REAL HYPERSURFACES IN COMPLEX HYPERBOLIC TWO-PLANE GRASSMANNIANS WITH COMMUTING 6 STRUCTURE JACOBI OPERATORS 1 0 2 HYUNJINLEE,YOUNGJINSUHANDCHANGHWAWOO n a Abstract. In this paper, we introduce anew commuting condition between J thestructureJacobioperatorandsymmetric(1,1)-typetensorfieldT,thatis, 5 RξφT =TRξφ,whereT =AorT =S forHopfhypersurfacesincomplexhy- 2 perbolictwo-planeGrassmannians. Byusingsimultaneous diagonalzation for commuting symmetricoperators, we giveacomplete classification of real hy- ] persurfaces incomplexhyperbolictwo-plane Grassmannianswithcommuting G conditionrespectively. D . h t a m Introduction [ 1 Itisoneofthemaintopicsinsubmanifoldgeometrytoinvestigateimmersedreal v hypersurfacesofhomogeneoustypeinHermitiansymmetricspacesofrank2(HSS2) 8 withcertaingeometricconditions. Understandingandclassifyingrealhypersurfaces 1 in HSS2 is one of importantproblems in differential geometry. One of these spaces 0 is the complex two-plane Grassmannian G (Cm+2) = SU /S(U U ) defined 8 2 2+m 2 m 0 by the set of all complex two-dimensional linear subspaces in Cm+2.·Another one . is the complex hyperbolic two-plane GrassmannianG (Cm+2)=SU /S(U U ) 2 ∗2 2,m 2· m 0 defined by the set of all complex two-dimensional linear subspaces in indefinite 6 complex Euclidean space Cm+2. 2 1 These aretypicalexamplesofHSS2. Characterizingtypicalmodel spacesofreal : v hypersurfacesundercertaingeometricconditionsisoneofourmaininterestsinthe Xi classification theory in G2(Cm+2) or SU2,m/S(U2·Um) (see [13] and [14]). Our recent interest is the study by applying geometric conditions used in sub- r manifolds in G (Cm+2) to submanifolds in SU /S(U U ). a 2 2,m 2 m G (Cm+2) = SU /S(U U ) has compact transiti·ve group SU , however 2 2+m 2 m 2+m · SU /S(U U ) has noncompact indefinite transitive group SU . This distinc- 2,m 2 m 2,m · tion gives various remarkable results. Thecomplexhyperbolictwo-planeGrassmannianSU /S(U U )istheunique 2,m 2 m · noncompact, irreducible, K¨ahler and quaternionic K¨ahler manifold which is not a hyperk¨ahler manifold. 12010 Mathematics Subject Classification: Primary53C40; Secondary53C15. 2Key words : Real hypersurfaces; complex hyperbolictwo-plane Grassmannians, Hopfhyper- surface,shapeoperator,Riccitensor,structureJacobioperator,commutingcondition. *This work was supported by Grant Proj. No. NRF-2015-R1A2A1A-01002459 and the third authorissupportedbyNRFGrantfundedbytheKoreanGovernment(NRF-2013-FosteringCore LeadersofFutureBasicScienceProgram). 