Electric Potential III

Slides:



Advertisements
Similar presentations
Physics 2102 Gabriela González Physics 2102 Electric Potential.
Advertisements

Electrical Potential Electrical Potential Energy Electrical Potential
Physics 2113 Lecture: 15 FRI 20 FEB Electric Potential III Physics 2113 Jonathan Dowling.
Electric Potential II Physics 2102 Jonathan Dowling Physics 2102 Lecture 6.
Electric Potential Physics 2102 Gabriela González Physics 2102.
Physics 2113 Lecture 14: WED 18 FEB
Chapter 22 Electric Potential.
Physics 1502: Lecture 5 Today’s Agenda Announcements: –Lectures posted on: –HW assignments, solutions.
1 Fall 2004 Physics 3 Tu-Th Section Claudio Campagnari Lecture 11: 2 Nov Web page:
Electric Potential I Physics 2113 Jonathan Dowling Physics 2113 Lecture 13: FRI 13 FEB Danger!
Physics 1502: Lecture 6 Today’s Agenda Announcements: –Lectures posted on: –HW assignments, solutions.
Physics 2102 Lecture 5 Electric Potential I Physics 2102
1 Lecture 4 Electric Potential and/ Potential Energy Ch. 25 Review from Lecture 3 Cartoon - There is an electric energy associated with the position of.
Physics 2102 Lecture 9 FIRST MIDTERM REVIEW Physics 2102
Chapter 25 Electric Potential Electrical Potential and Potential Difference When a test charge is placed in an electric field, it experiences a.
Electric Potential of Uniform Charge Distributions Part II AP Physics C Montwood High School R. Casao.
Electricity and Magnetism Review 1: Units 1-6
Chapter 22 Gauss’s Law Chapter 22 opener. Gauss’s law is an elegant relation between electric charge and electric field. It is more general than Coulomb’s.
Physics 2113 Lecture 08: MON 02 FEB Electric Fields III Physics 2113 Jonathan Dowling Charles-Augustin de Coulomb ( )
Electric Potential I Physics 2102 Jonathan Dowling Physics 2102 Lecture: 08 FRI 30 JAN Ch Danger!
Electric Potential II Physics 2102 Jonathan Dowling Physics 2102 Lecture: 09 MON 02 FEB Ch
Obtaining Electric Field from Electric Potential Assume, to start, that E has only an x component Similar statements would apply to the y and z.
11/27/2015Lecture V1 Physics 122 Electric potential, Systems of charges.
Electric Potential & Electric Potential Energy. Electric Potential Energy The electrostatic force is a conservative (=“path independent”) force The electrostatic.
Physics 1202: Lecture 4 Today’s Agenda Announcements: –Lectures posted on: –HW assignments, solutions.
Physics 2113 Lecture: 14 FRI 25 SEP Electric Potential III Physics 2113 Jonathan Dowling.
-Electric Potential due to Continuous Charge Distributions AP Physics C Mrs. Coyle.
Chapter 21 Electric Potential.
Electric Potential Chapter 25 The Electric Potential
Electric Charge (1) Evidence for electric charges is everywhere, e.g.
Electric Potential II Physics 2102 Jonathan Dowling Physics 2102 Lecture: 07 TUE 09 FEB.
Electric Potential Chapter 25 Electric Potential Energy Electric Potential Equipotential Surfaces.
Lecture 4 Electric Potential/Energy Chp. 25 Cartoon - There is an electric energy associated with the position of a charge. Opening Demo - Warm-up problem.
Chapter 25 Electric Potential. Electrical Potential Energy The electrostatic force is a conservative force, thus It is possible to define an electrical.
Wednesday, Feb. 8, 2012PHYS , Spring 2012 Dr. Jaehoon Yu 1 PHYS 1444 – Section 004 Lecture #7 Wednesday, Feb. 8, 2012 Dr. Alden Stradeling Chapter.
Electric Potential 2 q A C B r A B r path independence a a Rr VQ 4   r Q 4   R.
1 Lecture 4 Work, Electric Potential and Potential Energy Ch. 25 Topics Work, electric potential energy and electric potential Calculation of potential.
Oct. 4, From last time(s)… Work, energy, and (electric) potential Electric potential and charge Electric potential and electric field. Electric charges,
Lecture 7-1 Electric Potential Energy of a Charge (continued) i is “the” reference point. Choice of reference point (or point of zero potential energy)
Electric Potential (III)
Physics 2113 Lecture: 14 FRI 26 SEP
Physics 2102 Lecture 10r: WED04FEB
Physics 2113 Lecture 12 Electric Potential II Physics 2113
Line integral of Electric field: Electric Potential
Force between Two Point Charges
Chapter 23 Electric Potential
Conductors and Gauss’s Law
Physics 2102 Lecture: 10 WED 04 FEB
Last time… Fields, forces, work, and potential
Thin sheet of any charge distribution
Chapter 23 Electric Potential
ELECTRIC POTENTIAL To move a charge that is at rest,
Un importable: #91ADB18D,6 #95A4C6F7,6 #8686DCDC,4 #8280F5F7,6
Physics 2113 Jonathan Dowling Physics 2113 Lecture 13 EXAM I: REVIEW.
Chapter 25 Electric Potential.
Chapter 23 Electric Potential
Physics 2102 Lecture: 04 WED 21 JAN
Physics 2113 Lecture 08: FRI 12 SEP
Chapter 23 Electric Potential
1/2/2019.
PHYS 1444 – Section 003 Lecture #7
Physics 2113 Lecture 07: WED 09 SEP
Physics 2102 Lecture 06: THU 04 FEB
Relation Between Electric Potential V & Electric Field E
Physics 2113 Lecture 11 Electric Potential I Physics 2113
Chapter 25 - Summary Electric Potential.
Phys102 Lecture 2 The Electric Field
Halliday/Resnick/Walker Fundamentals of Physics 8th edition
Chapter 23 Electric Potential
Chapter 23 Electric Potential
Presentation transcript:

