Remarks on inequalities for the Casorati curvatures of slant submanifolds in quaternionic space forms

In this paper, we obtain an inequality for the normalized Casorati curvature of slant submanifolds in quaternionic space forms by using T Oprea’s optimization method.

MSC:53C40, 53D12.

The Casorati curvature of an n-dimensional submanifold M of a Riemannian manifold, usually denoted by $\mathcal{C}$, is an extrinsic invariant defined as the normalized square of the length of the second fundamental form of the submanifold. In [1], Decu et al. introduced the normalized δ-Casorati curvatures ${\delta }_c(n-1)$ and ${\hat{\delta }}_c(n-1)$ by

and

where $x\in M$, and established some inequalities involving these invariants for submanifolds in real space forms. Later, Slesar et al. proved two inequalities relating the above normalized Casorati curvatures for a slant submanifolds in a quaternionic space form in [2]. However, it was pointed out that the coefficient $\frac{n+1}{2n(n-1)}$ in (1) is inappropriate and must be replaced by $\frac{n+1}{2n}$ [3, 4]. Following [3, 4], we define the normalized δ-Casorati curvature ${\delta }_C(n-1)$ by

By using T Oprea’s optimization method on Riemannian submanifolds, we establish the following inequalities in terms of ${\delta }_C(n-1)$ for θ-slant proper submanifolds of a quaternionic space form.

Theorem 1 Let $M^n$, $n\ge 3$, be θ-slant proper submanifold of a quaternionic space form ${\overline{M}}^{4m}(c)$. Then the normalized δ-Casorati curvature ${\delta }_C(n-1)$ satisfies

where ρ is the normalized scalar curvature of $M^n$. Moreover, the equality case holds if and only if $M^n$ is an invariantly quasi-umbilical submanifold with trivial normal connection in ${\overline{M}}^{4m}(c)$, such that with respect to suitable orthonormal tangent frame $\{{\xi }_1,\dots ,{\xi }_n\}$ and normal orthonormal frame $\{{\xi }_{n+1},\dots ,{\xi }_{4m}\}$, the shape operators $A_r=A_{e_r}$, $r\in \{n+1,\dots ,4m\}$, take the following forms:

Let $(M^n,g)$ be an n-dimensional submanifold in an $(n+p)$-dimensional Riemannian manifold $({\overline{M}}^{n+p},\overline{g})$. The Levi-Civita connections on ${\overline{M}}^{n+p}$ and $M^n$ will be denoted by $\overline{\mathrm{\nabla }}$ and ∇, respectively. For all $X,Y\in C^{\mathrm{\infty }}(TM)$, $N\in C^{\mathrm{\infty }}(T{M}^{\mathrm{\perp }})$, the Gauss and Weingarten formulas can be expressed by

where h is the second fundamental form of M, $\overline{\mathrm{\nabla }}$ is the normal connection and the shape operator $A_N$ of M is given by

The submanifold M is said to be totally geodesic if $h=0$. Besides, M is called invariantly quasi-umbilical if there exist p mutually orthogonal unit normal vectors ${\xi }_{n+1},\dots ,{\xi }_{n+p}$ such that the shape operators with respect to all directions ${\xi }_r$ have an eigenvalue of multiplicity $n-1$ and that for each ${\xi }_r$ the distinguished eigendirection is the same [1–4].

In ${\overline{M}}^{n+p}$ we choose a local orthonormal frame $e_1,\dots ,e_n,e_{n+1},\dots ,e_{n+p}$, such that, restricting ourselves to $M^n$, $e_1,\dots ,e_n$ are tangent to $M^n$. We write $h_{ij}^r=g(h(e_i,e_j),e_r)$. Then the mean curvature vector H is given by

and the squared norm of h over dimension n is denoted by $\mathcal{C}$ and is called the Casorati curvature of the submanifold M. Therefore we have

Let $K(e_i\wedge e_j)$, $1\le i<j\le n$, denote the sectional curvature of the plane section spanned by $e_i$ and $e_j$. Then the scalar curvature of $M^n$ is given by

and the normalized scalar curvature ρ is defined by

Suppose L is an l-dimensional subspace of $T_{x}M$, $x\in M$, $l\ge 2$ and $\{e_1,\dots ,e_l\}$ an orthonormal basis of L. Then the scalar curvature $\tau (L)$ of the l-plane L is given by

and the Casorati curvature $\mathcal{C}(L)$ of the subspace L is defined as

For more details of slant submanifolds in quaternionic space forms, we refer to [2, 4].

