Lecture 3 - Lie Groups and Geometry

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Lecture 3 - Lie Groups and Geometry July 29, 2009 1 Integration of Vector Fields on Lie Groups Let M be a complete manifold, with a vector field X. A time-dependent family of diffeomorphisms ϕ t : M M is called the flow of X if, for any function f and any time τ, we have d f ( ( ϕ t ϕ 1 τ (p) )) = X p (f) (1) dt t=τ The path t ϕ t (p) is called the flow line, or integral curve, of X through p. Now let G be a Lie group, and assume X is a left-invariant vector field. The flow line of X through e is, by definition, the path t Exp(tX). Moving this by left-translation to any point a G, the flow line through a is Thus the flow of X is therefore t L a Exp(tX). ϕ t (a) = a Exp(tX) = R Exp(tX) a. Thus ϕ t = R Exp(tX), so that left-invariant vector fields integrate out to smooth families of right translations. Similarly right-invariant fields integrate out to left translations. 2 Riemannian Geometry on Lie Groups 2.1 Left-invariant metrics If g e is an inner product on the tangent space at the identity, we can extend g e to a metric g on G by left translation. That is, if a G and X a, Y a are vectors at a, then g(x a, Y a ) g(l a 1 X a, L a 1 Y a ). (2) 1

Note that a left-invariant metric g is constant when evaluated against left-invariant fields Y and Z. Thus (L X g) (Y, Z) = g([x, Y ], Z) g(y, [X, Z]) (3) Note that [X, W ] = 0 whenever X is right-invariant and W is left-invariant; this is from an exercise from a previous lecture. When g is a left-invariant metric, then right-invariant fields are Killing. 2.2 Bi-invariant metrics A metric is called bi-invariant if it is both left- and right-invariant. If X is a left-invariant field and g is a right-invariant metric, then L X g = 0. Therefore if g is bi-invariant and X, Y, Z are left-invariant, then 0 = g([x, Y ], Z) + g(y, [X, Z]). () Most Lie groups do not have bi-invariant metrics, although all compact Lie groups do. From (3) it is easy to see that semi-simple Lie groups have a bi-invariant metric, as the Killing form automatically satisfies () and is definite on semi-simple algebras. 2.3 Connection and curvature in a bi-invariant metric If a Lie group has a bi-invariant metric, the Lie algebra entirely determines the Riemannian structure. If g is left-invariant and X 1,..., X n are left-invariant fields that form an orthonormal basis at e (and therefore at all points), the Koszul formula reduces to 2 Xi X j, X k = [X i, X j ], X k [X j, X k ], X i + [X k, X i ], X j If g is bi-invariant, by () the last 2 terms cancel and we get 2 Xi X j, X k = [X i, X j ], X k, so that Using the Jacobi identity and (), we easily find Xi X j = 1 2 [X i, X j ]. (5) Rm(X, Y ) Z = 1 [[X, Y ], Z] Rm(X, Y ) Z, W = 1 [X, Y ], [W, Z] sec(x, Y ) = 1 [X, Y ] 2 X 2 Y 2. (6) Sectional curvatures are therefore all non-negative. 2

3 Examples 3.1 The 3-sphere Again the fundamental example is the 3-sphere. We have seen that S 3 is a Lie group in two equivalent ways, as the group of unit quaternions, and as the matrix group SU(2). We have seen that its Lie algebra has two equivalent formulations, as the Lie algebra of purely imaginary quaternions, and as the span of i times the Pauli matrices. In the metric inherited from R, the tangent vectors {i, j, k} T 1 S 3 are orthonormal. It is a simple matter to verify that the inherited metric is bi-invariant. Letting v i, v j, and v k be the left-invariant fields on S 3 with v i (1) = i, v j (1) = j and v k (1) = k, then with the Lie algebra structure [v i, v j ] = 2v k and cyclic permutations, we compute the connections vi v i = vj v j = vk v k = 0 the curvatures and the sectional curvatures vi v j = v k vj v k = v i vk v i = v j, Rm(v i, v j )v k = 0 Rm(v i, v j )v j = v i etc., (7) (8) sec(v i, v j ) = 1, sec(v j, v k ) = 1, sec(v i, v k ) = 1. (9) As we already know to be the case, S 3 has constant curvature +1. 3.2 The Hopf Fibration Note that H is isomorphic to C C, for instance by writing q = a + bi + cj + dk as q = (a + bi) + (c + di)j. (10) Let X L, Y L, and Z L be the vector fields obtained by left-translating the vectors i, j, k T 1 S 3. The corresponding integral curves through 1 are t e it, t e jt, and t e kt. Lefttranslating to any q S 3, the flow ϕ t : S 3 S 3 of X L is ϕ t = R e it. (11) Through a point q = a + bi + cj + dk, this is ϕ t (q) = q e it = e it (a + bi) + e it (c + di)j. (12) 3

Viewing this via stereographic projection from 1, it is easy to see that this is a left-handed (clockwise) screw motion (assuming S 3 is oriented with the outward normal). If i is extended instead to a right-invariant field X R, then the flow is q e it q = e it (a + bi) + e it (c + di)j (13) which is a flow by left-translations, and a right-handed (counterclockwise) screw motion. 3.3 Nilpotent groups The set of upper-triangular n n matrices with 1 s along the diagonal is a nilpotent group under matrix multiplication. From its importance in physics, the group of upper-triangular 3 3 matrices H = 1 x z 0 1 y 0 0 1 x, y, z R is given the name the Heisenberg group. Of course it it topologically just R 3. Its Lie algebra consists of the strictly upper-triangular matrices h = span R P =, Q =, h = (15) where we see 0 1 0 0 0 1 0 0 1 (1) [P, Q] = h, [P, h] = 0, [Q, h] = 0. (16) With the left-invariant metric, the Koszul formula gives and we compute P P = 0 P Q = 1 2 h Q P = 1 2 h QQ = 0 hp = 1 2 Q h Q = 1 2 P P h = 1 2 Q Qh = 1 2 P hh = 0 (17) Rm(P, Q)Q = 3 P Rm(P, h)h = 1 P Rm(Q, h)h = 1 Q Rm(Q, P )P = 3 Q (18) Rm(h, P )P = 1 h Rm(h, Q)Q = 1 h with all other curvatures, such as Rm(P, Q)h, being zero. Therefore sec(p, Q) = 3, sec(p, h) = 1, sec(q, h) = 1, (19) so H has both positive and negative sectional curvatures. We easily compute 1 2 0 0 Ric = 0 1 2 0 (20) 1 0 0 2 so scalar curvature is negative: R = 1 2.

Exercises 1) Let G be a connected Lie group with a bi-invariant metric, and Lie algebra g. Prove that the representation Ad : G GL(g) reduces to a representation Ad : G SO(T e g). 2) Identifying the Heisenberg group H with R 3, what are expressions (in (x, y, z)-coordinates) of the left- and right-invariant vector fields that extend P, Q, and h? 3) Is the metric on H that was given in the text a bi-invariant metric? ) Let V be the infinite-dimensional vector space of polynomials in x. Let λ be a constant. Prove that sending P to the operator λ d dx, Q to the operator that multiplies by x, and h to the operator that multiplies by λ, is a representation of H on V (in physics normally λ = i ). 5) The simplest non-trivial Lie algebra has two generators A and B with [A, B] = B. Obviously it is nilpotent. What is the corresponding Lie Group G? Given the leftinvariant metric with A = B = 1 and A, B = 0, what is the curvature? Prove that G has no bi-invariant metric. 5

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