Electric Potential III Physics 2113 Jonathan Dowling Physics 2113 Lecture: 14 Electric Potential III

Conservative Forces, Work, and Potential Energy Work Done (W) is Integral of Force (F) Potential Energy (U) is Negative of Work Done Hence Force is Negative Derivative of Potential Energy

Coulomb’s Law for Point Charge Force [N] = Newton Electric Field [N/C]=[V/m] Potential Energy [J]=Joule Potential Voltage [J/C]=[V] =Volt q2 q2 q1 P2 P1 P2 P1

Potential At Center of Ring of Charge Divide the charge distribution into differential elements Write down an expression for potential voltalge from a typical element — treat as point charge Integrate! Simple example: circular rod of radius r, total charge Q; find V at center. r dq Same result holds along z-axis!

Potential Along Axis of Ring of Charge Divide the charge distribution into differential elements Write down an expression for potential voltalge from a typical element — treat as point charge Integrate! R’ dq dq

Potential Voltage of Continuous Charge Distribution: Return of the Rod! Uniformly charged rod Total charge +Q Length L What is V at position P? r = x P dq=λdx L a dq Units: [Nm2/C2][C/m]=[Nm/C]=[J/C]=[V]

Potential Voltage of Continuous Charge Distribution: Return of the Rod! Uniformly charged rod Total charge +Q Length L What is V at position P? What about a>>L? r = x P dq=λdx L a In this limit we recover V=kq/r for point charge!

Potential Voltage of Continuous Charge Uniformly charged rod Total charge +Q Length L What is V at position P?

Potential Voltage of Continuous Charge What about d>>L? We recover formula V=kq/r for a point charge Again!

Electric Field & Potential: A Simple Relationship! Focus only on a simple case: electric field that points along +x axis but whose magnitude varies with x. Notice the following: Point charge: E = kQ/r2 V = kQ/r Dipole (far away): E = kp/r3 V = kp/r2 E is given by a DERIVATIVE of V! Of course! Note: MINUS sign! Units for E: VOLTS/METER (V/m)

E from V: Example Uniformly charged rod Total charge +Q Length L We Found V at P! Find E from V? x P dq L a Units: √ Electric Field!

Electric Field & Potential: ICPP Hollow metal spherical shell of radius R has a charge on the shell +q Which of the following is magnitude of the electric potential voltage V as a function of distance r from center of sphere? R V r r=R (b) V r r=R (a) Hint: Inside sphere there are no charges so E=0. But E=dV/dr=0. What can V be?

(a) Since Δx is the same, only |ΔV| matters! |ΔV1| =200, |ΔV2| =220, |ΔV3| =200 |E2| > |E3| = |E1| The bigger the voltage drop the stronger the field. Δx (b) = 3 (c) F = qE = ma accelerate leftward

Equipotentials and Conductors Conducting surfaces are EQUIPOTENTIALs At surface of conductor, E is normal (perpendicular) to surface Hence, no work needed to move a charge from one point on a conductor surface to another Equipotentials are normal to E, so they follow the shape of the conductor near the surface. V E

Conductors Change the Field Around Them! An Uncharged Conductor: A Uniform Electric Field: An Uncharged Conductor in the Initially Uniform Electric Field:

Sharp Conductors (NASA) Charge density is higher at conductor surfaces that have small radius of curvature E = σ/ε0 for a conductor, hence STRONGER electric fields at sharply curved surfaces! Used for attracting or getting rid of charge: lightning rods Van de Graaf -- metal brush transfers charge from rubber belt Mars pathfinder mission -- tungsten points used to get rid of accumulated charge on rover (electric breakdown on Mars occurs at ~100 V/m) (NASA)

Sharp Conductors: Lightning Rods

Ben Franklin Invents the Lightning Rod!

LIGHTNING SAFE CROUCH If caught out of doors during an approaching storm and your skin tingles or hair tries to stand on end, immediately do the "LIGHTNING SAFE CROUCH ”. Squat low to the ground on the balls of your feet, with your feet close together. Place your hands on your knees, with your head between them. Be the smallest target possible, and minimize your contact with the ground.

WE’LL BOTH BE DEAD IN SECONDS! QUICK — TAKE A SELFIE! WE’LL BOTH BE DEAD IN SECONDS!

Summary: Electric potential: work needed to bring +1C from infinity; units = V = Volt Electric potential uniquely defined for every point in space -- independent of path! Electric potential is a scalar -- add contributions from individual point charges We calculated the electric potential produced by a single charge: V = kq/r, and by continuous charge distributions : dV = kdq/r Electric field and electric potential: E= -dV/dx Electric potential energy: work used to build the system, charge by charge. Use W = U = qV for each charge. Conductors: the charges move to make their surface equipotentials. Charge density and electric field are higher on sharp points of conductors.