132 CHAPTER 3. MATHEMATICAL FOUNDATIONS
which can be generalized to tensor fields on Riemann manifolds.
LetMbe a Riemannian manifold with∂M=/0. Then, there is an inner product defined
onTMdefined by
(X,Y) =gijXiXj ∀X,Y∈TM.
Also, there is an inner product onT∗M:
(X∗,Y∗) =gijXi∗Yj∗ ∀X∗,Y∗∈T∗M.The tensor bundleTrkMis
TrkM=T︸M⊗ ··· ⊗︷︷ TM︸
k⊗︸T∗M⊗ ··· ⊗︷︷ T∗M︸
r.
The inner products onTMandT∗Minduce a natural inner product onTrkM:
(3.2.33) (u,v) =gi 1 j 1 ···gikjkgl^1 s^1 ···glrsruil 11 ······ilrkvsj 11 ······sjrr ∀u,v∈TrkM.
Hence we can define the inner product〈·,·〉onL^2 (TrkM)by(3.2.34) 〈u,v〉L 2 =
∫M(u,v)√
−gdx ∀u,v∈L^2 (TrkM),where(u,v)is as in (3.2.33).
Furthermore, we can also define an inner product on the spacesHm(TrkM)as follows
(3.2.35) 〈u,v〉Hm=
∫M[(− 1 )m(∆mu,v)+ (u,v)]√
−gdx ∀u,v∈Hm(TrkM),where∆=div·∇.
In the following, we give the Gauss formula onTrkM, which are crucial for the orthogonal
decomposition theory in the next section.
Theorem 3.11(Gauss Formula). For any u∈H^1 (TrkM)and v∈H^1 (Trk+^1 M)(or v∈
H^1 (Trk+ 1 M)),
(3.2.36)
∫M(∇u,v)√
−gdx=−∫M(u,divv)√
−gdx.Formula (3.2.36) is a corollary of the classical Gauss formula(3.2.37)
∫Mdivw√
−gdx=∫∂Mw·nds.In fact, letwk= (u,vk), then by (2.3.28) we have
divw=Dk(u,vk) = (∇u,v)+ (u,divv).If∂M=/0, then we derive from (3.2.37) that
∫
Mdivw√
−gdx=∫M[(∇u,v)+ (u,divv)]√
−gdx= 0 ,