Inequalities of warped product submanifolds in a Riemannian manifold of quasi-constant curvature

Jiahui Wang; Lijuan Cheng; Yecheng Zhu

doi:10.52396/JUSTC-2021-0217

JUSTC > 2022 > 52(3): 6-1-6-8. > DOI: 10.52396/JUSTC-2021-0217 CSTR: 32290.14.JUSTC-2021-0217

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Open Access JUSTC Mathematics Article 10 May 2022

Inequalities of warped product submanifolds in a Riemannian manifold of quasi-constant curvature

School of Mathematics and Physics, Anhui University of Technology, Maanshan 243002, China

Cite this: JUSTC, 2022, 52(3): 6

https://doi.org/10.52396/JUSTC-2021-0217

CSTR: 32290.14.JUSTC-2021-0217

Funds: Supported by NSFC (No.12026262)

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Author Bio:
Jiahui Wang is currently a graduate student at the Anhui University of Technology. Her research interests mainly focus on warped product submanifolds and isoparametric hypersurfaces

Yecheng Zhu received his PhD from the University of Science and Technology of China. He is currently an associate professor at the Anhui University of Technology. He is mainly engaged in differential geometry
Corresponding author:
Yecheng Zhu, E-mail: zhuyc929@mail.ustc.edu.cn
Received Date: October 08, 2021
Accepted Date: January 20, 2022
Available Online: May 10, 2022

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Abstract

Abstract

By optimization methods on Riemannian submanifolds, we establish two inequalities between the intrinsic and extrinsic invariants, for generalized normalized δ-Casorati curvatures of warped product submanifolds in a Riemannian manifold of quasi-constant curvature. We generalize the conclusions of the optimal inequalities of submanifolds in real space forms.

Graphical Abstract

The process of establishing the generalized normalized δ-Casorati curvatures inequality.

Abstract

By optimization methods on Riemannian submanifolds, we establish two inequalities between the intrinsic and extrinsic invariants, for generalized normalized δ-Casorati curvatures of warped product submanifolds in a Riemannian manifold of quasi-constant curvature. We generalize the conclusions of the optimal inequalities of submanifolds in real space forms.
Public Summary
- We establish Chen-like inequalities for generalized normalized δ-Casorati curvatures of warped product submanifolds in a Riemannian manifold of quasi-constant curvature.
- Our inequalities extend the optimal inequalities involving the scalar curvature and the Casorati curvature of a Riemannian submanifold in a real space form.

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1. Introduction

In 1993, Chen^[1] introduced $\delta$ -invariants, and established relationships between intrinsic invariants and extrinsic invariants for minimal submanifolds. In 1995, Chen ^[2] found Chen-like inequalities for Riemannian submanifolds and gave some applications of $\delta$ -invariants. Submanifolds are ideal submanifolds when Chen-like inequalities are equal and they receive the least possible tension at each point from ambient spaces.

The Casorati curvature was originally introduced in $1980$ for surfaces in $3$ -dimensional Euclidean space and is defined as the normalized square of the length of the second fundamental form (see Ref. [3]). In 2007, Decu et al. ^[4] introduced the normalized $\delta$ -Casorati curvatures $\widehat{\delta_C}(n-1)$ and $\delta_C(n-1)$ and established two optimal inequalities involving the scalar curvature and the normalized $\delta$ -Casorati curvature. In $2008$ , Decu et al.^[5] introduced the generalized normalized $\delta$ -Casorati curvatures $\widehat{\delta_C}(r;n-1)$ and $\delta_C(r;n-1)$ and proved two sharp inequalities. In 2017, Park^[6] obtained two types of optimal inequalities for the real hypersurfaces of complex two-plane Grassmannians and complex hyperbolic two-plane Grassmannians. In 2020, Choudhary and Blaga^[7] established some sharp inequalities involving generalized normalized $\delta$ -Casorati curvatures for invariant, anti-invariant and slant submanifolds in metallic Riemannian space forms and characterized the submanifolds for which the equality holds.

In this study, we establish Chen-like inequalities for generalized normalized $\delta$ -Casorati curvatures of warped product submanifolds in a Riemannian manifold of quasi-constant curvature.

Let $N_1^p$ and $N_2^q$ be two Riemannian manifolds with positive dimensions equipped with Riemannian metrics $g_{N_1^p}$ and $g_{N_2^q}$ , respectively. Let $f$ be a positive function on $N_1^p$ . Consider the product manifold $N_1^p{\times}N_2^q$ , with its projections $\pi:N_1^p {\times} N_2^q {\rightarrow} N_1^p$ and $\eta : N_1^p {\times} N_2^q {\rightarrow} N_2^q$ . The warped product manifold $M^n = N_1^p {\times}$ ${}_f N_2^q$ is the product manifold $N_1^p {\times} N_2^q$ equipped with a Riemannian structure such that

$\begin{align} {\parallel}X{\parallel}^2 = {\parallel}{\pi_*(X)}{\parallel}^2+f^2(\pi(x)){\parallel}{\eta_*(X)}{\parallel}^2 \end{align}$

(1)

for any tangent vector $X {\in} T_xM^n$ . Thus, we have $g = g_{N_1^p} +$ $f^2g_{N_2^q}$ . The function $f$ is called the warping function of the warped product manifold.

A Riemannian manifold $(\widetilde{M}^m,\tilde{g})$ is called a Riemannian manifold of quasi-constant curvature if the curvature tensor satisfies the following condition (see Ref. [8]):

$\begin{split} \widetilde{R}(X,Y,Z,W) = &a\big[\tilde{g}(X,Z)\tilde{g}(Y,W)-\tilde{g}(Y,Z)\tilde{g}(X,W)\big]+\\&b\big[\tilde{g}(X,Z)T (Y)T(W)-\tilde{g}(X,W)T(Y)T(Z)+\\&\tilde{g}(Y,W)T(X)T (Z)-\tilde{g}(Y,Z)T(X)T(W)\big]\end{split}$

(2)

where $a$ and $b$ are scalar functions, $T$ is a $1$ -form defined by

$\begin{equation} T(X) = \tilde{g}(X,P) \end{equation}$

(3)

where $P$ denotes the unit vector field. We uniquely decompose the vector field $P$ on $M^n$ into its tangent component $P^T$ and normal component $P^{\perp}$ , that is,

$\begin{align} P = P^T+P^{\perp} \end{align}$

(4)

Theorem 1.1. Let ${\phi}:M^n = N_1^p{\times}_fN_2^q{\rightarrow}\widetilde{M}^m$ be an isometric immersion of an $n$ -dimensional warped product submanifold $M^n$ into an $m$ -dimensional Riemannian manifold of a quasi-constant curvature $\widetilde{M}^m$ . Then

${\rm{(i)}}$ the generalized normalized $\delta$ -Casorati curvature $\delta_C(r;$ $n-1)$ satisfies

