

B PHY2049: Chapter 27

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Real EMF Sources: Internal Resistance batteries have small internal resistance

‹ Lowers

i=

effective potential delivered to circuit

E r+R

Vb

r

Veff = Vb − Va = E − ir

Va

R

E =E− r r+R

C

Veff

C

ÎReal

E = 1+ r / R

This is the voltage measured across the terminals! PHY2049: Chapter 27

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Internal Resistance Example ÎLoss

ÎE

of voltage is highly dependent on load E 12 Veff = = 1 + r / R 1 + 0.1/ R

= 12V, r = 0.1Ω, R = 100Ω

‹ Loss

ÎE ÎE

Veff = 12 /1.1 = 10.9V

of 1.1V

= 12V, r = 0.1Ω, R = 0.5Ω

‹ Loss

Veff = 12 /1.01 = 11.9V

of 0.1V

= 12V, r = 0.1Ω, R = 1Ω

‹ Loss

ÎE

of 0.01V

= 12V, r = 0.1Ω, R = 10Ω

‹ Loss

Veff = 12 /1.001 = 11.99V

Veff = 12 /1.2 = 10.01V

of 2.0V PHY2049: Chapter 27

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Heating From Internal Resistance ÎHeating

of EMF source: P = i2r

‹ Heating

ÎE

is extremely dependent on load

= 12V, r = 0.1Ω

‹R

= ‹R = ‹R = ‹R =

100Ω 10Ω 1.0Ω 0.5Ω

Vba Vba Vba Vba

= = = =

11.99V 11.9V 10.9V 10.0V

I I I I

= = = =

0.12 A 1.19 A 10.9 A 20 A

P P P P

= = = =

0.0014 W 0.14 W 11.9 W 40 W

2

14.4 ⎛ E ⎞ P=i r =⎜ ⎟ r = 2 r R + ⎝ ⎠ ( R + 0.1) 2

PHY2049: Chapter 27

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Resistors in Parallel Î Current

splits into several branches. Total current is conserved ‹

I = I1 + I2

Î Potential

resistor ‹

difference is same across each

V = V1 = V2

a

I

V d

V V V = + R p R1 R2

a

Rp = equivalent resistance. Works for any number of resistors PHY2049: Chapter 27

I2

R1

R2

I I I

V

1 1 1 = + R p R1 R2

I1

Rp d

I

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Resistors in Parallel ÎAs

more resistors R are added in parallel to the circuit, how does total resistance between points P and Q change? ‹ (a)

increases ‹ (b) remains the same ‹ (c) decreases

ÎIf

the voltage between P & Q is held constant, and more resistors are added, what happens to the current through each resistor? ‹ (a)

increases ‹ (b) remains the same ‹ (c) decreases

Overall current increases, but current through each branch is still V/R. PHY2049: Chapter 27

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Resistance Example ÎFind

net resistance of the circuit connected to the battery. Each resistance has R = 3 kΩ

PHY2049: Chapter 27

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Resistance Example (1+2) ÎCombine ‹ R12

#1 & #2 in series

= 6 kΩ

PHY2049: Chapter 27

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Resistance Example (1+2+3) ÎCombine ‹ R123

6kΩ & #3 in parallel

= 2 kΩ

PHY2049: Chapter 27

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Resistance Example (1+2+3+4) ÎCombine ‹ R1234

2kΩ & #4 in series

= 5 kΩ

B

A

A

C

PHY2049: Chapter 27

C

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Resistance Example (1+2+3+4+5) ÎCombine ‹ R12345

5kΩ & #5 in parallel

= 1.875 kΩ

A A

C

C

PHY2049: Chapter 27

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Resistance Example (1+2+3+4+5+6) ÎCombine ‹ R123456

A

1.875kΩ & #6 in series

= 4.875 kΩ

C

PHY2049: Chapter 27

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Circuits ÎIf

the light bulbs are all the same in each of these two circuits, which circuit has the higher current? ‹ (a)

circuit A ‹ (b) circuit B ‹ (c) both the same B draws twice the current as A ÎIn

which case is each light bulb brighter?

A

‹ (a)

circuit A ‹ (b) circuit B ‹ (c) both the same Current through each branch is unchanged (V/R)

B PHY2049: Chapter 27

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Light Bulb Problem ÎTwo

light bulbs operate at 120 V, one with a power rating of 25W and the other with a power rating of 100W. Which one has the greater resistance? ‹ (a)

the one with 25 W ‹ (b) the one with 100 W ‹ (c) both have the same resistance

ÎWhich

carries the greater current?

‹ (a)

the one with 25 W ‹ (b) the one with 100 W ‹ (c) both have the same current

P = I2R = V2/R, so 100W bulb has ¼ the resistance of the 25W bulb and carries 4x the current.

PHY2049: Chapter 27

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Dimmer ÎWhen

you rotate the knob of a light dimmer, what is being changed in the electric circuit? ‹ (a) ‹ (b) ‹ (c) ‹ (d) ‹ (e)

the voltage the resistance the current both (a) and (b) both (b) and (c)

House voltage is always 110 – 120V. Turning the knob increases the circuit resistance and thus lowers the current.

PHY2049: Chapter 27

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Power lines ÎAt

large distances, the resistance of power lines becomes significant. To transmit maximum power, is it better to transmit high V, low I or high I, low V? ‹ (a)

high V, low I ‹ (b) low V, high I ‹ (c) makes no difference

ÎWhy

Power loss is I2R, so want to minimize current.

do birds sitting on a high-voltage power line survive?

‹ They

are not touching high and low potential simultaneously to form a circuit that can conduct current

PHY2049: Chapter 27

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Household Circuits Î All

devices are added in parallel.

Î Overload:

too many devices that require a lot of current can draw more current than wires can handle. Overheating of wires ‹ Fire hazard! ‹

PHY2049: Chapter 27

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Resistors ÎCurrent

flows through a light bulb. If a wire is now connected across the bulb as shown, what happens? ‹ (a)

All the current continues to flow through the bulb ‹ (b) Current splits 50-50 into wire and bulb ‹ (c) Almost all the current flows through the wire ‹ (d) None of the above Current is maintained by external voltage source. The wire “shunt” has almost no resistance and it is in parallel with a bulb having resistance. Therefore all the current follows the zero (or extremely low) resistance path.

PHY2049: Chapter 27

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Circuits ÎTwo

light bulbs A and B are connected in series to a constant voltage source. When a wire is connected across B, what will happen to bulb A? ‹ (a)

burns more brightly than before ‹ (b) burns as brightly as before ‹ (c) burns more dimly than before ‹ (d) goes out The wire shunt effectively eliminates the second resistance, hence increasing the current in the circuit by 2x. The first bulb burns 4x brighter (I2 R).

PHY2049: Chapter 27

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Circuits ÎConsider

the network of resistors shown below. When the switch S is closed, then: ‹ What

happens to the voltage across R1, R2, R3, R4? ‹ What happens to the current through R1, R2, R3, R4? ‹ What happens to the total power output of the battery? ‹ Let R1 = R2 = R3 = R4 = 90 Ω and V = 45 V. Find the current through each resistor before and after closing the switch. Before ¾I1 = 45/135 = 1/3 ¾I2 = 0 ¾I3 = I4 = 15/90=1/6 After ¾I1 = 45/120 = 3/8 ¾I2 = I3 = I4 = 1/8 PHY2049: Chapter 27

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