Problems

b. Show that there are no submersions of compact manifolds into Eu-clidean spaces.

9 Show that every smooth real function on a compact manifold has at least two critical points.

10 LetM be a compact manifold of dimensionnand letf :M → Rⁿ be smooth. Prove thatfhas at least one critical point.

11 Let p(z) = z^m +a_m−1z^m−1 +· · ·+a₀ be a polynomial with complex coefficients and consider the associated polynomial mapC → C. Show that this map is a submersion out of finitely many points.

12 (Generalized inverse function theorem.) Letf :M →N be a smooth map which is injective on a compact submanifoldP of M. Assume that df_p : T_pM →T_f(p)N is an isomorphism for everyp∈P.

a. Prove thatf(P)is a submanifold ofN and thatf restricts to a diffeo-morphismP →f(P).

b. Prove that indeedf maps some open neighborhood ofP in M dif-feomorphically onto an open neighborhood of f(P) in N. (Hint: It suffices to show thatf is injective on some neighborhood ofP; if this is not the case, there exist sequences{p_i},{q_i}inM both converging to a point p ∈ P, withp_i 6= q_i but f(p_i) = f(q_i) for all i, and this contradicts the non-singularity ofdfp.)

13 Letpbe a homogeneous polynomial of degreeminnvariablest₁, . . . , t_n. Show thatp⁻¹(a)is a submanifold of codimension one ofRⁿifa6= 0. Show that the submanifolds obtained witha >0are all diffeomorphic, as well as those witha <0. (Hint: Use Euler’s identity

Xn

i=1

t_i∂p

∂ti

=mp.)

14 Then×nreal matrices with determinar1form a group denotedSL(n,R).

Prove thatSL(n,R)is a submanifold ofGL(n,R). (Hint: Use Problem 13.) 15 Consider the submanifolds GL(n,R), O(n) and SL(n,R) of the vec-tor spaceM(n,R) (see Examples 1.2.7(ix) and 1.4.14(b), and Problem 14, respectively).

a. Check that the tangent space ofGL(n,R)at the identity is canonically isomorphic toM(n,R).

b. Check that the tangent space ofSL(n,R)at the identity is canonically isomorphic to the subspace ofM(n,R)consisting of matrices of trace zero.

1.8. PROBLEMS 37 c. Check that the tangent space ofO(n)at the identity is canonically iso-morphic to the subspace ofM(n,R)consisting of the skew-symmetric matrices.

16 Denote byM(m×n,R)the vector space of realm×nmatrices.

a. Show that the subset ofM(m×n,R)consisting of matrices of rank at leastk(0≤k≤min{m, n}) is a smooth manifold.

b. Show that the subset ofM(m×n,R)consisting of matrices of rank equal to k(0 ≤ k ≤ min{m, n}) is a smooth manifold. What is its dimension? (Hint: We may work in a neighborhood of a matrix

g=

k m−k

^k A ^n−kB

C D

whereAis nonsingular and right multiply by I −A⁻¹B

0 I

to check thatghas rankkif and only ifD−CA⁻¹B = 0.)

17 Let M −→^f N −→^g P be a sequence of smooth maps between smooth manifolds. Assume thatg ⋔ Qfor a submanifoldQofP. Prove thatf ⋔ g⁻¹(Q)if and only ifg◦f ⋔Q.

18 LetG ⊂ R² be the graph of g : R → R, g(x) = |x|^1/3. Show that G admits a smooth structure so that the inclusionG→ R²is smooth. Is it an immersion? (Hint: consider the mapf :R→Rgiven by

f(t) =







te^−1/t ift >0, 0 ift= 0, te^1/t ift <0.)