$\begin{split} &\dfrac{2}{n(n-1)}\times\Bigg\{\frac{q{\Delta}f}{f}+\frac{p(p-1)a}{2}+b(p-1){{\parallel}P^T{\parallel}}^2_{N_1^p}+\frac{q(q-1)a}{2}+\\&b(q- 1){{\parallel}P^T{\parallel}}^2_{N_2^q}\Bigg\}+\frac{{\delta_C}(r;n-1)}{n(n-1)}-\frac{npr(n^2-n+qr-r){{\parallel}H{\parallel}}^2 }{(n-1) \big\{(n^2-n-r+qr)^2+p^2r^2\big\}}\geqslant \rho \end{split}$

(5)

for any real number $r$ such that $0<r<n(n-1)$ , where ${{\parallel}P^T{\parallel}}^2_{N_1^p} = {\sum\nolimits_{i = 1}^{p}} g(P^T,e_i)^2$ , ${{\parallel}P^T{\parallel}}^2_{N_2^q} = {\sum\nolimits_{s = p+1}^{n}}g(P^T,e_s)^2$ , $\rho$ is the normalized scalar curvature, ${{\parallel}H{\parallel}}^2$ is the squared mean curvature, $a$ and $b$ are scalar functions;

${\rm{(ii)}}$ the generalized normalized $\delta$ -Casorati curvature $\widehat{\delta_C}(r;n-1)$ satisfies

$\begin{split} &\dfrac{2}{n(n-1)}\times\Bigg\{\frac{q{\Delta}f}{f}+\frac{p(p-1)a}{2}+b(p-1){{\parallel}P^T{\parallel}}^2_{N_1^p}+\frac{q(q-1)a}{2}+\\ &b(q- 1){{\parallel}P^T{\parallel}}^2_{N_2^q}\Bigg\}+\frac{\widehat{\delta_C}(r;n-1)}{n(n-1)}-\frac{npr(n^2-n+qr-r){{\parallel}H{\parallel}}^2 }{(n-1) \big\{(n^2-n-r+qr)^2+p^2r^2\big\}}\geqslant\rho \end{split}$

(6)

for any real number $r>n(n-1)$ .

Equalities hold in (5) and (6) if and only if the shape operators for the suitable tangent and normal orthonormal frames are given by

$\left. {\begin{split} & A_{e_{n+1}} =\\&\left(\begin{array}{ccccccccc} h_{11}^{n+1}&0&\cdots&0&0&0&\cdots&0&0\\ 0&h_{22}^{n+1}&\cdots&0&0&0&\cdots&0&0\\ \vdots&\vdots&\ddots&\vdots&\vdots&\vdots&\ddots&\vdots&\vdots\\ 0&0&\cdots&h_{pp}^{n+1}&0&0&\cdots&0&0\\ 0&0&\cdots&0&h_{p+1p+1}^{n+1}&0&\cdots&0&0\\ 0&0&\cdots&0&0&h_{p+2p+2}^{n+1}&\cdots&0&0\\ \vdots&\vdots&\ddots&\vdots&\vdots&\vdots&\ddots&\vdots&\vdots\\ 0&0&\cdots&0&0&0&\cdots&h_{n-1n-1}^{n+1}&0\\ 0&0&\cdots&0&0&0&\cdots&0&h_{nn}^{n+1} \end{array} \right),\\ &h_{11}^{n+1} = \cdots = h_{pp}^{n+1} = pr^2f_1e_{n+1},\\&h_{p+1p+1}^{n+1} = \cdots = h_{n-1n-1}^{n+1} = (n^2-n+qr-r)rf_1e_{n+1},h_{nn}^{n+1} =\\ & n(n-1)(n^2-n+qr-r)f_1e_{n+1}, \\ & h_{ij}^{n+1} = 0, i\neq j,\\ &A_{e_{n+2}} = \cdots = A_{e_{n+m}} = 0 \end{split}} \right\}$

(7)

where $f_1$ is a function on $M^n$ .

Let $b = 0$ and $a = {\rm{const}}$ . Then we have

Corollary 1.1. Let ${\phi}:M^n = N_1^p{\times}_fN_2^q{\rightarrow}\widetilde{M}^m(a)$ be an isometric immersion of an $n$ -dimensional warped product submanifold $M^n$ into an $m$ -dimensional Riemannian manifold of a constant sectional curvature $a$ . Then

${\rm{(i)}}$ the generalized normalized $\delta$ -Casorati curvature $\delta_C(r;$ $n-1)$ satisfies

$\begin{split} &\dfrac{2}{n(n-1)}\times\Big\{\frac{q{\Delta}f}{f}+\frac{p(p-1)a}{2}+\frac{q(q-1)a}{2}\Big\}+\frac{{\delta_C}(r;n-1)}{n(n-1)}-\\ &\frac{npr(n^2-n+qr-r){{\parallel}H{\parallel}}^2 }{(n-1)\big\{(n^2-n-r+qr)^2+p^2r^2\big\}}{\geqslant}\rho \\\end{split}$

(8)

for any real number $r$ such that $0<r<n(n-1)$ ;

${\rm{(ii)}}$ the generalized normalized $\delta$ -Casorati curvature $\widehat{\delta_C}(r;$ $n-1)$ satisfies

$\begin{split} &\dfrac{2}{n(n-1)}\times\bigg\{\frac{q{\Delta}f}{f}+\frac{p(p-1)a}{2}+\frac{q(q-1)a}{2}\bigg\}+\frac{\widehat{\delta_C}(r;n-1)}{n(n-1)}-\\ &\frac{npr(n^2-n+qr-r){{\parallel}H{\parallel}}^2 }{(n-1)\big\{(n^2-n-r+qr)^2+p^2r^2\big\}}{\geqslant}\rho \\[-10pt]\end{split}$

(9)

for any real number $r>n(n-1)$ .

Equalities hold in (8) and (9) if and only if the shape operators for the suitable tangent and normal orthonormal frames are given by Eq. (7).

Moreover, let $p = 0,q = n$ and $f = 1$ . Then we have

Corollary 1.2. Let ${\phi}:M^n{\rightarrow}\widetilde{M}^m(a)$ be an isometric immersion of an $n$ -dimensional warped product submanifold into $\widetilde{M}^m(a)$ . We have

${\rm{(i)}}$ for any real number $r$ such that $0 < r < n(n-1)$ ,

$\begin{align} {\delta_C}(r;n-1)+n(n-1)a{\ge}n(n-1)\rho \end{align}$

(10)

${\rm{(ii)}}$ for any real number $r$ such that $r>n(n-1)$ ,

$\begin{align} \widehat{\delta_C}(r;n-1)+n(n-1)a{\ge}n(n-1)\rho \end{align}$

(11)

Equalities hold in (10) and (11) if and only if $M^n$ is an invariantly quasi-umbilical submanifold.

Remark: Corollary 1.2 is Theorem 2.1, and Corollary 3.1 in Ref. [5].

