Algebra-based Physics II

lgebabased Physics II Chapte 19 Electic potential enegy & The Electic potential Why enegy is stoed in an electic field? How to descibe an field fom enegetic point of view? Class Website: Natual way of enegy elease http://www.phys.lsu.edu/~jzhang/teaching.html

19.1 Potential Enegy Recall Consevative Foces Gavitational foce is a consevative foce 1. The wok done on an object by a consevative foce depends only on the object s initial and final position, and not the path taken.. The net wok done by a consevative foce in moving an object aound a closed path is zeo. Wok (W B ) decease of potential enegy ΔP PE PE B mgδy mgh G h W 0 B

Electic Potential Enegy The electic foce also a consevative foce Let s place a positive point chage in a unifom electic field and let it move fom point to B (no gavity): How much wok is done by the field in moving the chage fom to B? y o E *Remembe, W F d, whee F is the component of the constant foce along the diection of the motion. y f B Hee, F E, so W E( y y ) f o EΔy Intoduce: Electostatic Potential Enegy (EPE)

lgebabased Physics II Sep.1 st, Chap. 19.4 Electic potential Electic potential distibution Euipotential sufaces nnouncements: 1. HW (pat & B) posted. Class Website: http://www.phys.lsu.edu/~jzhang/teaching.html electic potential of chages

W Δ EPE ( EPE EPE ) EPE EPE B B B ΔEPE epesents the incease of electic potential enegy The wok done is eual to the decease in electostatic potential enegy! Chage feels electic foce Field foce does wok on chage F E Foce is consevative W B B u E u F W ΔEPE EPE EPE B B Define the electic field to descibe the field distibution EPE Depend on position

EPE The uantity on the ight is the potential enegy pe unit chage. We call this the Electic Potential, : The electic potential is a scala! It belongs to the field only! The electic potential also descibe the distibution of field When chage is at diffeent position, it has diffeent EPEs, Enegy Chage J C Units? [ olt] [ ] Thus thee ae diffeent electic potential in the space Review of Wok: 1. Wok is not a vecto, but it can be eithe positive o negative: Positive Foce is in the same diection as the motion Negative Foce is in the opposite diection as the motion. If positive wok is done on an object, the object speeds up. 3. If negative wok is done on an object, the object slows down.

19. Electic Potential Diffeence We can talk about the value of the potential at diffeent points in space: Fo example, what is the diffeence in electostatic potential between two points, and B, in an electic field??? E B EPE B EPE W B B So, Δ B W B Why is thee a minus sign??? Let s say the chage at point is positive: If I elease it, which way will it move? It moves down towad B! Since the foce is down and the motion is down, positive wok is done on the chage. Thus, W B is positive. This means that ( B ) is negative, o > B. We say that point is at a highe potential than point B.

Summay : ny chage, stating fom est, will acceleate fom high to low potential enegy egion by electic foce. WB EPE EPEB Positive chages, stating fom est, will acceleate fom egions of high potential and move towad egions of low potential. Negative chages, stating fom est, will acceleate fom egions of low potential and move towad egions of high potential. Δ B W B

Clicke Question 191 Unde an extenal field (E), Which side of space (left o ight) fo a positive chage has a lowe potential enegy? Left E Right 1. Left side. Right side The extenal electic field lines stat fom left to ight and a positive chage moves fom high to low potential enegy egion, thus the ight side has a lowe potential enegy fo a positive chage. Left side 0% 0% Right side

One common object associated with voltages is a battey: Wies Light bulb Notice that the positive chage moves fom highe potential () to lowe potential (). 1.5 olts Battey 1.5 1.5 J C The battey supplies 1.5 Joules of enegy fo evey coulomb of chage. The wod volt also appeas in a unit of enegy: Let s acceleate an electon fom est though a potential diffeence of 1 olt:

