Presentation is loading. Please wait.

Presentation is loading. Please wait.

Electrical Energy, Potential and Capacitance

Published byHomer Gibbs Modified over 6 years ago

Similar presentations

Presentation on theme: "Electrical Energy, Potential and Capacitance"— Presentation transcript:

1 Electrical Energy, Potential and Capacitance

2 Understanding “Difference”
Let’s say we have a proton placed between a set of charged plates. If the proton is held fixed at the positive plate, the ELECTRIC FIELD will apply a FORCE on the proton (charge). Since like charges repel, the proton is considered to have a high potential (voltage) similar to being above the ground. It moves towards the negative plate or low potential (voltage). The plates are charged using a battery source where one side is positive and the other is negative. The positive side is at 9V, for example, and the negative side is at 0V. So basically the charge travels through a “change in voltage” much like a falling mass experiences a “change in height. (Note: The electron does the opposite)

3 Electric Potential and Electric Fields
Since the amount of energy per charge is called Electric Potential, or Voltage, the product of the electric field and displacement is also VOLTAGE This makes sense as it is applied usually to a set of PARALLEL PLATES. DV=Ed Units: V = volts d = m E = N/C or V/m E DV d

4 Example A pair of oppositely charged, parallel plates are separated by 5.33 mm. A potential difference of 600 V exists between the plates. (a) What is the magnitude of the electric field strength between the plates? (b) What is the magnitude of the force on an electron between the plates?

5 Example A pair of oppositely charged, parallel plates are separated by 5.33 mm. A potential difference of 600 V exists between the plates. (a) What is the magnitude of the electric field strength between the plates? (b) What is the magnitude of the force on an electron between the plates? 113, N/C 1.81x10-14 N

6 Calculate the speed of a proton that is accelerated from rest through a potential difference of 120 V

7 Example Calculate the speed of a proton that is accelerated from rest through a potential difference of 120 V 1.52x105 m/s

8 Electric Potential of a Point Charge
Up to this point we have focused our attention solely to that of a set of parallel plates. But those are not the ONLY thing that has an electric field. Remember, point charges have an electric field that surrounds them. So imagine placing a TEST CHARGE out way from the point charge. Will it experience a change in electric potential energy? YES! Thus is also must experience a change in electric potential as well.

9 Electric Potential Let’s use our “plate” analogy. Suppose we had a set of parallel plates symbolic of being “above the ground” which has potential difference of 50V and a CONSTANT Electric Field. DV = ? From 1 to 2 DV = ? From 2 to 3 DV = ? From 3 to 4 DV = ? From 1 to 4 1 25 V 0 V 2 3 d 0.5d, V= 25 V E 12.5 V 4 0.25d, V= 12.5 V 37.5 V Notice that the “ELECTRIC POTENTIAL” (Voltage) DOES NOT change from 2 to 3. They are symbolically at the same height and thus at the same voltage. The line they are on is called an EQUIPOTENTIAL LINE. What do you notice about the orientation between the electric field lines and the equipotential lines?

10 Equipotential Lines So let’s say you had a positive charge. The electric field lines move AWAY from the charge. The equipotential lines are perpendicular to the electric field lines and thus make concentric circles around the charge. As you move AWAY from a positive charge the potential decreases. So V1>V2>V3. Now that we have the direction or visual aspect of the equipotential line understood the question is how can we determine the potential at a certain distance away from the charge? r V(r) = ?

11 Measuring Capacitance
Let’s go back to thinking about plates! The unit for capacitance is the FARAD, F. Surface Charge Density C/m2

12 Energy of a Capacitor

13 Example A parallel plate has an area of m2 and a plate separation of 0.001m and connected to a battery of 3V. What is the capacitance? charge on the positive plate? surface charge density? Magnitude of the electric field?

14

15 Example A 2.5x10-5F plate holds 1.75x10-3C of charge. What is the
Stored energy on the plate? voltage across the plate? new voltage by doubling the stored energy of the plate?

Download ppt "Electrical Energy, Potential and Capacitance"

Similar presentations

Electric Potential Energy and the Electric Potential

Electric Potential Energy and the Electric Potential
Electrical Energy, Potential and Capacitance

Electrical Energy, Potential and Capacitance
Electrical Energy and Electric Potential AP Physics C.

