DOCSLIB.ORG

Physics 1B Electricity & Magnetism

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text

Load more

Physics 1B! Electricity & Magnetism Frank Wuerthwein (Prof) Edward Ronan (TA) UCSD Quiz 1 • Quiz 1A and it’s answer key is online at course web site. • http://hepuser.ucsd.edu/twiki2/bin/view/ UCSDTier2/Physics1BWinter2012 • Expect to have grades up on web site by Friday evening this week. Outline of today • Continue Chapter 20. • Equipotentials • Parallel plates • Capacitance Equipotentials • An equipotential surface is a surface on which all points are the same potential. • It takes no work to move a particle along an equipotential surface or line (assume speed is constant). • The electric field at every point on an equipotential surface is perpendicular to the surface. • Equipotential surfaces are normally thought of as being imaginary; but they may correspond to real surfaces (like the surface of a conductor). Equipotentials • Let’s construct an equipotential surface for a lone negative charge. -10V " ! First, draw the field lines for -20V the charge. " ! If I move 1m away would -30V it matter if it was up or – down or left or right if I were to calculate potential? " ! No, so our equipotential surface would be a sphere. " ! Also, since V goes as (1/r), the spacing would increase between equipotential surfaces. Equipotentials •! For a lone positive charge, the equipotential surfaces are all spheres centered on the charge. •! We represent these spheres with equipotential lines. " ! Equipotential lines are shown in blue, electric field lines are shown in red. " ! Note that the field lines are perpendicular to the equipotential lines at every crossing. Equipotentials •! As you increase the number of charges in the distribution the equipotential lines get more complicated. •! Take the electric dipole composed of a positive and a negative charge. Parallel Plates •! If we had a very large plane of positive charge, what would the electric + + + + + + + + field look like? •! The electric field would be uniform in both directions away from the positive plate. " ! A positive charge on either side of the plate (top or bottom) would be repelled. Parallel Plates " ! What would be different if the plate were negative (but had the same magnitude of charge)? – – – – – – – – " ! The electric field would flip direction (in toward the negative plate), but still have the same magnitude. " ! A positive charge on either side of the plate (top or bottom) would be attracted. Parallel Plates + + + + + + + + •! What would now happen if I place the plates close together and parallel to each other? •! The field would be twice as strong in between the – – – – – – – – plates, but would essentially disappear " ! Equipotential lines are outside of the plates. evenly spaced! " ! What would the equipotential lines look like between the plates? Parallel Plates •! If I were to place a positive charge, q, in between the plates and then release it, what would happen? " ! The positive charge would move away from the positive plate (high PE, high V) toward the negative plate (low PE, low V). " ! The work done by the electric field would be: ! ! W = Felec " #x ! ! W = qE " #x = $#PE ! ! Parallel Plates • If we were to then turn to electric potential, we can say that: " ! This is true for a uniform electric field. " ! But, general, you can always say that: " ! These equations just reiterate that if you move with the electric field, your electric potential will decrease. Parallel Plates •! We put opposite charges on two parallel plates and we create an electric field in between the plates. •! This is essentially storing energy between these plates by creating an electric field between them. •! We call such a device: Capacitor •! Next we will talk about how to characterize the electrical properties of such a device. Capacitors •! Capacitance, C, is a measure of how much charge can be stored for a capacitor with a given electric potential difference. " ! Where Q is the amount of charge on each plate (+Q on one, –Q on the other). " ! Capacitance is measured in Farads. " ! [Farad] = [Coulomb]/[Volt] " ! A Farad is a very large unit. Most things that you see are measured in μF or nF. Capacitors •! Inside a parallel-plate capacitor, the capacitance is: " ! where A is the area of one of the plates and d is the separation distance between the plates. " ! When you connect a battery up to a capacitor, charge is pulled from one plate and transferred to the other plate. Capacitors " ! The transfer of charge will stop when the potential drop across the capacitor equals the potential difference of the battery. " ! Capacitance is a physical fact of the capacitor, the only way to change it is to change the geometry of the capacitor. " ! Thus, to increase capacitance, increase A or decrease d or some other physical change to the capacitor. Concept Question •! You connect a capacitor to a 1.5V battery and you get a certain amount of charge Q on each plate. Which of the following happens if you replace the 1.5V battery with a 3.0V battery. " ! A) The capacitance, C, of the capacitor doubles. " ! B) The capacitance, C, of the capacitor halves. " ! C) The charge, Q, on each plate doubles. " ! D) The charge, Q, on each plate halves. " ! E) Neither C nor Q changes. •! ExampleCapacitance •! A parallel-plate capacitor is connected to a 3V battery. The capacitor plates are 20m2 and are separated by a distance of 1.0mm. What is the amount of charge that can be stored on a plate? •! Answer •! Usually no coordinate system needs to be defined for a capacitor (unless a charge moves in between the plates). •! Start with the equation for a parallel-plate capacitor. Capacitance " Answer " ! Start with: " ! Next, turn to the definition of capacitance: Capacitors •! Capacitors are usually used in circuits. •! A circuit is a collection of objects usually containing a source of electrical energy (like a battery). •! This energy source is connected to elements (like capacitors) that convert the electrical energy to other forms. •! We usually create a circuit diagram to represent all of the elements at work in the real circuit. Circuits •! For example, let’s say that we had two capacitors connected in parallel to a battery. •! In the circuit diagram we would represent a capacitor with a parallel line symbol: || •! Also, in the circuit diagram we would represent a battery with a short line and a long line: i| •! The short line representing the negative terminal and the long line representing the positive terminal. Capacitors •! The previous real circuit can then be drawn as a circuit diagram as follows: " ! In this circuit, both capacitors would have the same potential difference as the battery. " ! ΔVbat = ΔV1 = ΔV2 •! Plus, we can say that the charges on either plate are equal to the total that passes through the battery. •! QTo t = Q1 + Q2 Capacitors •! We can essentially replace the two capacitors in parallel with one equivalent capacitor (this may make our life easier). " ! The equivalent capacitor must have exactly the same external effect on the circuit as the original capacitors. " ! The battery sees QTo t passing through it and believes that the one equivalent capacitor has a potential difference of ΔV. For Next Time (FNT) •!Prepare for the Quiz on Friday •!Continue homework for Chapter 20 •!Keep reading Chapter 20 .
Recommended publications
  • Experiment 1: Equipotential Lines and Electric Fields

