Characterizations of the Frame Bundle Admitting Metallic Structures on Almost Quadratic ϕ-Manifolds

Khan, Mohammad Nazrul Islam; De, Uday Chand; Alam, Teg

doi:10.3390/math11143097

Open AccessArticle

Characterizations of the Frame Bundle Admitting Metallic Structures on Almost Quadratic ϕ-Manifolds

by

Mohammad Nazrul Islam Khan

¹

,

Uday Chand De

²

and

Teg Alam

^3,*

¹

Department of Computer Engineering, College of Computer, Qassim University, Buraydah 51452, Saudi Arabia

²

Department of Pure Mathematics, University of Calcutta, 35, Ballygaunge Circular Road, Kolkata 700019, India

³

Department of Industrial Engineering, College of Engineering, Prince Sattam bin Abdulaziz University, Al Kharj 11942, Saudi Arabia

^*

Author to whom correspondence should be addressed.

Mathematics 2023, 11(14), 3097; https://doi.org/10.3390/math11143097

Submission received: 1 June 2023 / Revised: 20 June 2023 / Accepted: 11 July 2023 / Published: 13 July 2023

(This article belongs to the Special Issue Geometry of Manifolds and Applications)

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Abstract

:

In this work, we have characterized the frame bundle

F M

admitting metallic structures on almost quadratic

ϕ

-manifolds

ϕ^{2} = p ϕ + q I - q η \otimes ζ

, where p is an arbitrary constant and q is a nonzero constant. The complete lifts of an almost quadratic

ϕ

-structure to the metallic structure on

F M

are constructed. We also prove the existence of a metallic structure on

F M

with the aid of the

\tilde{J}

tensor field, which we define. Results for the 2-Form and its derivative are then obtained. Additionally, we derive the expressions of the Nijenhuis tensor of a tensor field

\tilde{J}

on

F M

. Finally, we construct an example of it to finish.

Keywords:

metallic structure; frame bundle; partial differential equations; almost quadratic ϕ-structure; 2-Form; diagonal lift; mathematical operators; nijenhuis tensor

MSC:

53C15; 58D17

1. Introduction

Numerous types of f-structures on a differentiable manifold M have been studied by Yano [1], Ishihara and Yano [2], Blair [3], Nakagawa [4] and others. Yano proposed the notion of an f-structure obeying

f^{3} + f = 0, f

is a tensor field of type (1,1), which is the generalization of an almost complex structure and an almost contact structure [5] and investigated some basic results of it. Later, Goldberg and Yano [6] and Goldberg and Perridis [7] defined a polynomial structure

P (J) = J^{n} + a_{n} J^{n - 1} + . . . + a_{2} J + a_{1} I,

where

a_{1}, a_{2}, \dots, a_{n}

are real numbers, J is a tensor field of type (1,1) and I is an identity tensor field of type (1,1) on M. Moreover, some important polynomial structures such as an

f (3, ε)

-structure [8], a general quadratic structure [9], an almost complex structure and an almost product structure [1],

ϕ (4, \pm 2)

-structures [10] and an almost r-contact structure [11] are studied and the fundamental results are established in these papers.

Recently, the polynomial structure

J^{2} = p J + q I, p, q \in N,

where

N

is the set of natural numbers, of degree 2 is known as a metallic structure on M [12,13,14]. For specific values of p and q, metallic structures become prominent structures given below:

p	q	Structure
0	1	an almost product structure [15]
0	−1	an almost complex structure [16,17]
1	1	a golden structure [18,19]
2	1	a silver structure [20]

Hretceanu and Crasmareanu [21] initiated the study of golden and metallic structures on a Riemannian manifold and interpreted the geometry of submanifolds admitting both structures on M. The various geometric properties of such structures in a metallic (and golden) Riemannian manifold and a metallic (and golden) warped product Riemannian manifold were studied in [22,23,24,25,26]. Debnath and Konar [27] defined a new type of structure named as an almost quadratic

ϕ

-structure

(ϕ, ζ, η)

on M and studied some geometric properties of such structures. Next, Gonul et al. [28] established the relationship between an almost quadratic metric

ϕ

-structure and a metallic structure on M. Most recently, Gok et al. [29] defined a generalized structure namely

f_{(a, b)} (3, 2, 1)

-structures on manifolds and construct a framed

f_{(a, b)} (3, 2, 1)

-structures on M.