Electrical Energy and Electric Potential AP Physics C.
Physics 152 Walker, Chapter 20 Electrostatic Potential Energy Electrostatic Potential.

Physics 152 Walker, Chapter 20 Electrostatic Potential Energy Electrostatic Potential.
Unit 2 Day 3: Electric Energy Storage Electric potential energy stored between capacitor plates Work done to add charge to the capacitor plates Energy.

Unit 2 Day 3: Electric Energy Storage Electric potential energy stored between capacitor plates Work done to add charge to the capacitor plates Energy.
February 16, 2010 Potential Difference and Electric Potential.

February 16, 2010 Potential Difference and Electric Potential.
Lecture 7 Capacitors. Micro-economists are wrong about specific things, and macroeconomists are wrong about things in general. Yoram Bauman.

Lecture 7 Capacitors. Micro-economists are wrong about specific things, and macroeconomists are wrong about things in general. Yoram Bauman.
Electrical Energy and Electric Potential

Electrical Energy and Electric Potential
Chapter 17 Electric Potential.

Chapter 17 Electric Potential.
Charge Comes in + and – Is quantized elementary charge, e, is charge on 1 electron or 1 proton e = 1.602  10 -19 Coulombs Is conserved total charge remains.

Charge Comes in + and – Is quantized elementary charge, e, is charge on 1 electron or 1 proton e =  Coulombs Is conserved total charge remains.
Electric Potential and Electric Energy Chapter 17.

Electric Potential and Electric Energy Chapter 17.
Electric Potential. Electrostatic Potential Energy and Potential Difference The electrostatic force is conservative – potential energy can be defined.

Electric Potential. Electrostatic Potential Energy and Potential Difference The electrostatic force is conservative – potential energy can be defined.
Electric Potential Difference. Electric Potential Energy (PE) Potential energy associated with a charged object due to its position relative to a source.

Electric Potential Difference. Electric Potential Energy (PE) Potential energy associated with a charged object due to its position relative to a source.
Electrical Energy and Potential IB Physics. Electric Fields and WORK In order to bring two like charges near each other work must be done. In order to.

Electrical Energy and Potential IB Physics. Electric Fields and WORK In order to bring two like charges near each other work must be done. In order to.
1 My Chapter 17 Lecture Outline. 2 Chapter 17: Electric Potential Electric Potential Energy Electric Potential How are the E-field and Electric Potential.

1 My Chapter 17 Lecture Outline. 2 Chapter 17: Electric Potential Electric Potential Energy Electric Potential How are the E-field and Electric Potential.
Electric Potential AP Physics Chapter 17. Electric Charge and Electric Field 17.1 Electric Potential Energy and Potential Difference.

Electric Potential AP Physics Chapter 17. Electric Charge and Electric Field 17.1 Electric Potential Energy and Potential Difference.
e-e- e-e- e-e- e-e- e-e- e-e- e-e- e-e- e-e- e-e- p+p+ p+p+ p+p+ Connecting two parallel plates to a battery produces uniform electric field  the electric.

e-e- e-e- e-e- e-e- e-e- e-e- e-e- e-e- e-e- e-e- p+p+ p+p+ p+p+ Connecting two parallel plates to a battery produces uniform electric field  the electric.
Which of these configurations gives V = 0 at all points on the y-axis? 4) all of the above 5) none of the above 10. Equipotential Surfaces III 1) x +2.

Which of these configurations gives V = 0 at all points on the y-axis? 4) all of the above 5) none of the above 10. Equipotential Surfaces III 1) x +2.
Chapter 18.2 Review Capacitance and Potential. 1. A 5 μF capacitor is connected to a 12 volt battery. What is the potential difference across the plates.

Chapter 18.2 Review Capacitance and Potential. 1. A 5 μF capacitor is connected to a 12 volt battery. What is the potential difference across the plates.
Static Electricity, Electric Forces, Electric Fields, Electric Potential Energy, Electric Potential, Capacitors.

Static Electricity, Electric Forces, Electric Fields, Electric Potential Energy, Electric Potential, Capacitors.

Similar presentations

Ads by Google