    Experiment 1: Equipotential Lines and Electric Fields

    MASSACHUSETTS INSTITUTE OF TECHNOLOGY Department of Physics 8.02 Spring 2006 Experiment 1: Equipotential Lines and Electric Fields OBJECTIVES 1. To develop an understanding of electric potential and electric fields 2. To better understand the relationship between equipotentials and electric fields 3. To become familiar with the effect of conductors on equipotentials and E fields PRE-LAB READING INTRODUCTION Thus far in class we have talked about fields, both gravitational and electric, and how we can use them to understand how objects can interact at a distance. A charge, for example, creates an electric field around it, which can then exert a force on a second charge which enters that field. In this lab we will study another way of thinking about this interaction through electric potentials. The Details: Electric Potential (Voltage) Before discussing electric potential, it is useful to recall the more intuitive concept of potential energy, in particular gravitational potential energy. This energy is associated with a mass’s position in a gravitational field (its height). The potential energy difference between being at two points is defined as the amount of work that must be done to move between them. This then sets the relationship between potential energy and force (and hence field): B G G dU ∆=UU−U=−Fs⋅d ⇒ ()in 1D F=− (1) BA∫ A dz We earlier defined fields by breaking a two particle interaction, force, into two single particle interactions, the creation of a field and the “feeling” of that field. In the same way, we can define a potential which is created by a particle (gravitational potential is created by mass, electric potential by charge) and which then gives to other particles a potential energy.
  • Electric Potential Equipotentials and Energy