2. Preliminaries

Let $M^n$ be an $n$ -dimensional warped product submanifold of an $m$ -dimensional Riemannian manifold of quasi-constant curvature ${\widetilde{M}}^m$ . Let $\nabla$ and $\widetilde{\nabla}$ be the ${\rm{Levi}}$ – ${\rm{Civita}}$ connection on $M^n$ and $\widetilde{M}^m$ , respectively. Then, the Gauss and Weingarten formulas are given respectively by

$\left. {\begin{split} &\widetilde{\nabla}_XY = {\nabla}_XY+h(X,Y) \\ &\widetilde{\nabla}_XN = -A_NX+\nabla_X^{\perp}N \end{split}} \right\}$

(12)

for vector fields $X$ , $Y$ tangent to $M^n$ , and vector field $N$ normal to $M^n$ . Here $h$ denotes the second fundamental form, $\nabla^{\perp}$ is the normal connection and $A$ is the shape operator. The second fundamental form and shape operator are related by

$\begin{align} \tilde{g}(h(X,Y),N) = g(A_NX,Y) \end{align}$

(13)

where $\tilde{g}$ and $g$ denote the metric on $\widetilde{M}^m$ and $M^n$ respectively. If $R$ and $\widetilde{R}$ are the curvature tensors of $M^n$ and ${\widetilde{M}}^m$ , respectively, then the Gauss equation is given by

$\begin{split} &R(X,Y,Z,W) = \widetilde{R}(X,Y,Z,W)+\tilde{g}(h(X,Z),h(Y,W))-\\&\tilde{g}(h(X,W),h(Y,Z)) \\[-10pt]\end{split}$

(14)

for any vector field $X$ , $Y$ , $Z$ , and $W$ tangent to $M^n$ .

Let $\{e_1,\cdots,e_n\}$ be an orthonormal basis of the tangent space $T_xM^n$ and let $\{e_{n+1},\cdots, e_m\}$ be an orthonormal basis of normal space $T^{\perp}_xM^n$ . The mean curvature vector $H$ at $x$ is

$\begin{align} H(x) = \frac{1}{n}{\sum\limits_{\alpha = n+1}^{m}}\left( {{\sum\limits_{i = 1}^{n}}h_{{i}{i}}^{\alpha}} \right)e_{\alpha} \end{align}$

(15)

The squared mean curvature of the submanifold $M^n$ in $\widetilde{M}^m$ is defined as

$\begin{align} {{\parallel}H{\parallel}}^2 = \frac{1}{n^2}{\sum\limits_{\alpha = n+1}^{m}}\left( {{\sum\limits_{i = 1}^{n}}h_{ii}^{\alpha}} \right)^2 \end{align}$

(16)

Also, we set

$\left. {\begin{array}{r} h_{ij}^{\alpha} =\tilde{g}(h(e_i,e_j),e_{\alpha})\\ {{\parallel}h{\parallel}}^2 = {\sum\limits_{\alpha = n+1}^{m}} \ {\sum\limits_{i,j = 1}^{n}}\tilde{g}(h(e_{i},e_{j}),e_\alpha)^2 \end{array}} \right\}$

(17)

Let $K(e_{i}{\wedge}e_{j})$ be the sectional curvature of the plane section spanning $e_{i}$ and $e_{j}$ at $x{\in}M^n$ . Subsequently, the scalar curvature $\tau(x)$ of $M^n$ is given by

$\begin{align} \tau(x) = \sum\limits_{1{\le}{i}<{j}{\le}n}K(e_{i}{\wedge}e_{j}) \end{align}$

(18)

and the normalized scalar curvature $\rho$ of $M^n$ at $x$ is defined as

$\begin{align} \rho(x) = \frac{2\tau(x)}{n(n-1)} \end{align}$

(19)

The Casorati curvature ${\cal{C}}$ of the submanifold $M^n$ is the squared norm of the second fundamental form $h$ over dimension $n$ and is given by

$\begin{align} {\cal{C}} = \frac{1}{n}\sum\limits_{\alpha = n+1}^{m}{\sum\limits_{i,j = 1}^{n}}(h_{ij}^{\alpha})^2 \end{align}$

(20)

If $L$ is an $l$ -dimensional subspace of $T_xM^n$ , where $l{\geqslant}2$ and $\{e_1,{\cdots},e_l\}$ is an orthonormal basis of $L$ , the scalar curvature $\tau(L)$ of the $l$ -plane section $L$ is defined as

$\begin{align} \tau(L) = \sum\limits_{1{\le}{i}<{j}{\le}l}K(e_{i}{\wedge}e_{j}) \end{align}$

(21)

and the Casorati curvature of the subspace $L$ , denoted by ${\cal{C}}(L)$ , is given by

$\begin{align} {\cal{C}}(L) = \frac{1}{l}\sum\limits_{\alpha = n+1}^{m}{\sum\limits_{i,j = 1}^{l}}(h_{ij}^{\alpha})^2 \end{align}$

(22)

The generalized normalized $\delta$ –Casorati curvatures $\delta_C(r;$ $n-1)$ and $\widehat{\delta_C}(r;n-1)$ of the submanifold $M^n$ are defined for a positive real number $r{\ne}n(n-1)$ as

$\begin{split} &[\delta_C(r;n-1)]_x = r{\cal{C}}_x+\frac{(n-1)(n+r)(n^2-n-r)}{rn}\inf\{{\cal{C}}(L)|L: {\rm{a}} \;\\& {\rm{hyperplane}} \;\; {\rm{of}} \;\; T_xM^n \} \\[-10pt]\end{split}$

(23)

if $0<r<n^2-n$ ; and

$\begin{split} &[\widehat{\delta_C}(r;n-1)]_x = r{\cal{C}}_x-\frac{(n-1)(n+r)(r-n^2+n)}{rn}\sup\{{\cal{C}}(L)|L: {\rm{a}} \;\\& {\rm{hyperplane}} \;\; {\rm{of}} \;\; T_xM^n \} \\[-10pt]\end{split}$

(24)

if $r>n^2-n$ .

By Gauss equation, we get

$\begin{align} K(e_{i}{\wedge}e_{j}) = \widetilde{K}(e_{i}{\wedge}e_{j})+\sum\limits_{\alpha = n+1}^{m}(h_{{i}{i}}^{\alpha}h_{jj}^{\alpha}-{(h_{ij}^{\alpha})}^2) \end{align}$

(25)

where $K(e_{i}{\wedge}e_{j})$ and $\widetilde{K}(e_{i}{\wedge}e_j)$ denote the sectional curvatures of the plane section spanned by $e_{i}$ and $e_{j}$ at $x$ in the submanifold $M^n$ and in the ambient manifold $\widetilde{M}^m$ , respectively. By Eqs. $(2)$ and $(25)$ , we have

$\begin{split} \tau(N_1^p)& = {\sum\limits_{\alpha = n+1}^{m}} \ {\sum\limits_{1{\le}i<j{\le}p}}(h_{ii}^{\alpha}h_{jj}^{\alpha}-(h_{ij}^{\alpha})^2)+\tilde{\tau}(N_1^p) =\\ & \frac{p(p-1)a}{2}+b(p-1){{\parallel}P^T{\parallel}}^2_{N_1^p}+{\sum\limits_{\alpha = n+1}^{m}} \ {\sum\limits_{1{\le}i<j{\le}p}}(h_{ii}^{\alpha}h_{jj}^{\alpha}-(h_{ij}^{\alpha})^2) \end{split}$