19 Define submanifolds(M₁, f₁),(M₂, f₂)ofN to beequivalentif there ex-ists a diffeomorphismg:M₁→M₂such thatf₂◦g=f₁.

a. Show that this is indeed an equivalence relation.

b. Show that each equivalence class of submanifolds ofN contains a unique representative of the form (M, ι), where M is a subset ofN with a manifold structure such thatι : M → N is a smooth immer-sion.

c. LetN be a smooth manifold, and letM be a subset ofN equipped with a given topology. Prove that there exists at most one smooth structure onM, up to equivalence, which makes(M, ι)an immersed submanifold of N, whereι : M → N is the inclusion. (Hint: Use Proposition 1.4.9.)

d. LetN be a smooth manifold, and letM be a subset ofN. Prove that there exists at most one structure of smooth manifold on M, up to equivalence, which makes(M, ι) an initial submanifold ofN, where ι:M →N is the inclusion. (Hint: Use Proposition 1.4.9.)

20 LetN be a smooth manifold of dimensionn+k. For a pointq ∈N and a subsetA⊂N, denote byC_q(A)the set of all points ofAthat can be joined toqby a smooth curve inMwhose image lies inA.

a. Prove that if(P, g)is an initial submanifold of dimensionnofN then for everyp∈P there exists a local chart(V, ψ)ofN aroundg(p)such that

ψ(C_g(p)(V ∩g(P))) =ψ(V)∩(Rⁿ× {0}).

(Hint: Use Proposition 1.4.5.)

b. Conversely, assumeP is a subset ofN with the property that around any point p ∈ P there exists a local chart(V, ψ)of N aroundpsuch that

ψ(C_p(V ∩P)) =ψ(V)∩(Rⁿ× {0}).

Prove that there exists a topology on P that makes each connected component ofPinto an initial submanifold of dimensionnofNwith respect to the inclusion. (Hint: Apply Proposition 1.2.10 to the re-strictionsψ|Cp(V∩P). Proving second-countability requires the follow-ing facts: for locally Euclidean Hausdorff spaces, paracompactness is equivalent to the property that each connected component is second-countable; every metric space is paracompact; the topology on P is metrizable since it is compatible with the Riemannian distance for the Riemannian metric induced from a given Riemannian metric on N; Riemannian metrics can be constructed onN using partitions of unity.)

21 Show that the product of any number of spheres can be embedded in some Euclidean space with codimension one.

§ 1.5

22 Let M be a closed submanifold ofN. Prove that the restriction map C^∞(N) → C^∞(M) is well defined and surjective. Show that the result ceases to be true if: (i)M is not closed; or (ii)M ⊂N is closed but merely assumed to be an immersed submanifold.

23 LetM be a smooth manifold of dimensionn. Givenp ∈ M, construct a local chart(U, ϕ)ofM aroundpsuch thatϕis the restriction of a smooth mapM →Rⁿ.

1.8. PROBLEMS 39 24 Prove that on any smooth manifold M there exists a proper smooth mapf :M → R. (Hint: Useσ-compactness of manifolds and partitions of unity.)

§ 1.6

25 Determine the vector field onR²with flowϕt(x, y) = (xe^2t, ye^−3t).

26 Determine the flow of the vector fieldXonR² when:

a. X=y_∂x^∂ −x_∂y^∂. b. X=x_∂x^∂ +y_∂y^∂.

27 Given the following vector fields inR³,

X=y_∂x^∂ −x_∂y^∂ , Y =z_∂y^∂ −y_∂z^∂ , Z = _∂x^∂ +_∂y^∂ +_∂z^∂ , compute their Lie brackets.

28 Show that the restriction of the vector field defined onR²ⁿ X =−x2 ∂

∂x1 +x1 ∂

∂x2 +· · · −x2n ∂

∂x2n−1 +x2n−1 ∂

∂x2n

to the unit sphereS²ⁿ⁻¹defines a nowhere vanishing smooth vector field.

29 LetXandY be smooth vector fields onM andN with flows{ϕ_t}and {ψt}, respectively, and letf :M → N be smooth. Show thatXandY are f-related if and only iff ◦ϕ_t=ψ_t◦ffor allt.