    Electric Potential Equipotentials and Energy

    Electric Potential Equipotentials and Energy Phys 122 Lecture 8 G. Rybka Your Thoughts • Nervousness about the midterm I would like to have a final review of all the concepts that we should know for the midterm. I'm having a lot of trouble with the homework and do not think those questions are very similar to what we do in class, so if that's what the midterm is like I think we need to do more mathematical examples in class. • Confusion about Potential I am really lost on all of this to be honest I'm having trouble understanding what Electric Potential actually is conceptually. • Some like the material! I love potential energy. I think it is These are yummy. fascinating. The world is amazing and physics is everything. A few answers Why does this even matter? Please go over in detail, it kinda didn't resonate with practical value. This is the first pre-lecture that really confused me. What was the deal with the hill thing? don't feel confident in my understanding of the relationship of E and V. Particularly calculating these. If we go into gradients of V, I will not be a happy camper... The Big Idea Electric potential ENERGY of charge q in an electric field: b ! ! b ! ! ΔU = −W = − F ⋅ dl = − qE ⋅ dl a→b a→b ∫ ∫ a a New quantity: Electric potential (property of the space) is the Potential ENERGY per unit of charge ΔU −W b ! ! ΔV ≡ a→b = a→b = − E ⋅ dl a→b ∫ q q a If we know E, we can get V The CheckPoint had an “easy” E field Suppose the electric field is zero in a certain region of space.
  • Electric Field and Equipotential: 1 General Physics Lab Handbook By

    Electric Field and Equipotential: 1 General Physics Lab Handbook By

    General Physics Lab Handbook by D.D.Venable, A.P.Batra, T.Hübsch, D.Walton & M.Kamal Electric Field and Equipotential OBJECT: To plot the equipotential lines in the space between a pair of charged electrodes and relate the electric field to these lines. APPARATUS: Two different plastic templates (opaque and either cardboard, transparent, or plastic) digital voltmeter (DVM), graph sheets, BK Precision Power Supply/Battery Eliminator 3.3/4.5/6/7.5/9/12V, 1A Model#1513 potential source (with 6 Volts selected), and connecting wires. THEORY: Electric field is an important and useful concept in the study of electricity. For an electric charge distribution, the electric field intensity or simply the electric field at a point in space is defined as the electric force per unit charge: r r F E = . (1) q From the knowledge of an electric field, we can determine the force on any arbitrary charge at different points. Theoretically the electric field is determined using an infinitesimally small positive test charge q0. By convention the direction of the electric field is the direction of the force that the test charge experiences. The electric field (which is a vector field), may therefore be mapped or displayed graphically by lines of force. A line of force is an imaginary line in space along which the test particle would move under the influence of the mapped electrostatic field; at any point, the tangent to the line of force gives the electric field at that point. For a simple case of an isolated positive charge, the electric field is directed radially outward, as shown in the Fig.
  • Chapter 17 Electric Potential

    Chapter 17 Electric Potential

    Chapter 17 Electric Potential The Electric Potential Difference Created by Point Charges When two or more charges are present, the potential due to all of the charges is obtained by adding together the individual potentials. Example: The Total Electric Potential At locations A and B, find the total electric potential. The Electric Potential Difference Created by Point Charges 8.99×109 N ⋅m2 C2 + 8.0×10−-98 C 8.99×109 N ⋅m2 C2 −8.0×10−-98 C V = ( )( )+ ( )( )= +240 V A 0.20 m 0.60 m 8.99×109 N ⋅m2 C2 + 8.0×10−-98 C 8.99×109 N ⋅m2 C2 −8.0×10-9−8 C V = ( )( )+ ( )( )= 0 V B 0.40 m 0.40 m Equipotential Surfaces and Their Relation to the Electric Field An equipotential surface is a surface on which the electric potential is the same everywhere. Equipotential surfaces for kq a point charge (concentric V = r spheres centered on the charge) The net electric force does no work on a charge as it moves on an equipotential surface. Equipotential Surfaces and Their Relation to the Electric Field The electric field created by any charge or group of charges is everywhere perpendicular to the associated equipotential surfaces and points in the direction of decreasing potential. In equilibrium, conductors are always equipotential surfaces. Equipotential Surfaces and Their Relation to the Electric Field Lines of force and equipotential surfaces for a charge dipole. Equipotential Surfaces and Their Relation to the Electric Field The electric field can be shown to be related to the electric potential.
  • 19 Electric Potential and Electric Field