(26)

$\begin{split} \tau(N_2^q)& = {\sum\limits_{\alpha = n+1}^{m}} \ {\sum\limits_{p+1{\le}s<t{\le}n}}(h_{ss}^{\alpha}h_{tt}^{\alpha}-(h_{st}^{\alpha})^2)+\tilde{\tau}(N_2^q) =\\ & \frac{q(q-1)a}{2}+b(q-1){{\parallel}P^T{\parallel}}^2_{N_2^q}+{\sum\limits_{\alpha = n+1}^{m}} \ {\sum\limits_{p+1{\le}s<t{\le}n}}(h_{ss}^{\alpha}h_{tt}^{\alpha}-(h_{st}^{\alpha})^2) \end{split}$

(27)

where ${{\parallel}P^T{\parallel}}^2_{N_1^p} = {\sum\nolimits_{i = 1}^{p}} g(P^T,e_i)^2$ , ${{\parallel}P^T{\parallel}}^2_{N_2^q} = {\sum\nolimits_{s = p+1}^{n}}g(P^T,e_s)^2$ .

Definition 2.1. For the differential function $f$ on $M^n$ , the Laplacian ${\Delta}f$ and gradient ${\nabla}f$ of $f$ are defined by

$\begin{align} &g({\nabla}f,X) = X(f) \end{align}$

(28)

$\begin{align} &{\Delta}f = \sum\limits_{i = 1}^{n}(({\nabla}_{e_{i}}e_{i})f-e_{i}e_{i}f) \end{align}$

(29)

for any vector field $X$ that is tangent to $M^n$ .

Lemma 2.1.^[9] Let $M^n = N_1^p{\times}_fN_2^q$ be a warped product submanifold of $\widetilde{M}^m$ . The relation between the sectional curvature and Laplacian ${\Delta}f$ of $f$ is

$\begin{align} {\sum\limits_{l = 1}^{p}}{\sum\limits_{k = p+1}^{n}}K(e_{l}{\wedge}{e_{k}}) = \frac{q{\Delta}f}{f} = q({\Delta}{\ln}f-{{\parallel}{{\nabla}{\ln}f}{\parallel}}^2) \end{align}$

(30)

Lemma 2.2.^[10] Let $N_1$ be a Riemannian submanifold of a Riemannian manifold $(N_2,\bar{g})$ , $\varphi:N_2{\rightarrow}{\mathbb{R}}$ be a differentiable function and consider the constrained extremum problem

$\begin{align} \mathop{{\rm{min}}}\limits_{x{\in}N_1}\varphi(x) \end{align}$

(31)

If $x_0{\in}N_1$ is a solution of the problem $(31)$ , then

${\rm{(i)}}$ $({\rm{grad}} \ \varphi)(x_0){\in}T_{x_0}^{\perp}N_1$ ;

${\rm{(ii)}}$ the bilinear form $\Lambda:T_{x_0}N_1{\times}T_{x_0}N_1{\rightarrow}{\mathbb{R}}$ defined by

$\begin{align} \Lambda(X,Y) = {\rm{Hess}}_{\varphi}(X,Y)+\bar{g}\big(h_1(X,Y),({\rm{grad}} \ \varphi)(x_0)\big) \end{align}$

(32)

is positive semi-definite, where $h_1$ is the second fundamental form of $N_1$ in $N_2$ and grad $\varphi$ is the gradient of $\varphi$ .

3. Proof of the theorem

Proof of Theorem 1.1 From Eqs. $(26)$ , $(27)$ , $(30)$ , and the Gauss equation, we obtain

$\begin{split} &\tau{(x)} = \sum\limits_{l = 1}^{p}\sum\limits_{k = p+1}^{n}K(e_l{\wedge}e_k)+\sum\limits_{1{\le}i<j{\le}p}K(e_i{\wedge}e_j)+\sum\limits_{p+1{\le}s<t{\le}n}K(e_s{\wedge}e_t) =\\ &\frac{q{\Delta}f}{f}+\frac{p(p-1)a}{2}+b(p-1){{\parallel}P^T{\parallel}}^2_{N_1^p}+\frac{q(q-1)a}{2}+b(q-1){{\parallel}P^T{\parallel}}^2_{N_2^q}+\\ &{\sum\limits_{\alpha = n+1}^{m}}\ {\sum\limits_{1{\le}i<j{\le}p}}(h_{ii}^{\alpha}h_{jj}^{\alpha}-(h_{ij}^{\alpha})^2)+{\sum\limits_{\alpha = n+1}^{m}}\ {\sum\limits_{p+1{\le}s<t{\le}n}}(h_{ss}^{\alpha}h_{tt}^{\alpha}-(h_{st}^{\alpha})^2) \end{split}$

(33)

We define the following quadratic polynomial ${\cal{P}}$ in the components of the second fundamental form as

$\begin{split} {\cal{P}} = &r{{\cal{C}}}+\frac{(n-1)(n+r)(n^2-n-r)}{nr}{{\cal{C}}(L)}-2{\tau} +2\times\Big\{\frac{q{\Delta}f}{f}+\\ &\frac{p(p-1)a}{2}+b(p-1){{\parallel}P^T{\parallel}}^2_{N_1^p}+\frac{q(q-1)a}{2}+b(q-1){{\parallel}P^T{\parallel}}^2_{N_2^q}\Big\} \end{split}$

(34)

where $L$ denotes the hyperplane of $T_xM^n$ . Without loss of generality, we can suppose that $L$ is spanned by $e_1,e_2,\cdots,e_{n-1}$ . From Eqs. $(33)$ and $(34)$ , we have

$\begin{align} {\cal{P}} = &\frac{r}{n}{\sum\limits_{\alpha = n+1}^{m}} \ {\sum\limits_{i,j = 1}^{n}}(h_{ij}^{\alpha})^2+\frac{(n+r)(n^2-n-r)}{nr}{\sum\limits_{\alpha = n+1}^{m}} \ {\sum\limits_{i,j = 1}^{n-1}}(h_{ij}^{\alpha})^2-\\ &2{\sum\limits_{\alpha = n+1}^{m}} \ {\sum\limits_{1{\leqslant}i<j{\leqslant}p}}(h_{ii}^{\alpha}h_{jj}^{\alpha}-(h_{ij}^{\alpha})^2)-2{\sum\limits_{\alpha = n+1}^{m}} \ {\sum\limits_{p+1{\leqslant}s<t{\leqslant}n}}(h_{ss}^{\alpha}h_{tt}^{\alpha}-(h_{st}^{\alpha})^2){\geqslant}\\ &\frac{n^2-n+nr-2r}{r}{\sum\limits_{\alpha = n+1}^{m}} \ {\sum\limits_{i = 1}^{n-1}}(h_{ii}^{\alpha})^2+\frac{r}{n}{\sum\limits_{\alpha = n+1}^{m}}(h_{nn}^{\alpha})^2-\\ &2{\sum\limits_{\alpha = n+1}^{m}} \ {\sum\limits_{1{\leqslant}i<j{\leqslant}p}}h_{ii}^{\alpha}h_{jj}^{\alpha}-2{\sum\limits_{\alpha = n+1}^{m}} \ {\sum\limits_{p+1{\leqslant}s<t{\leqslant}n}}h_{ss}^{\alpha}h_{tt}^{\alpha} \end{align} \\[-12pt]$