1 2 HYUNJINLEE,YOUNGJINSUHANDCHANGHWAWOO Let M be a real hypersurface in complex hyperbolic two-plane Grassmannian SU /S(U U ). Let N be a local unit normalvector field on M. Since the com- 2,m 2 m · plex hyperbolic two-plane Grassmannians SU /S(U U ) has the K¨ahler struc- 2,m 2 m · tureJ,wemaydefineaReebvector fieldξ = JN anda1-dimensionaldistribution − =Span ξ . ⊥ C { } Let be the orthogonal complement of distribution in T M at p M. It is ⊥ p C C ∈ the complex maximal subbundle of T M. Thus the tangent space of M consists of p the direct sum of and as follows: T M = . The real hypersurface M ⊥ p ⊥ C C C ⊕C is said to be Hopf if A , or equivalently, the Reeb vector field ξ is principal C ⊂ C withprincipalcurvatureα=g(Aξ,ξ),whereg denotesthemetric. Inthiscase,the principal curvature α is said to be a Reeb curvature of M. FromthequaternionicK¨ahlerstructureJ=Span J ,J ,J ofSU /S(U U ), 1 2 3 2,m 2 m { } · therenaturallyexistalmostcontact3-structurevectorfieldsξ = J N,ν =1,2,3. ν ν − Let = Span ξ ,ξ ,ξ . It is a 3-dimensional distribution in the tangent space ⊥ 1 2 3 Q { } T M of M at p M. In addition, stands for the orthogonalcomplement of p ⊥ ∈ Q Q inT M. ItisthequaternionicmaximalsubbundleofT M. Thusthetangentspace p p of M can be splitted into and as follows: T M = . ⊥ p ⊥ Q Q Q⊕Q Thus,wehaveconsideredtwonaturalgeometricconditionsforrealhypersurfaces in SU /S(U U ) such that the subbundles and of TM are both invariant 2,m 2 m · C Q under the shape operator. By using these geometric conditions, we will use the results in Suh [13, Theorem 1]. Ontheotherhand,aJacobifieldalonggeodesicsofagivenRiemannianmanifold (M¯,g¯) plays an important role in the study of differential geometry. It satisfies a well-known differential equation which inspires Jacobi operators. It is defined by (R¯ (Y))(p) = (R¯(Y,X)X)(p), where R¯ denotes the curvature tensor of M¯ and X X,Y denoteanyvectorfieldsonM¯. Itisknowntobeaself-adjointendomorphism on the tangent space T M¯, p M¯. Clearly, each tangent vector field X to M¯ p ∈ provides a Jacobi operator with respect to X. Thus the Jacobi operator on a real hypersurface M of M¯ with respect to ξ is said to be a structure Jacobi operator and will be denoted by R . The Riemannian curvature tensor of M (resp., M¯) is ξ denoted by R (resp., R¯). For a commuting problem concernedwith the structure Jacobioperator R and ξ thestructuretensorφofHopfhypersurfaceM inG (Cm+2),thatis,R φA=AR φ, 2 ξ ξ Lee,Suh andWoo [3]provedthata Hopf hypersurfaceM withR φA=AR φ and ξ ξ ξα = 0 is locally congruent to an open part of a tube around a totally geodesic G (Cm+1) in G (Cm+2). Motivated by this result, we consider the same condition 2 2 in the different ambient space, that is, (C-1) R φAX =AR φX ξ ξ foranytangentvectorfieldX onM inSU /S(U U ). Thegeometricmeaningof 2,m 2 m · R φAX =AR φX canbeexplainedinsuchawaythatanyeigenspaceofR onthe ξ ξ ξ distribution = X T M X ξ ,p M,isinvariantundertheshapeoperator p C { ∈ | ⊥ } ∈ A of M in SU /S(U U ). Then by using [13, Theorem 1], we give a complete 2,m 2 m · classification of Hopf hypersurfaces in SU /S(U U ) with R φAX = AR φX 2,m 2 m ξ ξ · as follows: Theorem 1. LetM beaHopf hypersurface in complex hyperbolic two-planeGrass- mannians SU /S(U U ), m 3 with R φA = AR φ. If the Reeb curvature 2,m 2 m ξ ξ · ≥ COMMUTING STRUCTURE