Electromagnetic Field Theory: A Problem Solving Approach Part 28

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Đánh giá Electromagnetic Field Theory: A Problem Solving Approach Part 28
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Problems 245 36. Charge maintained at constant density Po at x = 0 is carried away by a conducting fluid travelling at constant velocity Ui. and is collected at x = 1. + Vo - .ross-sectional area A P =Po 1 r 0 x I (a) What are the field and charge distributions within the fluid if the electrodes are at potential difference V0 ? (b) What is the force on the fluid? (c) Repeat (a) and (b) if the voltage source is replaced by a load resistor RL. 37. A dc voltage has been applied a long time to an open circuited resistive-capacitive structure so that the voltage and current have their steady-state distributions as given by (44). Find the resulting discharging transients for voltage and current if at t = 0 the terminals at z = 0 are suddenly: (a) open circuited. Hint: sinh a(z -1) sin (m) I sinh at +r I [a'+ (mir/l) ] m dz (b) Short circuited. Hint: JIcosh a(z - ) sin s)d((2n S21 1)7 (2n + dz= cosh al 21[a2+ [(2n•21)r 38. At t = 0 a distributed resistive line as described in Section 3-6-4 has a step dc voltage Vo applied at z = 0.The other end at z = I is short circuited. (a) What are the steady-state voltage and current distributions? (b) What is the time dependence of the voltage and current during the transient interval? Hint: i mwi· oa· sinh a(z -1) sin (-i-) dz = 1I{a2 - [ mw sinh al msinh at + (Mr1)2] 246 Polarizationand Conduction 39. A distributed resistive line is excited at z = 0 with a sinusoidal voltage source v(t) = Vo cos wt that has been on for a long time. The other end at z = 1 is either open or short circuited. (a) Using complex phasor notation of the form v(z, t) = Re (i^(z)eM d) find the sinusoidal steady-state voltage and current distributions for each termination. (b) What are the complex natural frequencies of the system? (c) How much time average power is delivered by the source? 40. A lossy dielectric with permittivity e and Ohmic conductivity ar is placed between coaxial cylindrical electrodes with large Ohmic conductivity oc and length 1. What is the series resistance per unit length 2R of the electrodes, and the capacitance C and conductance G per unit length of the dielectric? Section 3.7 41. Two parallel plate electrodes of spacing I enclosing a dielectric with permittivity e are stressed by a step voltage at t = 0. Positive charge is then injected at t = 0 from the lower electrode with mobility At and travels towards the opposite electrode. X I 0-- -I sit) 0 i s(t) -- t------------- Problems 247 (a) Using the charge conservation equation of Section 3-2-1, show that the governing equation is aE -+pE at aE J(t) ax e where J(t) is the current per unit electrode area through the terminal wires. This current does not depend on x. (b) By integrating (a) between the electrodes, relate the current J(t) solely to the voltage and the electric field at the two electrodes. (c) For space charge limited conditions (E(x = 0)= 0), find the time dependence of the electric field at the other electrode E(x = 1, t) before the charge front reaches it. (Hint: With constant voltage, J(t) from (b) only depends on E(x = 1, t). Using (a) at x = I with no charge, aE/8x = 0, we have a single differential equation in E(x = 1,t).) (d) What is the electric field acting on the charge front? (Hint: There is no charge ahead of the front.) (e) What is the position of the front s(t) as a function of time? (f) At what time does the front reach the other electrode? (g) What are the steady-state distribution of potential, electric field, and charge density? What is the steady-state current density J(t -• )? (h) Repeat (g) for nonspace charge limited conditions when the emitter electric field E(x = 0) = Eo is nonzero. 42. In a coaxial cylindrical geometry of length L, the inner electrode at r = Ri is a source of positive ions with mobility /t in the dielectric medium. The inner cylinder is at a dc voltage Vo with respect to the outer cylinder. E,(r = Ri) = E i vo (a) The electric field at the emitter electrode is given as Er(r= Ri) = Ei. If a current I flows, what are the steady-state electric field and space charge distributions? (b) What is the dc current I in terms of the voltage under space charge limited conditions (Ei = 0)? Hint: f [r2 -R r ] 2 dr= [r 2 -R ], 2 -R, cos Ri \r 248 Polarizationand Conduction (c) For what value of Ei is the electric field constant between electrodes? What is the resulting current? (d) Repeat (a)-(b) for concentric spherical electrodes. Section 3.8 43. (a) How much work does it take to bring a point dipole from infinity to a position where the electric field is E? (a) P P p (d) (b) (c) (b) A crystal consists of an infinitely long string of dipoles a constant distance s apart. What is the binding energy of the 3 crystal? (Hint: Y ,,ll/n 1.2.) 