(35)

We consider the quadratic forms

$\begin{align} \varphi_{\alpha}:{\mathbb{R}}^n{\rightarrow}{\mathbb{R}},\qquad \alpha = n+1,n+2,\cdots,m \end{align}$

(36)

defined by

$\begin{split} \varphi_{\alpha}{(h_{11}^{\alpha},{\cdots},h_{nn}^{\alpha})} = &\frac{n^2-n+nr-2r}{r}{\sum\limits_{i = 1}^{n-1}}(h_{ii}^{\alpha})^2+\frac{r}{n}(h_{nn}^{\alpha})^2-\\ &2{\sum\limits_{1{\leqslant}i<j{\leqslant}p}}h_{ii}^{\alpha}h_{jj}^{\alpha} -2{\sum\limits_{p+1{\leqslant}s<t{\leqslant}n}}h_{ss}^{\alpha}h_{tt}^{\alpha} \end{split}$

(37)

Then by Eqs. $(35)$ and $(37)$ , we derive

$\begin{align} {\cal{P}}{\geqslant}\sum\limits_{\alpha = n+1}^{m}\varphi_{\alpha} \end{align}$

(38)

Next, for $\alpha$ , we consider the extremum problem

$\begin{align} \min{\varphi_{\alpha}},\qquad {\rm{subject}} \ \ {\rm{to}} \qquad \varGamma :h_{11}^{\alpha}+h_{22}^{\alpha}+{\cdots}+h_{nn}^{\alpha} = K^{\alpha} \end{align}$

(39)

where $K^{\alpha}$ is a real constant(see Ref. [11]). The partial derivatives of function $\varphi_{\alpha}$ are

$\left. {\begin{array}{r} \dfrac{{\partial}\varphi_{\alpha}}{{\partial}h_{11}^{\alpha}} = \dfrac{2(n+r)(n-1)}{r}h_{11}^{\alpha}-2{\sum\nolimits_{i = 1}^{p}}h_{ii}^{\alpha},\\ \vdots\\ \dfrac{{\partial}\varphi_{\alpha}}{{\partial}h_{pp}^{\alpha}} = \dfrac{2(n+r)(n-1)}{r}h_{pp}^{\alpha}-2{\sum\nolimits_{i = 1}^{p}}h_{ii}^{\alpha}\\ \dfrac{{\partial}\varphi_{\alpha}}{{\partial}h_{{p+1}{p+1}}^{\alpha}} = \dfrac{2(n+r)(n-1)}{r}h_{{p+1}{p+1}}^{\alpha}-2{\sum\nolimits_{s = p+1}^{n}}h_{ss}^{\alpha}\\ \vdots\\ \dfrac{{\partial}\varphi_{\alpha}}{{\partial}h_{{n-1}{n-1}}^{\alpha}} = \dfrac{2(n+r)(n-1)}{r}h_{{n-1}{n-1}}^{\alpha}-2{\sum\nolimits_{s = p+1}^{n}}h_{ss}^{\alpha}\\ \dfrac{{\partial}\varphi_{\alpha}}{{\partial}h_{nn}^{\alpha}} = \dfrac{2({n+r})}{n}h_{nn}^{\alpha}-2{\sum\nolimits_{s = p+1}^{n}}h_{ss}^{\alpha} \end{array}} \right\}$

(40)

Applying Lemma $2.2$ , for an optimal solution $(h_{11}^{\alpha},h_{22}^{\alpha},{\cdots},h_{nn}^{\alpha})$ of the minimum problem, vector $grad \ \varphi_{\alpha}$ is normal at $\varGamma$ and collinear with the vector $(1,1,\cdots,1)$ .

From Eq. $(40)$ and Lemma $2.2$ , we derive that a critical point of the problem has the following form:

$\left. {\begin{array}{r} h_{11}^{\alpha} = {\cdots} = h_{pp}^{\alpha} = \dfrac{pr^2}{(n^2-n-r+qr)^2+p^2r^2}K^{\alpha}\\ h_{{p+1}{p+1}}^{\alpha} = {\cdots} = h_{{n-1}{n-1}}^{\alpha} = \dfrac{(n^2-n+qr-r)r}{(n^2-n-r+qr)^2+p^2r^2}K^{\alpha}\\ h_{nn}^{\alpha} = \dfrac{n(n-1)(n^2-n+qr-r)}{(n^2-n-r+qr)^2+p^2r^2}K^{\alpha} \end{array}} \right\}$

(41)

We fixed an arbitrary point $x{\in}\varGamma$ . According to Lemma $2.2$ , we deduce that the corresponding bilinear form $\Lambda:T_x{\varGamma}{\times}T_x{\varGamma}{\rightarrow}{\mathbb{R}}$ is given by

$\begin{align} \Lambda(X,Y) = {\rm{Hess}}_{\varphi_{\alpha}}(X,Y)+g(h'(X,Y),({\rm{grad}} \ \varphi_{\alpha})(x)) \end{align}$

(42)

where $h'$ is the second fundamental form of $\varGamma$ in ${\mathbb{R}}^n$ and $g$ is the inner product on ${\mathbb{R}}^n$ .

By Eq. $(40)$ , for $i$ , $j\in\{1,\cdots,p\}$ , $i{\neq}j$ and $s$ , $t\in\{p+1,\cdots,n\}$ , $s{\neq}t$ , we get

$\left. {\begin{array}{r} \dfrac{{\partial}^2{\varphi_{\alpha}}}{{\partial}(h_{ii}^{\alpha})^2} = \dfrac{2(n+r)(n-1)-2r}{r} \\ \dfrac{{\partial}^2{\varphi_{\alpha}}}{{\partial}h_{ii}^{\alpha}{\partial}h_{jj}^{\alpha}} = -2\\ \dfrac{{\partial}^2{\varphi_{\alpha}}}{{\partial}h_{ii}^{\alpha}{\partial}h_{tt}^{\alpha}} = 0\\ \dfrac{{\partial}^2{\varphi_{\alpha}}}{{\partial}(h_{ss}^{\alpha})^2} = \dfrac{2(n+r)(n-1)-2r}{r}\\ \dfrac{{\partial}^2{\varphi_{\alpha}}}{{\partial}h_{ss}^{\alpha}{\partial}h_{tt}^{\alpha}} = -2\\ \dfrac{{\partial}^2{\varphi_{\alpha}}}{{\partial}(h_{nn}^{\alpha})^2} = \dfrac{2r}{n} \end{array}} \right\}$

(43)

