Presentation is loading. Please wait.

Presentation is loading. Please wait.

Potential Difference and Capacitance Consider a rock dropped in a grav. field: Work is done by gravity To lift the object, Work is done to give the rock.

Published byCrystal Mathews Modified over 8 years ago

Similar presentations

Presentation on theme: "Potential Difference and Capacitance Consider a rock dropped in a grav. field: Work is done by gravity To lift the object, Work is done to give the rock."— Presentation transcript:

1

2 Potential Difference and Capacitance Consider a rock dropped in a grav. field: Work is done by gravity To lift the object, Work is done to give the rock PE! High PE Low PE A test charge in an elect. Field: + + + + + + + + + + + + + – – – – – – q q Work is done by the electric field -- a difference in PE exists

3 Potential Difference [electric potential] (V): Work done in moving a charge across an electric field per unit of charge. ≈ Similar (but not exactly) to PE is Work done in moving an object up through a gravitational field V = W q Units: volt (v) = J/C Different masses, same h, different PE!

4 + + + + + + + + + + + + + – – – – – – q2q Not same PE-- the 2q charge has greater PE However, same Potential Difference: V = W = 2W q 2q To move a larger charge across an electric field will require more work– but the potential difference of the field (voltage) stays constant!

5 Some Typical Voltages (approximately): Thundercloud to ground… 10 8 V High Power Line…. 10 6 V Television Power Supply…. 10 4 V Household outlet…. 1.1 X 10 2 V (in America) Potential changes on skin (EEG and EKG)…. 10 -4 V

6 1)How much work is needed to move a charge of -8.6 µC to a point where the potential difference is +75.0 V? 2) How much work is needed to move a proton from a point of potential of +100.0 V to a potential of -50.0 V? 3) An electron falls through a potential difference of 21,000 V in a TV tube. How much kinetic energy will it gain? 4) A force of 6.4 N is required to move a charge of 12.3 µC across an electric field created by two charged plates 3.00mm apart. What is the potential difference across these plates?

7 Capacitance A capacitor is a very common device used in electronics to store electric charge. camera flashes, RAM, surges, etc. usually two parallel plates (often rolled) + + + + + + + – – – – – – –

8 Capacitance (C) : the ratio of the charge on either plate to the potential difference between the plates C = QVQV Units: F (farad) = CVCV Capacitors have much less capacitance than a single farad: 1 µF = 10 -6 F and 1 pF = 10 -12 The insulating material between the plates will also affect the capacitance:

9 + + + + + - - - - - Air + + + + + + + + + + + - - - - - - - - - - - glass C1C1 C2C2 V 1 = V 2 but Q 2 = KQ 1 Therefore: C 2 = KC 1 where K is called the dialectric constant Dialectric constants are ratios compared to a vacuum!

10 MaterialDielectric Constant Paper1.5 to 2.6 Paraffin2.0 to 2.5 Rubber2.0 to 3.5 Glass5.4 to 10 Water80 Special electrical paper and plastics are commonly used dielectric materials. Their dielectric constants will vary depending on how they are manufactured.

11 Combinations of Capacitors Capacitors can be connected in parallel or in series: Parallel: All positive plates are connected to each other and all negative plates are connected to each other Series: Positive plates connected to negative plates + - + + + - - -

12 For capacitors connected in parallel, the larger the capacitance, the larger the stored charge, so the potential difference is constant: Q 1 = C 1 V, Q 2 = C 2 V, Q 3 = C 3 V Q T = C T V Q T = Q 1 + Q 2 + Q 3 C T V = C 1 V + C 2 V + C 3 V V cancels out, so for capacitors in Parallel: C T = C 1 + C 2 + C 3

13 For capacitors connected in series, the charge on each is constant, so: Q T = Q 1 = Q 2 = Q 3 The potential difference will vary with capacitance and the total across the combination will be: V T = QTCTQTCT V T = V 1 + V 2 + V 3 Q = Q + Q + Q C T C 1 C 2 C 3 1 = 1 + 1 + 1 C T C 1 C 2 C 3

14 Four capacitors are connected in parallel and charged to a potential difference of 150.0 V. The capacitor values are.300 µF,.300 µF,.400 µF, and.400 µF. What is the charge on one of the.400 µF capacitors? V T = 150.0 V C 1 =.300 µF C 2 =.300 µF C 3 =.400 µF C 4 =.400 µF Q 3 = ? Q 3 = C 3 V 3 V T = V 1 = V 2 = V 3 … Q 3 = (.400 µF)(150.0 V) = 60.0 µC

15 The same four capacitors are discharged and connected in series. A charge of 60.0 µC is measured across one of the.400 µF capacitors. Calculate the potential difference across one of the.300 µF capacitors. C 1 =.300 µF C 2 =.300 µF C 3 =.400 µF C 4 =.400 µF Q 3 = 60.0 µC V 2 = ? V 2 = Q2C2Q2C2 Q = Q 1 = Q 2 = Q 3 …. V 2 = 60.0 µC/.300 µF = 200 V

16 1) What is the potential difference between two points if.0065 J is required to move a charge of 3.2 µC between the points? 2) How much work must a 1.5 V battery do if it is to move.25 C per second through a wire for 13 minutes? 3) What is the equivalent capacitance when a 2.0 µF, a 4.0 µF and a 6.0 µF are connected in A) series B) parallel? 4) A proton is accelerated through a potential difference of 4.5 x 10 6 V. A) How much kinetic energyhas it acquired? B) If it started from rest, how fast is it going?