JACOBI OPERATORS 3 α = g(Aξ,ξ) is constant along the Reeb direction of the structure vector field ξ, then M is locally congruent to one of the following: (i) a tube over a totally geodesic SU /S(U U ) in SU /S(U U ) or 2,m 1 2 m 1 2,m 2 m − · − · (ii) a horosphere in SU /S(U U ) whose center at infinity is singular and of 2,m 2 m · type JX JX. ∈ FromtheRiemanniancurvaturetensorRofM inSU /S(U U )wecandefine 2,m 2 m · the Ricci tensor S of M in such a way that 4m 1 g(SX,Y)= − g(R(e ,X)Y,e ), i i i=1 X where e , ,e denotes a basis of the tangent space T M of M, p M, in 1 4m 1 p { ··· − } ∈ SU /S(U U ) (see [15]). Then we can consider another new commuting condi- 2,m 2 m · tion (C-2) R φSX =SR φX ξ ξ for any tangent vector field X on M. That is, the operator R φ commutes with ξ the Ricci tensor S. Then by [13, Theorem 1], we also give another classificationrelated to the Ricci tensor S of M in SU /S(U U ) as follows: 2,m 2 m · Theorem 2. LetM beaHopf hypersurface in complex hyperbolic two-planeGrass- mannians SU /S(U U ), m 3 with R φS = SR φ. If the smooth function 2,m 2 m ξ ξ · ≥ α = g(Aξ,ξ) is constant along the direction of ξ, then M is locally congruent to one of the following: (i) a tube over a totally geodesic SU /S(U U ) in SU /S(U U ) or 2,m 1 2 m 1 2,m 2 m − · − · (ii) a horosphere in SU /S(U U ) whose center at infinity is singular and of 2,m 2 m · type JX JX. ∈ Inthispaper,werefer[10],[13],[14]and[15]forRiemanniangeometricstructures of complex hyperboilc two-plane Grassmannians SU /S(U U ), m 3. 2,m 2 m · ≥ 1. The complex hyperbolic two-plane Grassmannian SU /S(U U ) 2,m 2 m · Inthissectionwesummarizebasicmaterialaboutcomplexhyperbolictwo-plane Grassmann manifolds SU /S(U U ), for details we refer to [9], [11], [13] and 2,m 2 m · [15]. The Riemannian symmetric space SU /S(U U ), which consists of all 2,m 2 m · complex two-dimensional linear subspaces in indefinite complex Euclidean space Cm+2 is a connected, simply connected, irreducible Riemannian symmetric space 2 of noncompact type and with rank two. Let G = SU and K = S(U U ), 2,m 2 m · and denote by g and k the corresponding Lie algebra of the Lie group G and K respectively. Let B be the Killing form of g and denote by p the orthogonal complement of k in g with respect to B. The resulting decomposition g = k p is ⊕ a Cartan decomposition of g. The Cartan involution θ Aut(g) on su is given 2,m ∈ by θ(A)=I AI , where 2,m 2,m I 0 I2,m =(cid:18)0−m,22 I2m,m(cid:19), I and I denote the identity 2 2-matrix and m m-matrix respectively. Then 2 m × × <X,Y >= B(X,θY) becomes a positive definite Ad(K)-invariantinner product − 4 HYUNJINLEE,YOUNGJINSUHANDCHANGHWAWOO ong. ItsrestrictiontopinducesametricgonSU /S(U U ),whichisalsoknown 2,m 2 m · as the Killing metric on SU /S(U U ). Throughout this paper we consider 2,m 2 m · SU /S(U U ) together with this particular Riemannian metric g. 2,m 2 m · The Lie algebra k decomposes