30 LetM be a properly embedded submanifold ofN. Prove that every smooth vector field onM can be smoothly extended to a vector field onN. 31 Construct a natural diffeomorphismT S¹≈S¹×Rwhich restricts to a linear isomorphismT_pS¹ → {p} ×Rfor everyp ∈ S¹ (we say that such a diffeomorphism maps fibers to fibers and is linear on the fibers).

32 Construct a natural diffeomorphismT(M×N)≈T M×T Nthat maps fibers to fibers and is linear on the fibers.

33 Construct a natural diffeomorphismTRⁿ≈Rⁿ×Rⁿthat maps fibers to fibers and is linear on the fibers.

34 Show thatT Sⁿ×R is diffeomorphic toSⁿ×Rⁿ⁺¹. (Hint: There are natural isomorphismsT_pSⁿ⊕R∼=Rⁿ⁺¹.)

35 A smooth manifold M of dimensionnis called parallelizable if T M ≈ M×Rⁿby a diffeomorphism that maps fibers to fibers and is linear on the fibers. Prove thatM is parallelizable if and only if there exists a globally definedn-frame{X₁, . . . , X_n}onM.

§ 1.7

36 Is there a non-constant smooth functionf defined on an open subset of R³such that

∂f

∂x−y∂f

∂z = 0 and ∂f

∂y +x∂f

∂z = 0?

(Hint: Consider a regular level set off.)

37 Consider the first order system of partial differential equations

∂z

∂x =α(x, y, z), ∂z

∂y =β(x, y, z)

whereα,β are smooth functions defined on an open subset ofR³.

a. Show that iff is a solution, then the smooth vector fieldsX = _∂x^∂ + α_∂z^∂ eY = _∂y^∂ +β_∂z^∂ span the tangent space to the graph off at all points.

b. Prove that the system admits local solutions if and only if

∂β

∂x+α∂β

∂z = ∂α

∂y +β∂α

∂z.

38 Prove that there exists a smooth functionf defined on a neighborhood of(0,0)inR²such thatf(0,0) = 0and^∂f_∂x =ye^−(x+y)−f,^∂f_∂y =xe^−(x+y)−f.

C H A P T E R 2

Tensor fields and differential forms

2.1 Multilinear algebra

LetV be a real vector space. In this section, we construct the tensor algebra T(V) and the exterior algebra Λ(V) overV. Elements ofT(V)are called tensors onV. Later we will apply these constructions to the tangent space TpM of a manifoldM and letpvary inM, similarly to the definition of the tangent bundle.

Tensor algebra

All vector spaces are real and finite-dimensional. LetV andW be vector spaces. It is less important what the tensor product of V and W is than what itdoes. Namely, a tensor product ofV andW is a vector spaceV ⊗W together with a bilinear maph:V ×W →V ⊗W such that the following universal propertyholds: for every vector space U and every bilinear map B :V×W →U, there exists a unique linear mapB˜ :V ⊗W →U such that B˜◦h=B.

V ⊗W

V ×W h∧

B> U B˜ ...

...>

There are different ways to constructV ⊗W. It does not actually matter which one we choose, in view of the following exercise.

2.1.1 Exercise Prove that the tensor product ofV and W is uniquely de-fined by the universal property. In other words, if(V⊗¹W, h1),(V⊗²W, h2) are two tensor products, then there exists an isomorphismℓ : V ⊗1W → V ⊗2W such thatℓ◦h₁=h₂.

We proceed as follows. Start with the canonical isomorphismV^∗∗ ∼=V betweenV and its bidual. It says that we can view an element v inV as

41

the linear map onV^∗ given by f 7→ f(v). Well, we can extend this idea and consider the spaceBil(V, W)of bilinear forms onV ×W. Then there is a natural maph:V ×W →Bil(V, W)^∗given byh(v, w)(b) =b(v, w)for b∈Bil(V, W). We claim that(Bil(V, W)^∗, h)satisfies the universal property:

given a bilinear mapB : V ×W → U, there is an associated mapU^∗ → Bil(V, W),f 7→f◦B; letB˜ : Bil(V, W)^∗ →U^∗∗=U be its transpose.