17 5) Given three 2.0 µF capacitors, draw all possible circuit diagrams and calculate the equivalent capacitance of each combination. 6) A pair of parallel plates is.0500 cm apart. Their capacitance with air between them is 75.0 pF. A) What is their capacitance with air replaced with paraffin? [ K = 2.2 ] B) If the potential difference between the plates is 25.5 V, what is the charge on each plate with paraffin? C) What is the equivalent capacitance of two pairs of these plates connected in series? D) What is the equivalent capacitance of two pairs of these plates connected in parallel?

Download ppt "Potential Difference and Capacitance Consider a rock dropped in a grav. field: Work is done by gravity To lift the object, Work is done to give the rock."

Similar presentations

Electrical Energy and Capacitance

Electrical Energy and Capacitance
Electric Energy and Current Chapter 17 Electrical Potential Energy- the potential energy between charges at a distance, or between a charge and an electric.

Electric Energy and Current Chapter 17 Electrical Potential Energy- the potential energy between charges at a distance, or between a charge and an electric.
© 2005 Pearson Prentice Hall This work is protected by United States copyright laws and is provided solely for the use of instructors in teaching their.

© 2005 Pearson Prentice Hall This work is protected by United States copyright laws and is provided solely for the use of instructors in teaching their.
Capacitors1 THE NATURE OF CAPACITANCE All passive components have three electrical properties Resistance, capacitance and inductance Capacitance is a measure.

Capacitors1 THE NATURE OF CAPACITANCE All passive components have three electrical properties Resistance, capacitance and inductance Capacitance is a measure.
Chapter 23 Capacitance.

Chapter 23 Capacitance.
Lecture 8 Capacitance and capacitors

Lecture 8 Capacitance and capacitors
Electric Potential AP Physics: M. Blachly Textbook: 17:1-3.

Electric Potential AP Physics: M. Blachly Textbook: 17:1-3.
Electric Energy and Current Chapter 18 Electrical Potential Energy- the potential energy between charges at a distance, or between a charge and an electric.

Electric Energy and Current Chapter 18 Electrical Potential Energy- the potential energy between charges at a distance, or between a charge and an electric.
Capacitance and Dielectrics

Capacitance and Dielectrics
Bright Storm on Capacitors (Start to minute 7:10).

Bright Storm on Capacitors (Start to minute 7:10).
UNIT 9 Electrostatics and Currents 1. Tuesday March 20 th 2 Electrostatics and Currents.

UNIT 9 Electrostatics and Currents 1. Tuesday March 20 th 2 Electrostatics and Currents.
Capacitors insulating dielectric Capacitors store charge. They have two metal plates where charge is stored, separated by an insulating dielectric. To.

Capacitors insulating dielectric Capacitors store charge. They have two metal plates where charge is stored, separated by an insulating dielectric. To.
Objectives: 1. Define and calculate the capacitance of a capacitor. 2. Describe the factors affecting the capacitance of the capacitor. 3. Calculate the.

Objectives: 1. Define and calculate the capacitance of a capacitor. 2. Describe the factors affecting the capacitance of the capacitor. 3. Calculate the.
1 Capacitance and Dielectrics Chapter 27 Physics chapter 27.

1 Capacitance and Dielectrics Chapter 27 Physics chapter 27.
(Capacitance and capacitors)

(Capacitance and capacitors)
General Physics II, Lec 11, Discussion, By/ T.A. Eleyan 1 Review (Electrostatic)

General Physics II, Lec 11, Discussion, By/ T.A. Eleyan 1 Review (Electrostatic)
Capacitance and Dielectrics

Capacitance and Dielectrics
Chapter 18 – Electric Potential and Capacitance Section 1 Electric Potential Energy.

Chapter 18 – Electric Potential and Capacitance Section 1 Electric Potential Energy.
Chapter 24 Capacitance, Dielectrics, Electric Energy Storage

Chapter 24 Capacitance, Dielectrics, Electric Energy Storage
A capacitor is a device that stores electrical potential energy by building up a difference in charge on two pieces of metal.

A capacitor is a device that stores electrical potential energy by building up a difference in charge on two pieces of metal.

Similar presentations

Ads by Google