    19 Electric Potential and Electric Field

    CHAPTER 19 | ELECTRIC POTENTIAL AND ELECTRIC FIELD 663 19 ELECTRIC POTENTIAL AND ELECTRIC FIELD Figure 19.1 Automated external defibrillator unit (AED) (credit: U.S. Defense Department photo/Tech. Sgt. Suzanne M. Day) Learning Objectives 19.1. Electric Potential Energy: Potential Difference • Define electric potential and electric potential energy. • Describe the relationship between potential difference and electrical potential energy. • Explain electron volt and its usage in submicroscopic process. • Determine electric potential energy given potential difference and amount of charge. 19.2. Electric Potential in a Uniform Electric Field • Describe the relationship between voltage and electric field. • Derive an expression for the electric potential and electric field. • Calculate electric field strength given distance and voltage. 19.3. Electrical Potential Due to a Point Charge • Explain point charges and express the equation for electric potential of a point charge. • Distinguish between electric potential and electric field. • Determine the electric potential of a point charge given charge and distance. 19.4. Equipotential Lines • Explain equipotential lines and equipotential surfaces. • Describe the action of grounding an electrical appliance. • Compare electric field and equipotential lines. 19.5. Capacitors and Dielectrics • Describe the action of a capacitor and define capacitance. • Explain parallel plate capacitors and their capacitances. • Discuss the process of increasing the capacitance of a dielectric. • Determine capacitance given charge and voltage. 19.6. Capacitors in Series and Parallel • Derive expressions for total capacitance in series and in parallel. • Identify series and parallel parts in the combination of connection of capacitors. • Calculate the effective capacitance in series and parallel given individual capacitances. 19.7. Energy Stored in Capacitors • List some uses of capacitors.
  • Electric Potential

    Electric Potential

    Chapter 23 Electric Potential PowerPoint® Lectures for University Physics, Thirteenth Edition – Hugh D. Young and Roger A. Freedman Lectures by Wayne Anderson Copyright © 2012 Pearson Education Inc. Goals for Chapter 23 • To calculate the electric potential energy of a group of charges • To know the significance of electric potential • To calculate the electric potential due to a collection of charges • To use equipotential surfaces to understand electric potential • To calculate the electric field using the electric potential Copyright © 2012 Pearson Education Inc. Introduction • How is electric potential related to welding? • Electric potential energy is an integral part of our technological society. • What is the difference between electric potential and electric potential energy? • How is electric potential energy related to charge and the electric field? Copyright © 2012 Pearson Education Inc. Electric potential energy in a uniform field • The behavior of a point charge in a uniform electric field is analogous to the motion of a baseball in a uniform gravitational field. • Figures 23.1 and 23.2 below illustrate this point. Copyright © 2012 Pearson Education Inc. A positive charge moving in a uniform field • If the positive charge moves in the direction of the field, the potential energy decreases, but if the charge moves opposite the field, the potential energy increases. • Figure 23.3 below illustrates this point. Copyright © 2012 Pearson Education Inc. A negative charge moving in a uniform field • If the negative charge moves in the direction of the field, the potential energy increases, but if the charge moves opposite the field, the potential energy decreases. • Figure 23.4 below illustrates this point.
  • Module 2 : Electrostatics Lecture 10 : Poisson Equations

    Module 2 : Electrostatics Lecture 10 : Poisson Equations

    Module 2 : Electrostatics Lecture 10 : Poisson Equations Objectives In this lecture you will learn the following Poisson's equation and its formal solution Equipotential surface Capacitors - calculation of capacitance for parallel plate, spherical and cylindrical capacitors Work done in charging a capacitor Poisson Equation Differential form of Gauss's law, Using , so that This is Poisson equation. In cartesian form, A formal soltion to Poisson equation can be written down by using the property Dirac - function discussed earlier. It can be seen that Operating with operator on both sides (The subscrpt indicates that here is to be taken with respect to variable ) We had shown that substituting which the expression follows. Equipotential surface Equipotential surfaces are defined as surfaces over which the potential is constant At each point on the surface, the electric field is perpendicular to the surface since the electric field, being the gradient of potential, does not have component along a surface of constant potential. We have seen that any charge on a conductor must reside on its surface. These charges would move along the surface if there were a tangential component of the electric field. The electric field must therefore be along the normal to the surface of a conductor. The conductor surface is, therefore, an equipotential surface. Electric field lines are perpendicular to equipotential surfaces (or curves) and point in the direction from higher potential to lower potential. In the region where the electric field is strong, the equipotentials are closely packed as the gradient is large. Click here for Animation The electric field strength at the point P may be found by finding the slope of the potential at the point P.
  • Coefficient of Potential and Capacitance Lecture 12: Electromagnetic Theory

