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Phy2005 Applied Physics II Spring 2016 Announcements: Solutions to chapter 20 problems posted on HW page. Answers to chapter 21 problems posted on HW page.

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Presentation on theme: "Phy2005 Applied Physics II Spring 2016 Announcements: Solutions to chapter 20 problems posted on HW page. Answers to chapter 21 problems posted on HW page."— Presentation transcript:

1 Phy2005 Applied Physics II Spring 2016 Announcements: Solutions to chapter 20 problems posted on HW page. Answers to chapter 21 problems posted on HW page Exam 1 Wednesday, Feb. 10 in class. 1 handwritten formula sheet ok

2 Science news page Crazy physicist Andreas Wahl – Stunt # 2 https://www.youtube.com/watch?v=tzm_yyl13yo

3 Last time: Resistors Parallel connection Series connection R1R1 R2R2 R3R3 R1R1 R2R2 R3R3 R eq = R 1 + R 2 + R 3 1/R eq = 1/R 1 +1/R 2 +1/R 3 Rules are “opposite” to those for capacitors! Today: Resistance vs resistivity, power Ohm’s law: V=IR V=Voltage across resistor I=current through resistor R=resistance of resistor

4 ACADEMIC HONESTY Each student is expected to hold himself/herself to a high standard of academic honesty. Under the UF academic honesty policy. Violations of this policy will be dealt with severely. There will be no warnings or exceptions.UF academic honesty policy

5 20-26 When a current of 3A flows through a 12-Ohm resistor, what is the potential difference between the ends of the resistor? 1. 36 V 2. 4 V 3. 0.25 V 4. 4 J 5. 0.25 J

6 We said some things conduct better than others. A measure of how well a given material conducts is its resistivity. Things with high resistivity conduct poorly. Things with low resistivity conduct well. Resistance, Resistivity & Ohm’s Law

7 A given device, like a resistor has a value of resistance R that depends on the resistivity  of the material it’s made out of, and its geometry. For a cylinder of cross- sectional area A and length L, Resistance, Resistivity & Ohm’s Law

8 A metal wire consists of “gas” of electrons at some temperature T. Even without net current, electrons move at typical speeds of 1/10 the speed of light. An electron moves at this high speed until it collides with something that changes its direction (ionic vibration, impurity, another electron). On the average in the absence of an electric field, the velocity is zero. Microscopic picture of conduction in wire Ions electrons

9 Ions Here’s what 1 electron does in a wire with no battery: Microscopic picture of conduction in wire

10 Ions Here’s what 1 electron does in a wire with no battery: Microscopic picture of conduction in wire

11 Ions Here’s what 1 electron does in a wire with no battery: Microscopic picture of conduction in wire

12 Ions Here’s what 1 electron does in a wire with no battery: Microscopic picture of conduction in wire

13 Ions Here’s what 1 electron does in a wire with no battery: Microscopic picture of conduction in wire

14 Ions Here’s what 1 electron does in a wire with no battery: Microscopic picture of conduction in wire

15 Ions Here’s what 1 electron does in a wire with no battery: No net progress “downstream”! Microscopic picture of conduction in wire

16 If we apply an electric field, the electrons “drift downstream” on the average. Ions electrons E Q: Why don’t they keep accelerating due to electric force? Microscopic picture of conduction in wire

17 If we apply an electric field, the electrons “drift downstream” on the average. Ions electrons E Q: Why don’t they keep accelerating due to electric force? A: Collisions! Microscopic picture of conduction in wire

18 Ions Here’s what 1 electron does in a wire with a battery: E Microscopic picture of conduction in wire

19 Ions Here’s what 1 electron does in a wire with a battery: E Microscopic picture of conduction in wire

20 Ions Here’s what 1 electron does in a wire with a battery: E Microscopic picture of conduction in wire

21 Ions Here’s what 1 electron does in a wire with a battery: E Microscopic picture of conduction in wire

22 Ions Here’s what 1 electron does in a wire with a battery: In presence of electric field, the electrons “drift downstream” on the average. Net average velocity only 1cm/s or less! E Microscopic picture of conduction in wire

23 1. Average speed of electrons in wire: about c/10: 2. Drift velocity of electrons: very slow, less than 1 cm/sec. This velocity corresponds to the current we calculate. 3. Velocity of information, energy flow. Close to c. Summary: three important speeds where c = speed of light = 3 x 10 8 m/s

24 ! Power ! Power = work/time E +q F = qE d V=0V=Ed time  t Work done to move charge is qV in time  t So power supplied is qV/  t = IV P=IV

25 Q. A 40 W/120 V light bulb produces 40 W of power when connected to 120 V. How much power would be produced if the same bulb is connected to 60 V? You can solve this problem by calculating R of the filament and use the formula for power, P = IV = V 2 /R, and R is fixed. P (for 120 V) = 40 (W), p (for 60 V) = 40*(60/120) 2 = 10 (W)

26 A certain 1400 W space heater is designed to operate on 120 V. How much current flows through it when it is operating? What is its resistance when operating? Power = IV = I 2 R = V 2 /R Since we know P and V, use P = IV to calculate I. I = P/V = (1400 W)/(120 V) = 11.7 A Now, we can use Ohm’s law to calculate R. When it is operating on 120 V, 11.7 A current flows. R = V/I = (120 V)/(11.7 A) = 10.25  Statement: P = IV If I hook up this heater on 60 V, the power Produced by this heater would drop to ½. No!

27

28 ACADEMIC HONESTY Each student is expected to hold himself/herself to a high standard of academic honesty. Under the UF academic honesty policy. Violations of this policy will be dealt with severely. There will be no warnings or exceptions.UF academic honesty policy

29

30 If the four light bulbs in the figure are identical, which circuit puts out more light? 1. I 2. II 3. Same for both 4. Need to know R

31 r r r/2 2r P = V 2 /R PI = V 2 /(r/2) = 2V 2 /r PII = V 2 /(2r) = V 2 /(2r) = (1/4)PI

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