Let $(N_2,\overline{g})$ be a Riemannian manifold, $N_1$ be a Riemannian submanifold of it, g be the metric induced on $N_1$ by $\overline{g}$ and $f:N_1\to \mathbb{R}$ be a differentiable function.

Following [5–7] we considered the constrained extremum problem

then we have the following.

Lemma 1 ([5])

If $x_0\in N_1$ is the solution of the problem (4), then

1. (i)

   $(gradf)(x_0)\in T_{x_0}^{\perp }{N}_1$;

2. (ii)

   the bilinear form

   $$\begin{array}{c}\mathcal{A}:T_{x_0}{N}_1\times T_{x_0}{N}_1\to \mathbb{R};\hfill \\ \mathcal{A}(X,Y)={Hess}_f(X,Y)+\overline{g}(h(X,Y),(gradf)(x_0))\hfill \end{array}$$

is positive semidefinite, where h is the second fundamental form of $N_1$ in $N_2$.

In [6], the above lemma was successfully applied to improve an inequality relating $\delta (2)$ obtained in [8]. Later, Chen extended the improved inequality to the general inequalities involving δ-invariants $\delta (n_1,\dots ,n_k)$ [9]. More details of δ-invariants can be found in [10–15]. Besides, the first author gave another proof of the inequalities relating the normalized δ-Casorati curvature ${\hat{\delta }}_c(n-1)$ for submanifolds in real space forms by using T Oprea’s optimization method [16].

From the Gauss equation we can easily obtain (see (12) in [2])

We define now the following function, denoted by $\mathcal{Q}$, which is a quadratic polynomial in the components of the second fundamental form:

Without loss of generality, by assuming that L is spanned by $e_1,\dots ,e_{n-1}$, one gets

here we used (5) and (6).

From (7) we have

For $\alpha =n+1,\dots ,4m$, let us consider the quadratic form

and the constrained extremum problem

where $k^{\alpha }$ is a real constant.

The partial derivatives of the function $f_{\alpha }$ are

For an optimal solution $(h_{11}^{\alpha },h_{22}^{\alpha },\dots ,h_{nn}^{\alpha })$ of the problem in question, the vector $grad{f}_{\alpha }$ is normal at Ϝ, that is, it is collinear with the vector $(1,1,\dots ,1)$. From (9), (10), (11), and (12), it follows that a critical point of the considered problem has the form

As ${\sum }_{i=1}^n{h}_{ii}^{\alpha }=k^{\alpha }$, by using (13) we have

We fix an arbitrary point $x\in Ϝ$. The 2-form $\mathcal{A}:T_xϜ\times T_xϜ\to \mathbb{R}$ has the expression

where $h^{\prime }$ is the second fundamental form of Ϝ in ${\mathbb{R}}^n$ and $〈,〉$ is the standard inner-product on ${\mathbb{R}}^n$. In the standard frame of ${\mathbb{R}}^n$, the Hessian of $f_{\alpha }$ has the matrix

As Ϝ is totally geodesic in ${\mathbb{R}}^n$, considering a vector X tangent to Ϝ at the arbitrary point x on Ϝ, that is, verifying the relation ${\sum }_{i=1}^n{X}_i=0$, we have

Thus the point $(h_{11}^{\alpha },h_{22}^{\alpha },\dots ,h_{nn}^{\alpha })$ given by (14) is a global minimum point, here we used Lemma 1. Inserting (14) in (8) we have

From (2), (6), and (15) we can derive inequality (3). The equality case of (3) holds if and only if we have the equality in all the previous inequalities. Thus

We would like to thank to Professor Weidong Song, who has always been generous with his time and advice.

Authors and Affiliations

1. School of Mathematics and Computer Science, Anhui Normal University, Huajing South Road, Yijiang District, Wuhu, Anhui, 241000, P.R. China

   Pan Zhang & Liang Zhang

Corresponding author

Correspondence to Liang Zhang.

Competing interests

The authors declare that they have no competing interests.

Authors’ contributions

All authors contributed equally and significantly in writing this paper. All authors read and approved the final manuscript.

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