orthogonally into k = su su u , where u 2 m 1 1 ⊕ ⊕ is the one-dimensional center of k. The adjoint action of su on p induces the 2 quaternionic K¨ahler structure J on SU /S(U U ), and the adjoint action of 2,m 2 m · mi I 0 Z = m+2 2 2,m u (cid:18) 0m,2 m−+2i2Im(cid:19)∈ 1 inducestheK¨ahlerstructureJ onSU /S(U U ). Byconstruction,J commutes 2,m 2 m · witheachalmostHermitianstructureJ inJforν =1,2,3. Recallthatacanonical ν localbasis J ,J ,J ofaquaternionicK¨ahlerstructureJconsistsofthreealmost 1 2 3 { } Hermitian structures J ,J ,J in J such that J J = J = J J , where 1 2 3 ν ν+1 ν+2 ν+1 ν − the index ν is to be taken modulo 3. The tensor field JJ , which is locally defined ν on SU /S(U U ), is self-adjoint and satisfies (JJ )2 = I and tr(JJ ) = 0, 2,m 2 m ν ν · where I is the identity transformation. For a nonzero tangent vector X, we define RX = λX λ R , CX =RX RJX, and HX =RX JX. { | ∈ } ⊕ ⊕ We identify the tangent space T SU /S(U U ) of SU /S(U U ) at o o 2,m 2 m 2,m 2 m · · with p in the usual way. Let a be a maximal abelian subspace of p. Since SU /S(U U ) has rank two, the dimension of any such subspace is two. Every 2,m 2 m · nonzerotangentvectorX ∈ToSU2,m/S(U2·Um)∼=p is containedin some maximal abelian subspace of p. Generically this subspace is uniquely determined by X, in which case X is called regular. If there exist more than one maximal abelian sub- spaces of p containing X, then X is called singular. There is a simple and useful characterization of the singular tangent vectors: A nonzero tangent vector X p ∈ is singular if and only if JX JX or JX JX. ∈ ⊥ Up to scaling there exists a unique SU -invariant Riemannian metric g on 2,m SU /S(U U ). Equipped with this metric, SU /S(U U ) is a Riemannian 2,m 2 m 2,m 2 m · · symmetric space of rank two which is both K¨ahler and quaternionic K¨ahler. For computational reasons we normalize g such that the minimal sectional curvature of(SU /S(U U ),g) is 4. The sectionalcurvature K of the noncompactsym- 2,m 2 m · − metric space SU /S(U U ) equipped with the Killing metric g is bounded by 2,m 2 m 4 K 0. The sectional c·urvature 4 is obtained for all two-planes CX when X − ≤ ≤ − is a non-zero vector with JX JX. ∈ When m = 1, G (C3) = SU /S(U U ) is isometric to the two-dimensional complex hyperbolic s∗2pace CH2 w1i,t2h con1st·an2t holomorphic sectional curvature 4. − When m = 2, we note that the isomorphism SO(4,2) SU yields an isom- 2,2 etry between G (C4) = SU /S(U U ) and the indefinite≃real Grassmann mani- foldG (R6)ofo∗2rientedtwo-2d,2imensi2o·na2llinearsubspacesofanindefiniteEuclidean ∗2 2 space R6. For this reason we assume m 3 from now on, although many of the 2 ≥ subsequent results also hold for m=1,2. From now on, hereafter X,Y and Z always stand for any tangent vector fields on M. COMMUTING STRUCTURE JACOBI OPERATORS 5 The Riemannian curvature tensor R¯ of SU /S(U U ) is locally given by 2,m 2 m · 2R¯(X,Y)Z =g(Y,Z)X g(X,Z)Y +g(JY,Z)JX − − g(JX,Z)JY 2g(JX,Y)JZ − − 3 + g(J Y,Z)J X g(J X,Z)J Y 2g(J X,Y)J Z ν ν ν ν ν ν { − − } νX=1 3 + g(J JY,Z)J JX g(J JX,Z)J JY , ν ν ν ν { − } νX=1 where J ,J ,J is any canonical local basis of J. 1 2 3 { } 2. Fundamental formulas in SU /S(U U ) 2,m 2 m · In this section, we derive some basic formulas and the Codazzi equation for a real hypersurface in SU /S(U U ) (see [13], [14] and [15]). 