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Math F665: Final Exam Due: TBA 1. The conversion formula E = mc 2 for rest mass allows one to specify mass as energy. In particle physics, a standard measure of energy is a “gigaelectronvolt”. Recall that the volt is the unit of electric potential: the energy required to move a coulomb of charge from a point with voltage V1 to a point with voltage V2 is V2 − V1 . An electron volt is the energy in Joules required to move an electron accross a single volt of potential, and a gigaelectronvolt (GeV) is the energy needed to move 109 electrons over a volt of potential. a) Recalling that the charge of an electron is 1.6 × 10−19 coulombs, show that a mass of 1GeV is equivalent to 1.8 × 10−27 kg. b) A muon has a mass of 0.106 GeV and a rest frame half life of 2.19 × 10−6 seconds. It is moving in a circular particle accelerator, 1 km in diameter, with energy 1000 GeV. How far around the circle to you expect it will travel? 2. The rules for computing Cristoffel symbols, parallel transport, covariant derivatives, and so forth work equally well for Riemannian metrics (i.e. metrics g ab with signature (+, +, . . . , +)) and in any dimension. Consider the Riemannian metric dϕ2 + sin2 ϕdθ 2 , which is the metric for the sphere in polar coordinates. Here, ϕ ∈ (0, π) and θ ∈ (−π, π). 1. Show that curves of constant θ are geodesics, and that the only line of constant ϕ that is a geodesic is the curve ϕ = 0. 2. In this coordinate system, take the vector X = [1, 0] and parallel transport it around a line of constant ϕ. What is the resulting vector? Your answer should depend on ϕ. 3. GR: 5.7 4. Consider a metric of the form ds 2 = dt 2 − t 2a1 dx12 − t 2a2 dx22 − t 2a3 dx32 . (1) Find necessary and sufficient conditions on the numbers a1 , a2 and a3 such that the metric is a solution of the vacuum Einstein equations. 5. Consider Einstein’s vaccum equation with a cosmological constant Λ: G ab = −Λg ab . Find the analog of the Schwarzschild solution for Λ ≠ 0. The equation of motion for geodesics can be written in the form p2 = f (u) as at the bottom of page 112. What is f (u) in this case? 6. GR 8.4 And more to come! See the next page for one more... Math F665: Final Exam Due: TBA 7. In this problem, we use units where c = 1. Maxwell’s equations for the potential A a read ◻A a − dδA a = J a = (є0 )−1 [ρ, − j1 , − j2 , − j3 ] where ρ is the charge density, j i is the electric current, and J a is the current 4-vector expressed as a 1-form. Our goal is, given J a , to find a solution of Maxwell’s equations. We will use the fact that the inhomogeneous wave equation ◻ϕ = f (2) is well posed with initial data ϕ at time x 0 = 0 and ∂0 ϕ at x 0 = 0. a) Explain why the conservation of charge condition δJ = ∇a J a = 0 is a necessary condition for there to exist a solution of Maxwell’s equations. b) We have already seen that if A a solves Maxwell’s equations for a given 4-current, then so does A a +(d f )a for any function f a . Hence Maxwell’s equations aren’t well-posed: there’s more than one solution! We can reduce the equations to a well-posed problem by a technique known a gauge fixing. The gauge we’ll use is the so-called Lorentz gauge defined by δA = 0 where δA = ∂0 A0 − ∂1 A1 − ∂2 A2 − ∂3 A3 . That is, we will seek a solution A satisfying δA = 0. I guess there’s no real question in part b). Carry on to part c)! c) Suppose that A a solves Maxwell’s equations. Let f be a function solving the inhomogeneous wave equation ◻ f = −δA with any initial data f ∣x0 =0 and ∂0 f ∣x0 =0 . Show that  a = A a + (d f )a is a solution of Maxwell’s equations for the same 4-current that also satisfies δ  = 0. Now explain why if there exists a solution of Maxwell’s equations, then there also exists a solution in Lorentz gauge. d) Given the analogy with the wave equation, the right initial data for Maxwell’s equations ought to consist of the value of A a at x 0 = 0 and ∂0 A a at x 0 = 0. But these equations overspecify the initial data. Suppose A a is a solution of Maxwell’s equations. Show that −∆A0 + ∂1 (∂0 A1 ) + ∂2 (∂0 A2 ) + ∂3 (∂0 A3 ) = ρ/є0 (3) and that this can be computed entirely from the initial data A a at x 0 = 0 and ∂0 A a at x 0 = 0. We will call equation (3) the charge constraint. e) Suppose α a and β a are initial data that satisfy the Lorentz constraint β0 − ∂1 α1 − ∂2 α2 − ∂3 α3 = 0 (4) −∆α0 + ∂1 (β1 ) + ∂2 (β2 ) + ∂3 (β3 ) = ρ/є0 . (5) and satisfy the charge constraint Let the components A a be the solutions of the four inhomogeneous wave equations ◻A a = J a 2 (6) Math F665: Final Exam Due: TBA with the initial conditions A a ∣x 0 =0 = α a ∂0 A a ∣x 0 =0 = β a . Show that (a) δA = 0 at x 0 = 0. (b) ∂0 δA = 0 at x 0 = 0. (You’ll need to use the charge constraint here along with the fact that A a solves the wave equation and δA = 0 at x 0 = 0 ). (c) ◻δA = 0 on all of spacetime. (You’ll need to use charge conservation here). Conclude that δA = 0 on all of spacetime. Conclude further that A is a solution of Maxwell’s equations in Lorentz gauge. f) In the usual initial problem for Maxwell’s equations one starts with an electric field satisfying ∇i E i = ρ/є0 and a magnetic field satisfying ∇i B i = 0. Show that given such a fields, one can find initial data α a and β a satisfying the Lorenz constraint and the charge constraint that generate these fields. Hence, given a current 4-vector and an initial choice of E i and B i one can solve Maxwell’s equations. You are welcome to assume that the scalar Poisson equation ∆ϕ = f is well posed. (It is if f decays sufficiently fast and we seek a solution that decays to zero at infinity). 3