1 olt Battey Hole The electon gets acceleated fom low potential to high potential It gains kinetic enegy. The enegy gained by an electon when acceleated though a potential diffeence of 1 olt 1 electon volt 1 e. If I acceleated an electon fom est though a potential diffeence of 50,000, then I know immediately that its kinetic enegy is 50,000 e. Enegy is usually expessed in Joules: 1 e 1.60 10 19 J Just like in a gavitational field, in an electic field, potential enegy (PE) can be conveted into kinetic enegy (KE): Example: Let s bing a small positive test chage fom vey fa away in towad a fixed, positive point chage: s I push the chage in close and close, the epulsive foce on it gets bigge and bigge: F *Thus, I have to do wok on the chage to move it close. The wok I do on the chage goes into inceasing its potential enegy!

Now elease the chage.. F The chage convets its stoed EPE into KE!!! Remembe: The total mechanical enegy of a system must be conseved. 1 1 1 E Tot mv Iω mgh kx EPE KE Tans KE Rot PE Gav PE Elastic PE Electo nd,.if the wok done by nonconsevative foces is zeo, then: E E Tot f Tot o

19.3 The Electic Potential of a Point Chage n electic potential exists aound chages. What is the fom of the potential fo a point chage? Let s place a positive test chage nea a positive fixed point chage: Q F B The electic field ceated by the point chage does wok on the test chage and moves it to the ight B What is the wok done by the field in moving the chage fom to B? Q F k Well, W F d, and the foce is given by Coulomb s Law: But, the foce is not constant as the chage moves fom to B, since the foce depends on. Thus, we have to use calculus and integate the foce ove the distance: Result: W B k Q k Q B

Fom ealie, we know that: B W B k Q B k Q Q If we let B be eally fa away, i.e. B, then B k 0. *This sets ou zeo potential at infinity. Q k Thus, we ae left with:. B is just some abitay distance fom the point chage, so we dop the subscipt: k Q This is the electic potential due to a point chage. We now have 3 euations which kind of look simila: F k Q E k Q k Q Foce between two chages. Electic field of a point chage. Electic potential of a point chage.

lgebabased Physics II Sep.1 st, Chap. 19.4 Electic potential Electic potential distibution Euipotential sufaces nnouncements: 1. HW (pat & B) posted. electic potential of chages Class Website: http://www.phys.lsu.edu/~jzhang/teaching.html

Electic potential due to a point chage if we assume o as : Q k { 0 (positive chage) 0 (negative chage) Electic potential enegy with : W ( ) ab B We now have 3 euations which kind of look simila: F k Q E k Q k Q Foce between two chages. Electic field of a point chage. Electic potential of a point chage.

Clicke Question 19 Which side of space (left o ight) is at a highe potential? Left E Right 1. Left side. Right side The electic field points fom left to ight, and electic field lines stat fom egions of high potential, thus the left side is at a highe potential. 0% 0% Left side Right side

Example 1: Two electons ae initially hold with a distance of 5 x 10 6 m. Then one of them is eleased and move away to infinity, what is the ultimate kinetic enegy of the electon? The consevative electic foce does the wok and incease the kinetic enegy. USE enegy consevation: E i mec 1 mev EPE E i i f mec 1 EPE m v e i f 1 v m v f e f EPE EPE m e f i ( v i 0, EPE f 0) EPE i e k e i k e i v f ke m e i e k m e i ( i 5 10 6 m)

zeo not zeo 0% 0% a k a k a k k j j 4 1 4 1 1 1 4 3 1 Fou identical chages () ae located at the fou cones of a suae with side length a. What is the electic potential at the cente of the suae? a 1. Zeo. Not zeo Clicke Question 19

19.4 Euipotential Sufaces So the potential fom a point chage is k Q E S B S This means the potential is the same in evey diection aound the point chage at a distance away. In 3D, this foms a spheical shell of adius aound the chage. Thus, the electic potential is the same eveywhee on this spheical suface (S ). It is called an euipotential suface. Euipotential sufaces ae sufaces of constant potential. Let s look at anothe euipotential suface (S B ) aound the point chage: We know the electic field lines point eveywhee adially outwad: Notice: The electic field lines ae pependicula to the euipotential sufaces.