2.1.2 Exercise Check thatB˜◦h=B.

2.1.3 Exercise Let {e_i}, {f_j} be bases ofV, W, respectively. Defineb_ij ∈ Bil(V, W)to be the bilinear form whose value on(e_k, f_ℓ)is1if(k, ℓ) = (i, j) and0 otherwise. Prove that{b_ij} is a basis ofBil(V, W). Prove also that {h(e_i, f_j)}is the dual basis ofBil(V, W)^∗. Deduce that the image ofhspans Bil(V, W)^∗ and henceB˜ as in Exercise 2.1.2 is uniquely defined.

Now thatV ⊗W is constructed, we can forget about its definition and keep in mind its properties only (in the same way as when we work with real numbers and we do not need to know that they are equivalence classes of Cauchy sequences), namely, the universal property and those listed in the sequel. Henceforth, we writev⊗w=h(v, w)forv∈V andw∈W. 2.1.4 Proposition LetV andW be vector spaces. Then:

a. (v₁+v₂)⊗w=v₁⊗w+v₂⊗w; b. v⊗(w1+w2) =v⊗w1+v⊗w2; c. av⊗w=v⊗aw =a(v⊗w);

for allv,v₁,v₂ ∈V;w,w₁,w₂∈W;a∈R.

2.1.5 Proposition LetU, V andW be vector spaces. Then there are canonical isomorphisms:

a. V ⊗W ∼=W ⊗V;

b. (V ⊗W)⊗U ∼=V ⊗(W ⊗U);

c. V^∗⊗W ∼= Hom(V, W); in particular,dimV ⊗W = (dimV)(dimW). 2.1.6 Exercise Prove Propositions 2.1.4 and 2.1.5.

2.1.7 Exercise Let {e₁, . . . , e_m}and{f₁, . . . , f_n}be bases forV andW, re-spectively. Prove that{e_i⊗f_j : i= 1, . . . , mandj = 1, . . . , n}is a basis forV ⊗W.

2.1.8 Exercise LetA= (a_ij)be a realm×nmatrix, viewed as an element of Hom(Rⁿ,R^m). Use the canonical inner product inRⁿto identify(Rⁿ)^∗ ∼= Rⁿ. What is the element ofRⁿ⊗R^mthat corresponds toA?

TakingV =W and using Proposition 2.1.5(b), we can now inductively form the tensornth power⊗ⁿV =⊗ⁿ⁻¹V ⊗V forn ≥1, where we adopt

2.1. MULTILINEAR ALGEBRA 43 the convention that⊗⁰V =R. Thetensor algebraT(V)overV is the direct sum

T(V) = M

r,s≥0

V^r,s where

V^r,s= (⊗^rV)⊗(⊗^sV^∗)

is called thetensor space of type(r, s). The elements ofT(V)are calledtensors, and those ofV^r,sare calledhomogeneous of type(r, s). The multiplication⊗, read “tensor”, is theR-linear extension of

(u₁⊗ · · · ⊗u_r1 ⊗u^∗₁⊗ · · · ⊗u^∗_s1)⊗(v₁⊗ · · · ⊗v_r2⊗v^∗₁⊗ · · · ⊗v_s^∗₂)

= u1⊗ · · · ⊗ur1⊗v1⊗ · · · ⊗vr2 ⊗u^∗₁⊗ · · · ⊗u^∗_s1 ⊗v₁^∗⊗ · · · ⊗v^∗_s2. T(V) is a non-commutative, associative graded algebra, in the sense that tensor multiplication is compatible with the natural grading:

V^r1,s1 ⊗V^r2,s2 ⊂V^r1+r2,s1+s2.

Note thatV^0,0 = R, V^1,0 = V, V^0,1 = V^∗, so real numbers, vectors and linear forms are examples of tensors.

Exterior algebra

Even more important to us will be a certain quotient of the subalgebra T⁺(V) =L

k≥0V^k,0ofT(V). LetIbe the two-sided ideal ofT⁺(V) gener-ated by the set of elements of the form

(2.1.9) v⊗v

forv∈V.