1 (c) Repeat (b) if the dipole moments alternate in sign. (Hint: _0-i(-1)"/n s = - 0 .90 .) (d) Repeat (b) and (c) if the dipole moments are perpendicular to the line of dipoles for identical or alternating polarity dipoles. 44. What is the energy stored in the field of a point dipole with moment p outside an encircling concentric sphere with molecular radius R? Hint: Jcos2 0 sin 0 dO = sin Cos 3 d = - cos 0 (sin • + 2) 45. A spherical droplet of radius R carrying a total charge Q on its surface is broken up into N identical smaller droplets. (a) What is the radius of each droplet and how much charge does it carry? (b) Assuming the droplets are very far apart and do not interact, how much electrostatic energy is stored? _· Problems 249 (c) Because of their surface tension the droplets also have a constant surface energy per unit area ws. What is the total energy (electrostatic plus surface) in the system? (d) How much work was required to form the droplets and to separate them to infinite spacing. (e) What value of N minimizes this work? Evaluate for a water droplet with original radius of 1mm and charge of 106 coul. (For water w, ý 0.072 joule/m2.) 46. Two coaxial cylinders of radii a and b carry uniformly distributed charge either on their surfaces or throughout the volume. Find the energy stored per unit length in the z direction for each of the following charge distributions that have a total charge of zero: (a) Surface charge on each cylinder with oa 2 1ra - -ob2rrb. (b) Inner cylinder with volume charge Pa and outer cylinder with surfacecharge ob where o'b2rb = -Palra. (c) Inner cylinder with volume charge Pa with the region between cylinders having volume charge Pb where para = -pbO(b 2 -a 2 ). 47. Find the binding energy in the following atomic models: (a) (b) (a) A point charge Q surrounded by a uniformly distributed surface charge - Q of radius R. (b) A uniformly distributed volume charge Q within a sphere of radius RI surrounded on the outside by a uniformly distributed surface charge - Q at radius R 2 . 48. A capacitor C is charged to a voltage V 0 . At t = 0 another initially uncharged capacitor of equal capacitance Switch closes at t = 0 R =V v1 (t= 0) Iv Resistance of connecting wires ) C =0 , (t=0) C is 250 Polarizationand Conduction connected across the charged capacitor through some lossy wires having an Ohmic conductivity a, cross-sectional area A, and. total length 1. (a) What is the initial energy stored in the system? (b) What is the circuit current i and voltages vi and v2 across each capacitor as a function of time? (c) What is the total energy stored in the system in the dc steady state and how does it compare with (a)? (d) How much energy has been dissipated in the wire resistance and how does it compare with (a)? (e) How do the answers of (b)-(d) change if the system is lossless so that o = co? How is the power dissipated? (f) If the wires are superconducting Section 3-2-5d showed that the current density is related to the electric field as where the plasma frequency w, is a constant. What is the equivalent circuit of the system? (g) What is the time dependence of the current now? (h) How much energy is stored in each element as a function of time? (i) At any time t what is the total circuit energy and how does it compare with (a)? E q+angle -q p=qd Section 3.9 49. A permanently polarized dipole with moment p is at an 6 to a uniform electric field E. (a) What is the torque T on the dipole? (b) How much incremental work dW is necessary to turn the dipole by a small angle dO? What is the total work required to move the dipole from 0 =0 to any value of 0? (Hint: dW= TdO.) (c) In general, thermal agitation causes the dipoles to be distributed over all angles of 0. Boltzmann statistics tell us that the number density of dipoles having energy W are n = no eWAT where no is a constant. If the total number of dipoles within a sphere of radius R is N, what is no? (Hint: Let u= (pE/kT) cos 0.) (d) Consider a shell of dipoles within the range of 0 to O+dO. What is the magnitude and direction of the net polarization due to this shell? I Problems 251 (e) What is the total polarization integrated over 0? This is known as the Langevin equation. (Hint: J ue" du = (u - 1)e".) (f) Even with a large field of E 106 v/m with a dipole composed of one proton and electron a distance of 10 A (10-9 m) apart, show that at room temperature the quantity (pE/kT) is much less than unity and expand the results of (e). (Hint: It will be necessary to expand (e) up to third order in (pE/kT). (g) In this limit what is the orientational polarizability? 