E Since S is close to the positive chage than S B, S is at a highe potential than S B. S B S Thus, electic field lines point in the diection of deceasing potential, i.e. they point fom high potential to low potential. Wok? The net electic foce does no wok as a chage moves on an euipotential suface. Why? WB We defined B. But, if we ae on an euipotential suface, then B, and W B 0. O. In ode fo the chage to feel a foce along an euipotential suface, thee must be a component of the field along the suface, but E is eveywhee pependicula to the euipotential suface.

euipotential suface a point chage a chaged staight wie

Fields, Potentials, and Motion of Chages Summay Electic field lines stat on positive chages and end on negative ones. Positive chages acceleate fom egions of high potential towad low potential. Negative chages acceleate fom egions of low potential towad high potential. Euipotential sufaces ae sufaces of constant potential. Electic field lines ae pependicula to an euipotential suface. Electic field lines ae pependicula to the suface of a conducto, thus a conducto is an euipotential suface! Electic field lines point fom egions of high potential towad low potential. Theefoe, positive chages move in the same diection as the electic field points, and negative chages move in the opposite diection of the electic field. The electic foce does no wok as a chage moves on an euipotential suface.

Paallel plate capacito Δs B E 9 6 3 0 The positive plate is at a potential of 9 and the negative plate is at 0. What would the euipotential sufaces look like between the plates? They would be a paallel set of planes! Let the plates be sepaated by a distance Δs. [ Change in voltage] Δ The electic field is then E [ Change in distance] Δs This is called the electic field gadient. Thus, the electic field also has units of [ / m]

19.5 Capacitos Two oppositely chaged conductos sepaated by some small distance. olts We can chage the plates by connecting them to a battey: Q Make this an euality: Q Q The highe the voltage on ou battey, the moe chage we can put on each plate. Thus, C Q C is a new uantity called the Capacitance. Units? C Q [ Chage] [ oltage] C [ Faad] [ F] * faad is a vey lage capacitance. We often use micofaads (μf) and picofaads (pf). 1 10 6 F 1 10 1 F The lage the capacitance, the moe chage it will hold!

Example: What voltage is needed to stoe 7. 10 5 C on the plates of a 6.0 μf capacito? Q olts Q What do we know: Q 7. 10 C 6.0 10 USE the definition of capacitance: 5 Q 7. 10 Q C so 1 6 C 6 10 5 6 C F Reality:

Dielectics We can fill the space between the plates with some insulating mateial, say ai, oil, pape, ubbe, plastic, etc. Dielectic This mateial is called a dielectic. E E o So what effect does the dielectic have on the field between the plates? Since the dielectic is an insulato, the chages in it aen t fee to move, but they can sepaate slightly within each atom: Each one of these atoms now poduces a small intenal electic field which points in the opposite diection to the field between the plates: Thus, the net electic field between the plates is educed by the dielectic. The eduction of the field is epesented by the following: E o is the field without the dielectic E is the field with the dielectic κ E o E κ is called the dielectic constant, and it must be geate than 1.

κ E o E Since κ is the atio of two electic fields, it s unitless. Mateial κ acuum 1 i 1.00054 Wate 80.4 The lage κ is, the moe it educes the field between the plates! E o κ d Let s say the plates have suface aea and ae sepaated by a distance d. E 1 Eo d ε o κ d E κ d σ κ o ε o ε But, C, o so ε o κ C d

Capacitos stoe chage what about enegy? EPE Stoed 1 1 C Ed and C ε oκ, so d EPE Stoed 1 ε oκ d ( E d ) Reaange this: EPE 1 1 κε E ( d) κε E o o (ol) olume between the plates EPE ol 1 Enegy Density κε o E Units? Enegy olume J m 3 *This expession holds tue fo any electic fields, not just fo capacitos!