    Coefficient of Potential and Capacitance Lecture 12: Electromagnetic Theory

    Coefficient of Potential and Capacitance Lecture 12: Electromagnetic Theory Professor D. K. Ghosh, Physics Department, I.I.T., Bombay We know that inside a conductor there is no electric field and that the surface of a metal is an equipotential surface. Further, the tangential component of the electric field on the surface is zero leaving with only a normal component of the field on the surface. Our argument in arriving at these properties was largely intuitive and was based on our expectation that under electrostatic conditions, we expect the system of charges to stabilize and move around. Let us look at this problem from a mathematical stand point. Consider surface of a conductor. Let us take the conductor surface to be in the xy plane. In the vacuum outside the conductor there are no free charges so that . Further as we are concerned with only electrostatic phenomena, everywhere. There are charges only on the surface of the conductor which would produce an electric field. The charges must be distributed in such a way that the fields they produce superpose so as to cancel the electric field inside the metal. So near the surface of the metal over a small a distance there is a change in the electric potential. Thus, if we take the outward normal to the surface of the conductor to be along the positive z direction, the z component of the electric field must be large near the surface. If the surface is homogeneous, or must be finite and continuous. Since the curl of the electric field is zero, this means, for instance, and since is finite and continuous, so must be , and by symmetry, .
  • Chapter 19: Electric Potential Energy & Electric Potential Why Electric

    Chapter 19: Electric Potential Energy & Electric Potential Why Electric

    Chapter 19: Electric Potential Energy & Electric Potential Why electric field contains energy? Is there an alternative way to understand electric field? Concepts: • Work done by conservative force • Electric potential energy • Elect ri c potenti a l 19.1 Potential Energy The electric force, like gravity, is a conservative force: Recall Conservative Forces 1. The work done on an object by a conservative force depends only on the object’s initial and final position, and not the path taken. 2. The net work done by a conservative force in moving an object around a closed path is zero. Let’s place a positive point charge q in a uniform electric field and let it move from point A to B (no gravity): How much work is done by the field in moving the charge from A to B? + +++ + +q yo A * Remember, W = Fd xd,whereFx d, where Fd is the component of the constant force along the direction of the motion. E Here, , so F = qE W = qE(y f − yo ) = qEΔy y f B Electrostatic Potential - --- - Energy (EPE) Thus, W = ΔEPE The work done is equal to the change in AB electrostatic potential energy! Now let’s divide both sides by the charge, q: W ΔEPE AB = The quantity on the right is the potential energy per unit q q charge. We call this the Electric Potential, V: EPE V = The electric potential is q a scalar! Units? ⎡Energy⎤ ⎡ J ⎤ ⎢ ⎥ = ⎢ ⎥ = [Volt]= [V ] ⎣Charge⎦ ⎣C ⎦ Review of Work: 1. Work is not a vector, but it can be either positive or negative: Positive – Force is in the same direction as the motion Negative – Force is in the opposite direction as the motion 2.
  • Chapter 23 – Electric Potential