50. A pair of parallel plate electrodes a distance s apart at a voltage difference Vo is dipped into a dielectric fluid of permittivity e. The fluid has a mass density pm and gravity acts downward. How high does the liquid rise between the plates? v+0 IiýEo Depth d DetP . h 0 . - -. . . . -- .. ... - ---:- •- . 51. Parallel plate electrodes at voltage difference Vo enclose an elastic dielectric with permittivity e. The electric force of attraction between the electrodes is balanced by the elastic force of the dielectric. (a) When the electrode spacing is d what is the free surface charge density on the upper electrode? <-- - ! *.·:::.:::::::: . - V 7~+ V 252 Polarizationand Conduction (b) What is the electric force per unit area that the electrode exerts on the dielectric interface? (c) The elastic restoring force per unit area is given by the relation d do FA= Yln- where Y is the modulus of elasticity and do is the unstressed (Vo=0) thickness of the dielectric. Write a transcendental expression for the equilibrium thickness of the dielectric. (d) What is the minimum equilibrium dielectric thickness and at what voltage does it occur? If a larger voltage is applied there is no equilibrium and the dielectric fractures as the electric stress overcomes the elastic restoring force. This is called the theory of electromechanical breakdown. [See K. H. Stark and C. G. Garton, Electric Strength of Irradiated Polythene, Nature 176 (1955) 1225-26.] 52. An electret with permanent polarization Poi, and thickness d partially fills a free space capacitor. There is no surface charge on the electret free space interface. Lj eO Area A A l V0 1' (a) What are the electric fields in each region? (b) What is the force on the upper electrode? 53. A uniform distribution of free charge with density po is between parallel plate electrodes at potential difference Vo. (a) What is the energy stored in the system? (b) Compare the capacitance to that when Po = 0. (c) What is the total force on each electrode and on the volume charge distribution? (d) What is the total force on the system? 54. Coaxial cylindrical electrodes at voltage difference Vo are partially filled with a polarized material. Find the force on this ·-- C~-------------- Problems 253 material if it is (a) permanently polarized as Poir; (b) linearly polarized with permittivity E. -1- Vo -I .- ~----- 00 55. The upper electrode of a pair at constant potential difference Vo is free to slide in the x direction. What is the x component of the force on the upper electrode? ID S Vd Depth d 56. A capacitor has a moveable part that can rotate through the angle 0 so that the capacitance C(O) depends on 0. (a) What is the torque on the moveable part? (b) An electrostatic voltmeter consists of N+ 1 fixed pieshaped electrodes at the same potential interspersed with N plates mounted on a shaft that is free to rotate for - 00 < 0 < 00. What is the capacitance as a function of 0? (c) A voltage v is applied. What is the electric torque on the shaft? (d) A torsional spring exerts a restoring torque on the shaft T,= -K(O- ,) where K is the spring constant and 0s is the equilibrium position of the shaft at zero voltage. What is the equilibrium position of the shaft when the voltage v is applied? If a sinusoidal voltage is applied, what is the time average angular deflection <0>? (e) The torsional spring is removed so that the shaft is free to continuously rotate. Fringing field effects cause the 254 Wm Polarizationand Conduction ( WM C() = 2EoNR s 2 (Oo - 0) 0 7 2r 0 •" 2• 0 capacitance to vary smoothly between minimum and maximum values of a dc value plus a single sinusoidal spatial term C(0) = [Cmax+ Cmin] +[•[Cm.x -Cmin] cos 20 A sinusoidal voltage Vo cos wt is applied. What is the instantaneous torque on the shaft? (f) If the shaft is rotating at constant angular speed w,. so that 0 -at + 8 where 8 is the angle of the shaft at t = 0, under what conditions is the torque in (e) a constant? Hint: sin 20 cos wo = sin 20(1 +cos 2wt) = sin'20 +1 [sin (2(wt + 0))- sin (2(wt - 0))] (g) A time average torque To is required of the shaft. What is the torque angle 8? (h) What is the maximum torque that can be delivered? This is called the pull-out torque. At what angle 8 does this occur? Section 3-10 57. The belt of a Van de Graaff generator has width w and moves with speed U carrying a surface charge of up to the spherical dome of radius R. ____~I_
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