2,m 2 m · Let M be a real hypersurface in complex hyperbolic two-plane Grassmannian SU /S(U U ),thatis,ahypersurfaceinSU /S(U U )withrealcodimension 2,m 2 m 2,m 2 m · · one. TheinducedRiemannianmetriconM willalsobedenotedbyg,and denotes ∇ the LeviCivita covariantderivative of(M,g). We denote by and the maximal C Q complexandquaternionicsubbundle ofthe tangentbundle TM ofM,respectively. Now let us put (2.1) JX =φX +η(X)N, J X =φ X +η (X)N ν ν ν foranytangentvectorfieldX ofarealhypersurfaceM inSU /S(U U ),where 2,m 2 m · φX denotes the tangential component of JX and N a unit normal vector field of M in SU /S(U U ). 2,m 2 m · Fromthe K¨ahlerstructure J ofSU /S(U U ) there exists analmostcontact 2,m 2 m · metric structure (φ,ξ,η,g) induced on M in such a way that (2.2) φ2X = X +η(X)ξ, η(ξ)=1, φξ =0, η(X)=g(X,ξ) − foranyvectorfieldX onM. Furthermore,let J ,J ,J beacanonicallocalbasis 1 2 3 { } ofJ. ThenthequaternionicK¨ahlerstructureJ ofSU /S(U U ),togetherwith ν 2,m 2 m · the condition J J = J = J J in section 1, induces an almost contact ν ν+1 ν+2 ν+1 ν − metric 3-structure (φ ,ξ ,η ,g) on M as follows: ν ν ν φ2X = X +η (X)ξ , η (ξ )=1, φ ξ =0, ν − ν ν ν ν ν ν φ ξ = ξ , φ ξ =ξ , ν+1 ν ν+2 ν ν+1 ν+2 (2.3) − φ φ X =φ X +η (X)ξ , ν ν+1 ν+2 ν+1 ν φ φ X = φ X+η (X)ξ ν+1 ν ν+2 ν ν+1 − for any vector field X tangent to M. Moreover, from the commuting property of J J =JJ ,ν =1,2,3insection1and(2.1),therelationbetweenthesetwocontact ν ν metric structures (φ,ξ,η,g) and (φ ,ξ ,η ,g), ν =1,2,3, can be given by ν ν ν φφ X =φ φX +η (X)ξ η(X)ξ , ν ν ν ν (2.4) − η (φX)=η(φ X), φξ =φ ξ. ν ν ν ν 6 HYUNJINLEE,YOUNGJINSUHANDCHANGHWAWOO Onthe otherhand,fromtheparallelismofK¨ahlerstructureJ,thatis, J =0and ∇ thequaternionicK¨ahlerstructureJ,togetherwithGaussandWeingartenformulas, e it follows that (2.5) ( φ)Y =η(Y)AX g(AX,Y)ξ, ξ =φAX, X X ∇ − ∇ (2.6) ξ =q (X)ξ q (X)ξ +φ AX, X ν ν+2 ν+1 ν+1 ν+2 ν ∇ − ( φ )Y = q (X)φ Y +q (X)φ Y +η (Y)AX X ν ν+1 ν+2 ν+2 ν+1 ν (2.7) ∇ − g(AX,Y)ξ . ν − Combining these formulas, we find the following: (φ ξ)= (φξ ) X ν X ν ∇ ∇ =( φ)ξ +φ( ξ ) X ν X ν (2.8) ∇ ∇ =q (X)φ ξ q (X)φ ξ+φ φAX ν+2 ν+1 ν+1 ν+2 ν − g(AX,ξ)ξ +η(ξ )AX. ν ν − Finally, using the explicit expression for the Riemannian curvature tensor R¯ of SU /S(U U ) in [14], the Codazzi equation takes the form 2,m 2 m · 2( A)Y +2( A)X =η(X)φY η(Y)φX 2g(φX,Y)ξ X Y − ∇ ∇ − − 3 + η (X)φ Y η (Y)φ X 2g(φ X,Y)ξ ν ν ν ν ν ν − − νX=1(cid:8) (cid:9) (2.9) 3 + η (φX)φ φY η (φY)φ φX ν ν ν ν − νX=1(cid:8) (cid:9) 3 + η(X)η (φY) η(Y)η (φX) ξ , ν ν ν − νX=1(cid:8) (cid:9) for any vector fields X and Y on M. On the other hand, by differentiating Aξ = αξ and using (2.9), we get the following 3 g(φX,Y) η (X)η (φY) η (Y)η (φX) g(φ X,Y)η (ξ) ν ν ν ν ν ν − { − − } Xν=1 (2.10) =g(( A)Y ( A)X,ξ) X Y ∇ − ∇ =g(( A)ξ,Y) g(( A)ξ,X) X Y ∇ − ∇ =(Xα)η(Y) (Yα)η(X)+αg((Aφ+φA)X,Y) 2g(AφAX,Y). − − Putting X =ξ gives 3 (2.11) Yα=(ξα)η(Y)+2 η (ξ)η (φY). ν ν νX=1 Then, substituting (2.11) into (2.10) the above equation, we have the following 3 α AφAY = (Aφ+φA)Y + η(Y)η (ξ)φξ +η (ξ)η (φY)ξ ν ν ν ν 2 νX=1(cid:8) (cid:9) (2.12) 3 1 1 φY η (Y)φξ +η (φY)ξ +η (ξ)φ Y . ν ν ν ν ν ν − 2 − 2 Xν=1(cid:8) (cid:9) COMMUTING STRUCTURE JACOBI OPERATORS 7 By differentiating and using (2.4), (2.5) and (2.6), we have (grad α)=X(ξα)ξ+(ξα)φAX X ∇ 3 2 q (X)η (ξ) q (X)η (ξ)+2η (φAX) φξ ν+2 ν+1 ν+1 ν+2 ν ν − νX=1n − o 3 2 η (ξ) q (X)φ ξ+q (X)φ ξ+η (ξ)AX ν ν+1 ν+2 ν+2 ν+1 ν − νX=1 n− g(AX,ξ)ξ +φ φAX ν ν − o 3 =X(ξα)ξ+(ξα)φAX 4 η (φAX)φξ ν ν − νX=1 3 2 η (ξ) η (ξ)AX g(AX,ξ)ξ +φ φAX . ν ν ν ν − νX=1 n − o By taking the skew-symmetric part to the above equation, we have 0=X(ξα)η(Y) Y(ξα)η(X)+(ξα)g (Aφ+φA)X,Y − 3 (cid:0) (cid:1) 4 η (φAX)g(φξ ,Y) η (φAY)g(φξ ,X) ν ν ν ν − νX=1n − o 3 +2α η (ξ) η(X)η (Y) η(Y)η (X) ν ν ν νX=1 n − o 3 2 η (ξ) g(φ φAX,Y) g(φ φAY,X) . ν ν ν − νX=1 n − o From this, by putting X =ξ we have the following 3 3 (2.13) Y(ξα)=ξ(ξα)η(Y)+2α η (ξ)η (Y) 2 η (ξ)η (AY). ν ν ν ν − νX=1 νX=1 From this, if we assume that ξα=0, then it follows that 3 3 η (ξ)η (AX)=α η (ξ)η (X). ν ν ν ν νX=1 νX=1 Lemma 2.1. Let M be a Hopf real hypersurface in SU /S(U U ). If the prin- 2,m 2 m · cipal curvature α is constant along the direction of ξ, then the distribution or Q component of the structure vector field ξ is invariant by the shape operator. ⊥ Q 3. Proof of Theorem 1 Let M be a Hopf hypersurface in SU /S(U U ) with 2,m 2 m · (C-1) R φAX =AR φX. ξ ξ The structure Jacobi operator R of M is defined by R X = R(X,ξ)ξ for any ξ ξ tangent vector X T M, p M (see [1] and [7]). Then for any tangent vector p ∈ ∈ 8 HYUNJINLEE,YOUNGJINSUHANDCHANGHWAWOO field X on M in SU /S(U U ), we calculate the structure Jacobi operator R 2,m 2 m ξ · 2R (X)=2R(X,ξ)ξ ξ 3 (3.1) = X+η(X)ξ+ η (X)ξ η(X)η (ξ)ξ ν ν ν ν − − Xν=1(cid:8) +3η (φX)φ ξ+η (ξ)φ φX +2αAX 2η(AX)Aξ, ν ν ν ν − (cid:9) where α denotes the Reeb curvature defined by g(Aξ,ξ). Lemma 3.1. Let M be a Hopf hypersurface in SU /S(U U ) with the commut- 2,m 2 m · ing condition R φAX = AR φX. If the smooth function α is constant along the ξ ξ direction of ξ on M, then the Reeb vector field ξ belongs to either the distribution or the distribution . ⊥ Q Q Proof. To prove this lemma, without loss of generality, ξ may be written as (*) ξ =η(X )X +η(ξ )ξ 0 0 1 1 where X (resp., ξ ) is a unit vector in (resp., ) and η(X )η(ξ )=0. 0 1 ⊥ 0 1 Q Q 6 From (*) and φξ =0, we have φX = η(ξ )φ X , 0 1 1 0 − (3.2) φξ1 =φ1ξ =η(X0)φ1X0,  φ φX =η (ξ)X . 