    Chapter 23 – Electric Potential

    Chapter 23 – Electric Potential - Electric Potential Energy - Electric Potential and its Calculation - Equipotential surfaces - Potential Gradient 0. Review b b Work: Wa→b = ∫ F ⋅ ld = ∫ F ⋅cos ϕ ⋅dl a a Potential energy - If the force is conservative: Wa→b = U a −U b = −(U b −U a ) = −∆U Work-Energy: K a +U a = K b +U b The work done raising a basketball against gravity depends only on the potential energy, how high the ball goes. It does not depend on other motions. A point charge moving in a field exhibits similar behavior. 1. Electric Potential Energy - When a charged particle moves in an electric field, the field exerts a force that can do work on the particle. The work can be expressed in terms of electric potential energy. - Electric potential energy depends only on the position of the charged particle in the electric field. Electric Potential Energy in a Uniform Field: Wa→b = F ⋅d = q0 Ed Electric field due to a static charge distribution generates a conservative force: Wa→b = −∆U → U = q0 E ⋅ y - Test charge moving from height ya to yb: Wa→b = −∆U = −(Ub −U a ) = q0 E(ya − yb ) Independently of whether the test charge is (+) or (-): - U increases if q 0 moves in direction opposite to electric force. - U decreases if q 0 moves in same direction as F = q 0 E. Electric Potential Energy of Two Point Charges: A test charge (q 0) will move directly away from a like charge q. rb rb 1 qq qq 1 1 W = F ⋅dr = 0 ⋅dr = 0 − a→b ∫ r ∫ 4πε r 2 4πε r r ra ra 0 0 a b The work done on q 0 by electric field does not depend on path taken, but only on distances ra and rb (initial and end points).
  • Electric Potential Equipotential Surfaces; Potential Due to a Point

    Electric Potential Equipotential Surfaces; Potential Due to a Point

    Electric Potential Equipotential Surfaces; Potential due to a Point Charge and a Group of Point Charges; Potential due to an Electric Dipole; Potential due to a Charge Distribution; Relation between Electric Field and Electric Potential Energy 1. How to find the electric force on a particle 1 of charge q1 when the particle is placed near a particle 2 of charge q2. 2. A nagging question remains: How does particle 1 “know “of the presence of particle 2? 3. That is, since the particles do not touch, how can particle 2 push on particle 1—how can there be such an action at a distance? 4. One purpose of physics is to record observations about our world, such as the magnitude and direction of the push on particle 1. Another purpose is to provide a deeper explanation of what is recorded. 5. One purpose of this chapter is to provide such a deeper explanation to our nagging questions about electric force at a distance. We can answer those questions by saying that particle 2 sets up an electric field in the space surrounding itself. If we place particle 1 at any given point in that space, the particle “knows” of the presence of particle 2 because it is affected by the electric field that particle 2 has already set up at that point. Thus, particle 2 pushes on particle 1 not by touching it but by means of the electric field produced by particle 2. One purpose of physics is to record observations about our world, 1 Equipotential Surfaces: Potential energy: When an electrostatic force acts between two or more charged particles within a system of particles, we can assign an electric potential energy U to the system.
  • Electric Potential of a Point Charge Equipotential Lines

    Electric Potential of a Point Charge Equipotential Lines

    Physics 08-07 Electric Potential Due to a Point Charge and Equipotential Lines Name: _____________________________ Electric Potential of a Point Charge 푘푞 푉 = 푟 V is __________________ the __________________ potential V __________ the potential difference if a test charge were ______________ to a distance of r from __________________ Two or more charges o Find the __________________ due to __________________ charge at that location o __________________ the potentials together to get the __________________ potential Two charges are 1 m apart. The charges are +2 μC and -4 μC. What is the potential 1/3 of the way between them? −11 How much work is done (−푊 = 푃퐸푓 − 푃퐸0) to bring two electrons to a distance of 5.3 × 10 m to the nucleus of a Helium atom (푞 = 3.2 × 10−19 퐶)? Equipotential Lines Lines where the electric __________________ is the __________________ Perpendicular to __________________ No ________________ is required to move charge along __________________ line since 푞훥푉 = 0 Sketch the equipotential lines in the vicinity of two opposite charges, where the negative charge is three times as great in magnitude as the positive. Created by Richard Wright – Andrews Academy To be used with OpenStax College Physics Physics 08-07 Electric Potential Due to a Point Charge and Equipotential Lines Name: _____________________________ Homework 1. What is an equipotential line? What is an equipotential surface? 2. Explain in your own words why equipotential lines and surfaces must be perpendicular to electric field lines. 3. Can different equipotential lines cross? Explain. 4. Imagine that you are moving a positive test charge along the line between two identical point charges.