Note that

$\begin{align} ({\rm{Hess}}_{\varphi_{\alpha}})_{ij} = (\varphi_{\alpha})_{i,j} = \frac{\partial^2\varphi_{\alpha}}{{\partial}h_{ii}^{\alpha}{\partial}h_{jj}^{\alpha}} -\frac{{\partial}\varphi_{\alpha}}{{\partial}h_{kk}^{\alpha}}\varGamma_{ij}^k \end{align}$

(44)

where

$\begin{align} \varGamma_{ij}^k = \frac{1}{2}g^{kl}\left( {\frac{{\partial}g_{il}}{{\partial}h_{jj}^{\alpha}}+\frac{{\partial}g_{lj}}{{\partial}h_{ii}^{\alpha}} -\frac{{\partial}g_{ij}}{{\partial}h_{ll}^{\alpha}}} \right) \end{align}$

(45)

Since $g$ is the inner product on ${\mathbb{R}}^n$ , $g_{ij}$ is constant, and $\varGamma_{ij}^k$ is $0$ . Then, we have

$\begin{align} ({\rm{Hess}}_{\varphi_{\alpha}})_{ij} = (\varphi_{\alpha})_{i,j} = \frac{\partial^2\varphi_{\alpha}}{{\partial}h_{ii}^{\alpha}{\partial}h_{jj}^{\alpha}} \end{align}$

(46)

The Hessian matrix of $\varphi_{\alpha}$ is

$\begin{align} {\rm{Hess}}_{\varphi_{\alpha}} = \left(\begin{array}{cccc ccccc} \dfrac{2(n+r)(n-1)-2r}{r}&{\cdots}&-2&0&0&{\cdots}&0\\ \vdots&\ddots&\vdots&\vdots&\vdots&\vdots&\vdots\\ -2&{\cdots}&\dfrac{2(n+r)(n-1)-2r}{r}&0&{\cdots}&0&0\\ 0&{\cdots}&0&\dfrac{2(n+r)(n-1)-2r}{r}&{\cdots}&-2&-2\\ \vdots&\ddots&\vdots&\vdots&{\ddots}&\vdots&\vdots\\ 0&{\cdots}&0&-2&{\cdots}&\dfrac{2(n+r)(n-1)-2r}{r}&-2\\ 0&{\cdots}&0&-2&{\cdots}&-2&\dfrac{2r}{n} \end{array} \right) \end{align}$

(47)

As $\varGamma$ is totally geodesic in ${\mathbb{R}}^n$ , we consider a vector $X = (X_1,$ $X_2,\cdots, X_n)$ tangent to $\varGamma$ at an arbitrary point $x$ on $\varGamma$ , that is, we verify the relation $\sum\nolimits_{i = 1}^nX_i = 0$ (see Ref. [11]). Next, we prove $\Lambda(X,$ $X)\geqslant 0$ .

${\rm{(i)}}$ For $n = 1$ , we have two possibilities

$\begin{align} {\rm{(a)}}\, {\rm{Hess}}_{\varphi_{\alpha}} = \left(\begin{array}{c} 2r \end{array} \right),\quad {\rm{(b)}}\, {\rm{Hess}}_{\varphi_{\alpha}} = \left(\begin{array}{c} -2 \end{array} \right) \end{align}$

(48)

Since $X_1 = 0$ , in this two cases

$\begin{align} {\rm{Hess}}_{\varphi_{\alpha}}(X,X) = 0 \end{align}$

(49)

${\rm{(ii)}}$ For $n = 2$ . we have three possibilities

$\begin{split} &{\rm{(a) \, Hess}}_{\varphi_{\alpha}} = \left(\begin{array}{cc} \dfrac{4}{r}&-2\\ -2&\dfrac{4}{r} \end{array} \right),\quad {\rm{(b)\, Hess}}_{\varphi_{\alpha}} = \left(\begin{array}{cc} \dfrac{4}{r}&0\\ 0&r \end{array} \right)，\quad {\rm{(c) \, Hess}}_{\varphi_{\alpha}} = \left(\begin{array}{cc} \dfrac{4}{r}&-2 -2r \end{array} \right)\\[-10pt] \end{split}$

(50)

For ${\rm{(a)}}$ ,

$\begin{aligned} {\rm{Hess}}_{\varphi_{\alpha}}(X,X) = \dfrac{4+2r}{r}(X_1^2+X_2^2)-2(X_1+X_2)^2 =\dfrac{4+2r}{r}(X_1^2+X_2^2)\geqslant 0\end{aligned}$

(51)

For ${\rm{(b)}}$ , ${\rm{Hess}}_{\varphi_{\alpha}}$ is positive definite, i.e., ${\rm{Hess}}_{\varphi_{\alpha}}(X,X) > 0$ . For ${\rm{(c)}}$ , ${\rm{Hess}}_{\varphi_{\alpha}}$ is positive semi-definite, i.e., ${\rm{Hess}}_{\varphi_{\alpha}}(X,X)\geqslant0$ .

${\rm{(iii)}}$ For $n\geqslant3$ , when $n = p$ , we have

$\begin{split} {\rm{Hess}}_{\varphi_{\alpha}}(X,X) =& \frac{2(n+r)(n-1)}{r}(\sum\limits_{i = 1}^nX_i^2)-2(\sum\limits_{i = 1}^nX_i)^2 = \frac{2(n+r)(n-1)}{r}(\sum\limits_{i = 1}^nX_i^2)\geqslant 0 \end{split}$

(52)

When $n>p$ , let

$\begin{align} &A = \left(\begin{array}{cccc ccccc} \dfrac{2(n+r)(n-1)-2r}{r}&\;\;\;-2&\;\;\; {\cdots}&\;\;\;-2\\ -2&\;\;\; \dfrac{2(n+r)(n-1)-2r}{r}&\;\;\; {\cdots}&\;\;\;-2\\ \vdots&\;\;\;\vdots&\;\;\; \ddots&\;\;\; \vdots\\ -2&\;\;\;-2&\;\;\; {\cdots}&\;\;\; \dfrac{2(n+r)(n-1)-2r}{r} \end{array} \right),\\ &B = \left(\begin{array}{ccccc} \dfrac{2(n+r)(n-1)-2r}{r}&-2&{\cdots}&-2&-2\\ -2&\dfrac{2(n+r)(n-1)-2r}{r}&{\cdots}&-2&-2\\ \vdots&\vdots&\ddots&\vdots&\vdots\\ -2&-2&{\cdots}&\dfrac{2(n+r)(n-1)-2r}{r}&-2\\ -2&-2&{\cdots}&-2&\dfrac{2r}{n} \end{array} \right) \end{align}$

(53)

Note that

$\begin{aligned} 0 |\lambda E-A| =\\& \Bigg[\lambda-\frac{2(n+r)(n-1)}{r}\Bigg]^{p-1}\Bigg(\lambda-\frac{2(n+r)(n-1)-2pr}{r}\Bigg) =\Bigg[\lambda-\frac{2(n+r)(n-1)}{r}\Bigg]^{p-1}\Bigg(\lambda-\frac{2n(n-1)+2(n-1-p)r}{r}\Bigg) \end{aligned}$

(54)

Thus, all eigenvalues of $A$ are greater than $0$ , i.e., $A$ is positive definite.