1 0 1 0 LetU= p M α(p)=0 beanopensubsetofM. Fromnowon,wediscussour { ∈ | 6 } argumentsonU. ByvirtueofLemma2.1,ξα=0givesAX =αX andAξ =αξ . 0 0 1 1 The equation (2.12) yields αAφX =(α2 2η2(X ))φX by substituting X =X . 0 0 0 0 − Since α is non-vanishing on U, it becomes (3.3) AφX =σφX , 0 0 where σ = α2−2η2(X0). α From (3.2) and (3.3), we have R (X )=α2X α2η(X )ξ, ξ 0 0 0 − (3.4) R (ξ )=α2ξ α2η(ξ )ξ, ξ 1 1 1  − R (φX )= α2 4η2(X ) φX . ξ 0 0 0 − On U, substituting Xby φX into ((cid:0)C-1), we have(cid:1) 0 (3.5) X η(X )ξ =0, 0 0 − which is a contradiction. Therefore, U = , and thus it must be p M U. Since ∅ ∈ − the setM U=Int(M U) ∂(M U),we considerthe followingtwocases. Here − − ∪ − Int (resp., ∂) denotes an interior (resp., the boundary) of (M U). − Case 1. p Int(M U). • ∈ − Ifp Int(M U),thenα=0. Forthiscase,itwasprovedbytheequation(2.11). ∈ − Case 2. p ∂(M U). • ∈ − Since p ∂M U, there exists a sequence of points p such that p p with n n ∈ − → α(p) = 0 and α(p )= 0. Such a sequence will have an infinite subsequence where n 6 η(ξ ) = 0 (in which case ξ at p, by the continuity) or an infinite subsequence 1 ∈ Q where η(X )=0 (in which case ξ at p). 0 ⊥ ∈Q COMMUTING STRUCTURE JACOBI OPERATORS 9 Accordingly, we get a complete proof of our lemma. (cid:3) FromLemma3.1,weconsiderthecasethatξ belongstothedistribution . Thus ⊥ Q without loss of generality, we may put ξ = ξ . Differentiating ξ = ξ along any 1 1 direction X TM and using (2.5) and (2.6), it gives us ∈ (3.6) 2η (AX)ξ 2η (AX)ξ +φ AX φAX =0. 3 2 2 3 1 − − Then, by using the symmetric (resp., skew-symmetric)property ofthe shape oper- ator A (resp., the structure tensor field φ), we also obtain (3.7) 2η (X)Aξ 2η (X)Aξ +Aφ X AφX =0. 3 2 2 3 1 − − Applying φ to (3.6), it implies 1 (3.8) 2η3(AX)ξ3+2η2(AX)ξ2 AX +αη(X)ξ φ1φAX =0. − − On the other hand, replacing X =φX into (3.6), we have (3.9) 2η2(X)Aξ2 2η3(X)Aξ3+Aφ1φX AX αη(X)ξ =0. − − − − Lemma 3.2. Let M be a Hopf hypersurface in SU /S(U U ), m 3, with 2,m 2 m · ≥ R φA = AR φ. If the Reeb vector field ξ belongs to the distribution , then the ξ ξ ⊥ Q shape operator A commutes with the structure tensor field φ. Proof. Applying ξ =ξ into right hand side (resp., left hand side) of (C-1), we get 1 2R φAX = AφX +2αA2φX 2η (X)Aξ +2η (X)Aξ Aφ X, ξ 3 2 2 3 1 − − − 2AR φX = φAX +2αAφAX 2η (AX)ξ +2η (AX)ξ φ AX. ξ 3 2 2 3 1 − − − Combining (3.6) and (3.7), the above equations become R φAX = AφX +αA2φX, ξ − AR φX = φAX +αAφAX. ξ − Hence, (C-1) is equivalent to (3.10) Aφ φA=αA(Aφ φA) − − Taking the symmetric part of (3.10), we have (3.11) Aφ φA=α(Aφ φA)A. − − From this, we can divide into the following three cases: First, let us consider an open subset U = p M α(p) = 0 of M. Naturally { ∈ | 6 } we can apply (3.10) and (3.11) on the open subset U. (Aφ φA)AX =A(Aφ φA)X. − − Since the shape operator A and the tensor Aφ φA are both