HONORS EXAMINATION IN GEOMETRY, 2013
(1) If C is a closed curve contained inside a disk of radius r in R2, prove that there exists a point p ∈ C where the curvature satisfies |κg(p)| ≥ 1/r. What analogous statement is true if C is an n-dimensional compact Riemannian manifold in Rn+1 contained inside an n-dimensional sphere of radius r? Is this result still true if C is a compact Riemannian manifold of any dimension in Rn+1 contained inside an n-dimensional sphere of radius r?
(2) Prove that Sn (the n-dimensional sphere of radius 1) has constant sectional curvature equal to 1.
(3) Consider the sphere and the cylinder:
S2 = {(x, y, z) ∈ R3| x2 + y2 + z2 = 1},
C = {(x, y, z) ∈ R3| x2 + y2 = 1}.
Let f: (S2- {(0, 0, 1),(0, 0, -1)}) → C denote the function that sends each point of the domain to the closest point in C. Prove that f is "equiareal" which means that it takes any region of the domain to a region of the same area in C.
(4) Let M2 ⊂ R3 be a ruled surface. This means that for all p ∈ M2 there exists a line in R3 through p which is entirely contained in M2. Explain why the Gauss curvature of M2 is non-positive.
(5) Let M = {(x, y, z) ∈ R3| z = x2 + y2 - 1}, and let C be the circle along which M intersects the xy-plane.
(a) The parallel transport once around C has the effect of rotating the tangent space T(1,0,0)M by what angle?
(b) What is the integral of the Gauss curvature over the region of M that is bounded by C?
(6) Let M be a Riemmanian manifold, and let f: M → R be a smooth function. Define gradf to be the unique vector field on M such that for all p ∈ M and all X ∈ TpM, ((gradf)(p), X) = dfp(X) . If gradf has constant norm on M, prove that all integrals curves of gradf are minimizing geodesics.
(7) Let M be a Riemannian manifold. A "ray" in M is define as a geodesic γ: [0, ∞) → M which is minimizing between any pair of points of its image. Suppose that p ∈ M and {Vn} → V is a convergent sequence of vectors in TpM. Suppose that for each n, the geodesic in the direction of Vn is a ray. Prove that the geodesic in the direction of their limit, V, is a ray.
(8) A Riemannian manifold M is called "homogeneous" if for every pair p, q ∈ M there exists an isometry f: M → M such that f(p) = q. A Riemannian manifold M is called a "symmetric space" if for every p ∈ M there exists an isometry f: M → M such that f(p) = p and dfp: TpM → TpM equals the antipodal map V |→ -V . Prove that every complete symmetric space is homogeneous. What examples of symmetric and homogeneous spaces can you think of?
(9) What can you conclude about a surface M2 ⊂ R3 for which the image of the Gauss map is contained in a great circle of S2?
(10) Let Sn(r) denote the n-dimensional sphere of points in Rn+1 at distance r from the origin. Let m, n ≥ 1 be integers and let s, r > 0 be real numbers. The product manifold, M = Sm(r) × Sn(s), can be identified with the following subset of Rm+n+2:
M = {(p, q) ∈ Rm+1 ⊕ Rn+1 ≅ Rm+n+2 | p ∈ Sm(r), q ∈ Sn(s)},
and therefore M inherits a natural "product" metric from the ambient Euclidean space. Under what conditions on {m, n, s, r} (if any) will M have...
(a) ...positive sectional curvature?
(b) ...positive Ricci curvature?
(c) ...positive scalar curvature?
(d) ...constant Ricci curvature?