Since $n>p$ , when $n-p = q = 1$ , we have

$\begin{align} B = \left(\begin{array}{c} \dfrac{2r}{n} \end{array} \right) \end{align}$

(55)

$B$ is positive definite. When $n-p = q\geq2$ , we have

$\begin{split} 0 = |\lambda E-B|& = \bigg[\lambda-\frac{2(n+r)(n-1)}{r}\bigg]^{q-2}\Big[\bigg(\lambda-\frac{2(n+r)}{n}\bigg) \bigg(\lambda-\frac{2(n+r)(n-1)-2(q-1)r}{r}\bigg)-2\bigg(-\lambda+\frac{2(n+r)(n-1)}{r}\bigg)\Bigg] =\\ & \bigg[\lambda-\frac{2(n+r)(n-1)}{r}\bigg]^{q-2}\Bigg[\lambda^2-\bigg(\frac{2(n+r)}{n}+\frac{2(n+r)(n-1)-2(q-1)r}{r}-2\bigg)\lambda+\\ &\frac{2(n+r)}{n}\times\frac{2(n+r)(n-1)-2(q-1)r}{r}-\frac{4(n+r)(n-1)}{r}\Bigg] =\\ & \bigg[\lambda-\frac{2(n+r)(n-1)}{r}\bigg]^{q-2}\Bigg[\lambda^2-\bigg(\frac{2r}{n}+\frac{2(n+r)(n-1)-2(q-1)r}{r}\bigg)\lambda+\frac{4(n+r)}{r}\times\frac{rp}{n}\Bigg] \end{split}$

(56)

Since

$\begin{align} \lambda^2-\big(\frac{2r}{n}+\frac{2(n+r)(n-1)-2(q-1)r}{r}\big)\lambda+\frac{4(n+r)}{r}\times\frac{rp}{n} = 0 \end{align}$

(57)

we have

$\begin{split} &\lambda_{n-1}\lambda_n = \frac{4(n+r)}{r}\times\frac{rp}{n}\geqslant0,\lambda_{n-1}+\lambda_n =\\ & \frac{2r}{n}+\frac{2(n+r)(n-1)-2(q-1)r}{r} = \frac{2r}{n}+\frac{2n(n-1)+2pr}{r}>0 \end{split}$

(58)

that is,

$\begin{align} \lambda_{n-1}\geqslant0,\quad \lambda_n>0 \qquad {\rm{or}} \qquad \lambda_{n-1}>0,\quad \lambda_n\geqslant0 \end{align}$

(59)

We prove that all eigenvalues of $B$ are greater than or equal to $0$ , i.e., $B$ is positive semi-definite. Thus, we prove that ${\rm{Hess}}_{\varphi_{\alpha}} (X,X)\geqslant0$ .

Combining ${\rm{(i)}}$ , ${\rm{(ii)}}$ and ${\rm{(iii)}}$ , we have

$\begin{align} \Lambda(X,X)\geqslant {\rm{Hess}}_{\varphi_{\alpha}}(X,X)\geqslant0 \end{align}$

(60)

Hence, by Eq. $(41)$ , the point $(h_{11}^{\alpha},h_{22}^{\alpha},\cdots,h_{nn}^{\alpha})$ is a global minimum point. From Eqs. $(37)$ and $(41)$ , we have

$\begin{split} \varphi_{\alpha}{\geqslant}&\frac{(n^2-n+nr-2r)\big[p^3r^3+(q-1)r(n^2-n+qr-r)^2\big] (K^{\alpha})^2}{\big\{(n^2-n-r+qr)^2+p^2r^2\big\}^2}+ \\ &\frac{rn(n-1)^2(n^2-n+qr-r)^2(K^{\alpha})^2}{\big\{(n^2-n-r+qr)^2+p^2r^2\big\}^2}-\frac{{p(p-1)(pr^2)^2}(K^{\alpha})^2}{\big\{(n^2-n-r+qr)^2+p^2r^2\}^2}-\\ &\frac{\big\{(q-1)(q-2)(n^2-n+qr-r)^2r^2+2(n^2-n+qr-r)^2rn(n-1)(q-1)\big\}(K^{\alpha})^2}{\big\{(n^2-n-r+qr)^2+p^2r^2\}^2} =\\ &\frac{pr(n^2-n+qr-r)^3(K^{\alpha})^2}{\big\{(n^2-n-r+qr)^2+p^2r^2\big\}^2}+\frac{p^3r^3(n^2-n+qr-r)(K^{\alpha})^2}{\big\{(n^2-n-r+qr)^2+p^2r^2\big\}^2} =\\&\frac{pr(n^2-n+qr-r)\big\{(n^2-n-r+qr)^2+p^2r^2\big\}(K^{\alpha})^2 }{\big\{(n^2-n-r+qr)^2+p^2r^2\}^2} =\\ &\frac{pr(n^2-n+qr-r)(K^{\alpha})^2 }{(n^2-n-r+qr)^2+p^2r^2} \end{split}$

(61)

We divide the proof of Theorem $1.1$ into two main cases, according to $0<r<n(n-1)$ or $r>n(n-1)$ .

Case 1: $0<r<n(n-1)$ . In this case, using $(38)$ and $(61)$ , we derive

$\begin{array}{c} {\cal{P}}{\geqslant}{\displaystyle \sum\limits_{\alpha = n+1}^{m}}\dfrac{pr(n^2-n+qr-r)(K^{\alpha})^2 }{(n^2-n-r+qr)^2+p^2r^2} = \dfrac{pr(n^2-n+qr-r)n^2{{\parallel}H{\parallel}}^2 }{(n^2-n-r+qr)^2+p^2r^2}\end{array}$

(62)

By Eqs. $(34)$ and $(62)$ , we derive

$\begin{split} &2\times\Bigg\{\dfrac{q{\Delta}f}{f}+\dfrac{p(p-1)a}{2}+b(p-1){{\parallel}P^T{\parallel}}^2_{N_1^p}+\dfrac{q(q-1)a}{2}+b(q-1){{\parallel}P^T{\parallel}}^2_{N_2^q}\Bigg\}+r{{\cal{C}}}+\\&\dfrac{(n-1)(n+r)(n^2-n-r)}{nr}{{\cal{C}}}(L){\geqslant}2{\tau}+\dfrac{pr(n^2-n+qr-r)n^2{{\parallel}H{\parallel}}^2 }{(n^2-n-r+qr)^2+p^2r^2} \end{split}$

(63)

Taking the infimum over all tangent hyperplanes $L$ of $T_xM^n$ in $(63)$ , we obtain