symmetric oper- − ators and commute with each other, there exists a common orthonormal basis E which gives a simultaneous diagonalization. Specifically, we have i i=1,...,4m 1 { } − (3.12) AE =λ E , i i i (3.13) (Aφ φA)E =β E , i i i − where λ and β are scalars for all i=1,2,...,4m 1. i i − Taking the inner product with E into (3.13), we have i (3.14) β g(E ,E )=g (Aφ φA)E ,E =2λ g(φE ,E )=0. i i i i i i i i − (cid:0) (cid:1) 10 HYUNJINLEE,YOUNGJINSUHANDCHANGHWAWOO Since g(E ,E )=1, β =0 for all i=1,2,...,4m 1. Hence AφX =φAX for any i i i − tangent vector field X on U. Next, if p Int(M U), then α(p) = 0. From this, the equation (3.11) gives ∈ − (Aφ φA)X(p)=0. − Finally, let us assume that p ∂(M U), where ∂(M U) is the boundary ∈ − − of M U. Then there exists a subsequence p U such that p p. Since n n − { } ⊂ → (Aφ φA)X(p ) = 0 on the open subset U in M, by the continuity we also get n − (Aφ φA)X(p)=0. − Summing up these observations, it is natural that the shape operator A com- mutes with the structure tensor field φ under our assumption. (cid:3) By[11]weassertM withtheassumptionsgiveninlemma3.2islocallycongruent to one of the following hypersurfaces: ( ) a tube over a totally geodesic SU /S(U U ) in SU /S(U U ) A 2,m 1 2 m 1 2,m 2 m T − · − · or, ( ) a horosphere in SU /S(U U ) whose center at infinity is singular and A 2,m 2 m H · of type JX JX. ∈ Inapaperdueto[11],SuhgavesomeinformationrelatedtotheshapeoperatorA of and as follows: A A T H PropositionA. LetM beaconnectedrealhypersurface incomplexhyperbolic two- plane Grassamannian SU /S(U U ), m 3. Assume that the maximal complex 2,m 2 m ≥ subbundle of TM and the maximal quaternionic subbundle of TM are both C Q invariant under the shape operator of M. If JN JN, then one of the following ∈ statements holds: ( ) M has exactly four distinct constant principal curvatures A T α=2coth(2r), β =coth(r), λ =tanh(r), λ =0, 1 2 and the corresponding principal curvature spaces are T =TM , T = , T =E , T =E . α ⊖C β C⊖Q λ1 −1 λ2 +1 The principal curvature spaces T and T are complex (with respect to J) λ1 λ2 and totally complex (with respect to J). ( ) M has exactly three distinct constant principal curvatures A H α=2, β =1, λ=0 with corresponding principal curvature spaces T =TM , T =( ) E , T =E . α β 1 λ +1 ⊖C C⊖Q ⊕ − Here, E and E are the eigenbundles of φφ with respect to the +1 1 1 − |Q eigenvaleus +1 and 1, respectively. − Since the symmetric tensor Aφ φA vanishes identically on (resp. ), it A A − T H triviallysatisfies(3.10). Henceweassertthat (resp., )incomplexhyperbolic A A T H two-planeGrassmanniansSU /S(U U )hastheourcommutingcondition(C-1) 2,m 2 m · (see [11]). Next, due to Lemma 3.1, let us suppose that ξ (i.e., JN JN). ∈Q ⊥ By virtue of the result in [13], we assert that a Hopf hypersurface M in complex hyperbolictwo-planeGrassmanniansSU /S(U U )satisfyingthehypothesesin 2,m 2 m · Theorem 1 is locally congruent to