A cylinder in a magnetic field (Jackson)

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Problem 1. A cylinder in a magnetic field (Jackson) A very long hollow cylinder of inner radius a and outer radius b of permeability µ is placed in an initially uniform magnetic field B o at right angles to the field. (a) For a constant field B o in the x direction show that A z = B o y is the vector potential. This should give you an idea of a convenient set of coordinates to use. Remark: See Wikipedia for a list of the vector Laplacian in all coordinates. Most often the vector Laplacian is used if the current is azimuthal and solutions may be looked for with A φ 0 and A r = A θ = 0 (or A ρ = A z = 0 in cylindrical coordinates). This could be used for example in Problem 3. Similarly if the current runs up and down, with A z 0 and A ρ = A φ = 0, so that B = (B x (x, y, z), B y (x, y, z), 0) is independent of z, then the vector Laplacian in cylindrical coordinates 2 A z is a good way to go. (b) Show that the magnetic field in the cylinder is constant ρ < a and determine its magnitude. (c) Sketch B / B o at the center of the as function of µ for a 2 /b 2 = 0.9, 0.5, 0.1 for µ > 1. 1

Problem 2. Helmholtz coils (Jackson) Consider a compact circular coil of radius a carrying current I, which lies in the x y plane with its center at the origin. (a) By elementary means compute the magnetic field along the z axis. (b) Show by direct analysis of the Maxwell equations B = 0 and B = 0 that slightly off axis near z = 0 the magnetic field takes the form B z σ 0 + σ 2 ( z 2 1 2 ρ2), B ρ σ 2 zρ, (1) ( where σ 0 = (Bz) o and σ 2 = 1 2 Bz o are the field and its z derivatives evaluated at the 2 origin. For later use give σ 0 and σ 2 explictly in terms of the current and the radius of the loop. z 2 ) Remark: The magnetic field near the origin satisfies B = 0, so B = 0. We say it is harmonic function 1. Because the function is harmonic, the taylor series of B on the z axis, is sufficient to determine the taylor series close to the z axis. (c) Now consider a second identical coil (co-axial with the first), having the same magnitude and direction of the current, at a height b above the first coil, where a is the radii of the rings. With the coordinate origin relocated at the point midway between the two centers of the coils, determine the magnetic field on the z-axis near the origin as an expansion in powers of z to z 4. Use mathematica if you like. You should find that the coefficient of z 2 vanishes when b = a Remark For b = a the coils are known as Helmholtz coils. For this choice of b the z 2 terms in part (c) are absent. (Also if the off-axis fields are computed along the lines of part (b), they also vanish.) The field near the origin is then constant to 0.1% for z < 0.17 a. 1 This means that B can be written B = ψ where 2 ψ = 0 2

Problem 3. A magnetized sphere and a circular hoop A uniformly magnetized sphere of radius a centered at origin has a permanent total magnetic moment m = m ẑ pointed along the z-axis (see below). A circular hoop of wire of radius b lies in the xz plane and is also centered at the origin. The hoop circles the sphere as shown below, and carries a small current I o (which does not appreciably change the magnetic field). The direction of the current I o is indicated in the figure. z I o y x (a) Determine the bound surface current on the surface of the sphere. (b) Write down (no long derivations please) the magnetic field B inside and outside the magnetized sphere by analogy with the spinning charged sphere disucssed in class. (c) Show that your solution satisfies the boundary conditions of magnetostatics on the surface of the sphere. (d) Compute the net-torque on the circular hoop. Indicate the direction and interpret. 3

Problem 4. Energy of a wire and rectangle (Jackson) (a) Consider an infinitely long straight wire carying a current I in the z direction. Use the known mangetic field of this wire, and the integral form of B = A B ds = dl A (2) S to show that the vector potential for an infinite current carrying wire in the Coulomb gauge is A z = (I/c) log ρ + const (3) 2π Check that the Coulomb gauge condition is satisfied. (b) Now consider a flat right rectangular loop carrying a constant current I 1 that is placed near a long straight wire carrying a constant current I 2. The rectangular loop is oriented so that its center is a perpendicular distance d from the wire; the sides of length a are parrel to the wire and the sides of length b make an angle α with the plane containing the wire and the loops center (the dashed line below). In the schematic diagram below, the current I 2 in the long wire flows out of page. The orientation of I 1 is also indicated, i.e. the current lower edge of the rectangle (of length a) also comes out of the page. α b/2 d Show that the interaction energy W 12 = I 1 c F 1 (4) (where F 1 is the magnetic flux from I 2 through the rectangular circuit carrying I 1 ), is W 12 = ai [ ] 1I 2 4d 2 4πc ln + b 2 + 4db cos α (5) 2 4d 2 + b 2 4db cos α 4

(c) Using energy considerations calculate the force between the loop and the wire for constant currents. (d) Check that for large distances d a, b the force computed in the previous sub-question agrees with the appropriate formula for a dipole in an external field. (e) Show that when d a, b the interaction energy reduces to W 12 = m B, where m is the magnetic moment of the loop. Explain the sign. 5

Problem 5. exam) A half submerged metal sphere (UIC comprehensive A very light neutral hollow metal spherical shell of mass m and radius a is slightly submerged by a distance b a below the surface of a dielectric liquid. The liquid has mass density ρ and electrical permitivity ɛ. The liquid sits in air which has negligble density ρ o ρ, and the permitivity of air is approximately unity, ɛ air 1. The pressure at the air liquid interface is p 0. Recall that stress tensor of an ideal fluid at rest is T ij = p(z)δ ij where p(z) is the pressure as a function of z. Air Liquid b (a) Use the formalism of stress tensor to show that p(z) increases as p = p 0 + ρgh, where h = z is the depth below the surface, z < 0. Here p 0 is the pressure at the surface. Hint: what is the net force per volume for a static fluid? (b) Use the formalism of stress tensor to prove that the boyancy force (for any shape) equals the difference in weight of the displaced fluid volume V and the corresponding weight of the air: F = (ρ ρ o )g V ρg V. (c) (Optional) Determine the boyancy force in this case. Now a charge Q is added to the sphere, and the sphere becomes half submerged. (d) Determine the potential, and the electrostatic fields E and D, in the top and lower halves of the sphere. Verify that all the appropriate boundary conditions are satisfied. (e) What is the surface charge density on the top and lower halves of the sphere? (f) Determine the electrostatic attractive force as a function of Q, a, and ɛ. What must Q be for the sphere to be half submerged? Make all reasonable approximations. Express your approximate result in terms of ρ, g, a, ɛ. Use dimensional reasoning to show that for a light sphere, Q = ρga 5 function of ɛ. (6) (g) (Optional) Estimate Q numerically for typical liquids. 6

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