2.1.10 Exercise Prove that another set of generators for Iis given by the elements of the formu⊗v+v⊗uforu,v ∈V.

Theexterior algebraoverV is the quotient Λ(V) =T⁺(V)/I.

The induced multiplication is denoted by∧, and read “wedge” or “exterior product”. In particular, the class ofv₁⊗· · ·⊗v_kmoduloIis denotedv₁∧· · ·∧

v_k. This is also a graded algebra, where the space of elements of degreekis Λ^k(V) =V^k,0/I∩V^k,0.

SinceIis generated by elements of degree2, we immediately get Λ⁰(V) =R and Λ¹(V) =V.

Λ(V)is not commutative, but we have:

2.1.11 Proposition α∧β= (−1)^kℓβ∧αforα ∈Λ^k(V),β ∈Λ^ℓ(V).

Proof. Sincev⊗v ∈Ifor allv∈V, we havev∧v= 0. SinceRis not a field of characteristic two, this relation is equivalent tov₁∧v₂ = −v₂ ∧v₁ for allv₁,v₂∈V.

By linearity, we may assume that α = u₁∧ · · · ∧u_k, β = v₁ ∧ · · · ∧v_ℓ. Now

α∧β = u1∧ · · · ∧u_k∧v1∧ · · · ∧v_ℓ

= −u₁∧ · · · ∧u_k−1∧v₁∧u_k∧v₂· · · ∧v_ℓ

= u₁∧ · · · ∧u_k−1∧v₁∧v₂∧u_k∧v₃· · · ∧v_ℓ

= · · ·

= (−1)^ℓu₁∧ · · · ∧u_k−1∧v₁∧ · · · ∧v_ℓ∧u_k

= (−1)^2ℓu1∧ · · · ∧u_k−2∧v1∧ · · · ∧v_ℓ∧u_k−1∧u_k

= · · ·

= (−1)^kℓβ∧α,

as we wished.

2.1.12 Lemma IfdimV =n, thendim Λⁿ(V) = 1andΛ^k(V) = 0fork > n.

Proof. Let{e1, . . . , en}be a basis ofV. Since

(2.1.13) {e_i1⊗ · · · ⊗e_ik : i₁, . . . , i_k∈ {1, . . . , n}}

is a basis ofV^k,0 (see Exercise 2.1.7), the image of this set under the pro-jectionV^k,0 → Λ^k(V)is a set of generators ofΛ^k(V). Taking into account Proposition 2.1.11 yieldsΛ^k(V) = 0fork > nand thatΛⁿ(V)is generated bye₁∧ · · · ∧e_n, so we need only show that this element is not zero.

Suppose, on the contrary, thate1 ⊗ · · · ⊗en ∈ I. Thene1⊗ · · · ⊗en is a linear combination of elements of the formα⊗v⊗v⊗β wherev ∈ V, α ∈ V^k,0, β ∈ V^ℓ,0 andk+ℓ+ 2 = n. Writingα (resp.β) in terms of the basis (2.1.13), we may assume that the only appearing base elements are of the forme₁⊗ · · · ⊗e_k(resp.e_n−ℓ+1⊗ · · · ⊗e_n). It follows that we can write (2.1.14) e₁⊗ · · · ⊗e_n =

n−2X

k=0

c_ke₁⊗ · · · ⊗e_k⊗v_k⊗v_k⊗e_k+3⊗ · · · ⊗e_n wherec_k∈Randv_k∈V for allk. Finally, writev_k =P_n

i=1a_ike_ifora_k∈R. Form= 0, . . . , n−2, the coefficient of

e₁⊗ · · · ⊗e_m⊗e_m+2⊗e_m+1⊗e_m+3⊗ · · · ⊗e_n on the right hand side of (2.1.14) is

c_ma_m+2,ma_m+1,m,

2.2. TENSOR BUNDLES 45

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