$\begin{split} &\dfrac{2}{n(n-1)}\times\Bigg\{\dfrac{q{\Delta}f}{f}+\dfrac{p(p-1)a}{2}+b(p-1){{\parallel}P^T{\parallel}}^2_{N_1^p}+\dfrac{q(q-1)a}{2}+b(q-1){{\parallel}P^T{\parallel}}^2_{N_2^q}\Bigg\}+\\&\dfrac{{\delta_C}(r;n-1)}{n(n-1)}-\dfrac{npr(n^2-n+qr-r){{\parallel}H{\parallel}}^2 }{(n-1)\bigg\{(n^2-n-r+qr)^2+p^2r^2\bigg\}}{\geqslant}\rho \end{split}$

(64)

Case 2: $r>n(n-1)$ . Similarly, using the same method, we obtain

$\begin{split} &\dfrac{2}{n(n-1)}\times\Bigg\{\dfrac{q{\Delta}f}{f}+\dfrac{p(p-1)a}{2}+b(p-1){{\parallel}P^T{\parallel}}^2_{N_1^p}+\dfrac{q(q-1)a}{2}+b(q-1){{\parallel}P^T{\parallel}}^2_{N_2^q}\Bigg\}+\\&\dfrac{{\widehat{\delta_C}}(r;n-1)}{n(n-1)}-\dfrac{npr(n^2-n+qr-r){{\parallel}H{\parallel}}^2 }{(n-1)\bigg\{(n^2-n-r+qr)^2+p^2r^2\bigg\}}{\geqslant}\rho \end{split}$

(65)

Equalities hold in (64) and (65) at a point $x{\in}M^n$ if and only if inequalities $(35)$ and $(61)$ become equalities. Thus, we have

(66)

By choosing an orthonormal basis such that $e_{n+1}$ is in the direction of the mean curvature vector, we have

$\left. {\begin{array}{r} h(e_1,e_1) = \cdots = h(e_p,e_p) = pr^2f_1e_{n+1},\\ h(e_{p+1},e_{p+1}) = \cdots = h(e_{n-1},e_{n-1}) = (n^2-n+qr-r)rf_1e_{n+1},\\ h(e_n,e_n) = n(n-1)(n^2-n+qr-r)f_1e_{n+1},\\ h(e_i,e_j) = 0,\qquad i\neq j \end{array} } \right\}$

(67)

where $f_1 = \dfrac{K^{n+1}}{(n^2-n+qr-r)^2+p^2r^2}$ is a function on $M^n$ .

Acknowledgements

This work was supported by the National Natural Science Foundation of China (12026262).

Conflict of interest

The authors declare that they have no conflict of interest.

Conflict of Interest

The authors declare that they have no conflict of interest.

We establish Chen-like inequalities for generalized normalized δ-Casorati curvatures of warped product submanifolds in a Riemannian manifold of quasi-constant curvature. Our inequalities extend the optimal inequalities involving the scalar curvature and the Casorati curvature of a Riemannian submanifold in a real space form.

References (11)

References

[1]	Chen B Y. Some pinching and classification theorems for minimal submanifolds. Arch. Math., 1993, 60: 568–578. DOI: 10.1007/BF01236084
[2]	Chen B Y. A Riemannian invariant and its applications to submanifold theory. Results in Mathematics, 1995, 27: 17–26. DOI: 10.1007/BF03322265
[3]	Casorati F. Mesure de la courbure des surfaces suivant l'idée commune.: Ses rapports avec les mesures de courbure gaussienne et moyenne. Acta. Math., 1890, 14: 95–110. DOI: 10.1007/BF02413317
[4]	Decu S, Haesen S, Verstraelen L. Optimal inequalities involving Casorati curvatures. Bull.Transilv. Univ. Brasov Ser. B, 2007, 14: 85–93.
[5]	Decu S, Haesen S, Verstraelen L. Optimal inequalities characterising quasi-umbilical submanifolds. J. Inequal. Pure and Appl. Math., 2008, 9: 79.
[6]	Park K S. Inequalities for the Casorati curvatures of real hypersurfaces in some Grassmannians. Taiwanese J. Math., 2018, 22: 63–77. DOI: 10.11650/tjm/8124
[7]	Choudhary M A, Blaga A M. Inequalities for generalized normalized δ-Casorati curvatures of slant submanifolds in metallic Riemannian space forms. J. Geom., 2020, 111: 39. DOI: 10.1007/s00022-020-00552-5
[8]	Chen B Y, Yano K. Hypersurfaces of a conformally flat space. Tensor, N. S., 1972, 26: 318–322.
[9]	Chen B Y. Another general inequality for CR-warped products in complex space forms. Hokkaido Math. J., 2003, 32: 415–444.
[10]	Oprea T. Chen's inequality in the Lagrangian case. Colloq. Math., 2007, 108: 163–169. DOI: 10.4064/cm108-1-15
[11]	Vîlcu G E. An optimal inequality for Lagrangian submanifolds in complex space forms involving Casorati curvature. J. Math. Anal. Appl., 2018, 465: 1209–1222. DOI: 10.1016/j.jmaa.2018.05.060

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References

[1]	Chen B Y. Some pinching and classification theorems for minimal submanifolds. Arch. Math., 1993, 60: 568–578. DOI: 10.1007/BF01236084
[2]	Chen B Y. A Riemannian invariant and its applications to submanifold theory. Results in Mathematics, 1995, 27: 17–26. DOI: 10.1007/BF03322265
[3]	Casorati F. Mesure de la courbure des surfaces suivant l'idée commune.: Ses rapports avec les mesures de courbure gaussienne et moyenne. Acta. Math., 1890, 14: 95–110. DOI: 10.1007/BF02413317
[4]	Decu S, Haesen S, Verstraelen L. Optimal inequalities involving Casorati curvatures. Bull.Transilv. Univ. Brasov Ser. B, 2007, 14: 85–93.
[5]	Decu S, Haesen S, Verstraelen L. Optimal inequalities characterising quasi-umbilical submanifolds. J. Inequal. Pure and Appl. Math., 2008, 9: 79.
[6]	Park K S. Inequalities for the Casorati curvatures of real hypersurfaces in some Grassmannians. Taiwanese J. Math., 2018, 22: 63–77. DOI: 10.11650/tjm/8124
[7]	Choudhary M A, Blaga A M. Inequalities for generalized normalized δ-Casorati curvatures of slant submanifolds in metallic Riemannian space forms. J. Geom., 2020, 111: 39. DOI: 10.1007/s00022-020-00552-5
[8]	Chen B Y, Yano K. Hypersurfaces of a conformally flat space. Tensor, N. S., 1972, 26: 318–322.
[9]	Chen B Y. Another general inequality for CR-warped products in complex space forms. Hokkaido Math. J., 2003, 32: 415–444.
[10]	Oprea T. Chen's inequality in the Lagrangian case. Colloq. Math., 2007, 108: 163–169. DOI: 10.4064/cm108-1-15
[11]	Vîlcu G E. An optimal inequality for Lagrangian submanifolds in complex space forms involving Casorati curvature. J. Math. Anal. Appl., 2018, 465: 1209–1222. DOI: 10.1016/j.jmaa.2018.05.060

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Inequalities of warped product submanifolds in a Riemannian manifold of quasi-constant curvature

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Inequalities of warped product submanifolds in a Riemannian manifold of quasi-constant curvature

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