On the other hand, let M be an m-dimensional differentiable manifold,

T M

its tangent bundle and

F M

its frame bundle. The notion of the mappings, namely vertical, complete and horzontal lifts from the manifold M to its tangent bundle

T M

were introduced by Sasaki [30], Yano and Ishihara [31] and Yano and Davis [32]. Kabayashi and Nomizu [33], Mok [34] and Okubo [35] have studied the complete lift of a vector field

A

to

F M

. The geometric structures such as an almost contact metric structure

(ϕ, ζ, η, g)

, and almost complex structures J on

F M

have been studied by Bonome et al. [16], who established the integrability and normality of such structures on

F M

.

In [36], Khan has introduced a tensor field

\tilde{J}

on

F M

and proved that

\tilde{J}

is a metallic structure on

F M

. The integrability condition for the diagonal and horizontal lifts of the metallic structure

\tilde{J}

on

F M

is established. The geometric structures on

F M

have been studied by Cordero et al. [37], Kowalski [38], Sekizawa [39], Kowalski and Sekizawa [40], Niedzialomski [41], Lachieze-Rey [42], Khan [43,44,45] and many more.

The main objective of this paper can be summarized as follows:

We study the complete lifts of an almost quadratic $ϕ$ -structure to the metallic structure on $F M$ .
We establish the existence of a metallic structure on $F M$ in the tensor field $\tilde{J}$ , which we define.
We obtain results on the 2-Form and its derivative on $F M$ .
We derive the expressions of the Nijenhuis tensor of a tensor field $\tilde{J}$ on $F M$ .
We construct an example related to it.

Remark:

ℑ_{a}^{b} (M)

and

ℑ_{a}^{b} (F M)

are symbolized as the set of all

(a, b)

-type tensor fields in M and

F M

respectively [17].

2. Preliminaries

Let

F, A, f

and

η

be a tensor field of type (1,1), a vector field, a function and a 1-form, respectively, on M. The horizontal, vertical and

α

-vertical lifts of

F, A, f

and

η

are represented by

F^{H}, A^{H}, A^{(α)}, f^{H}, η^{V}

and

η^{H_{α}}

on

F M

and they are expressed in terms of partial differential equations as [16,17]

\begin{matrix} A^{H} & = & A^{i} \frac{\partial}{\partial A^{i}} - A^{i} Γ_{i k}^{h} A_{α}^{k} \frac{\partial}{\partial A^{h}}, \end{matrix}

(1)

\begin{matrix} A^{(α)} & = & A^{i} \frac{\partial}{\partial A_{α}^{i}}, \\ F^{H} & = & F_{j}^{h} \frac{\partial}{\partial A^{h}} \otimes d x^{j} + A_{α}^{k} (Γ_{j k}^{i} F_{i}^{h} - Γ_{i k}^{h} F_{j}^{i}) \frac{\partial}{\partial A_{α}^{h}}, \end{matrix}

(2)

\begin{matrix} \otimes d x^{j} + δ_{α}^{β} F_{j}^{h} \frac{\partial}{\partial A_{α}^{h}} \otimes d X_{β}^{j}, \end{matrix}

(3)

\begin{matrix} η^{V} & = & η_{i} d x^{i}, \end{matrix}

(4)

\begin{matrix} η^{H_{α}} & = & A_{α}^{j} Γ_{i j}^{h} η_{h} d x^{i} + η_{i} d X_{α}^{i}, \end{matrix}

(5)

\begin{matrix} A^{H} & = & \sum_{α = 1}^{m} (A_{α}^{j} Γ_{i j}^{h} η_{h} d x^{i} + η_{i} d X_{α}^{i}), \end{matrix}

(6)

where

Γ_{i j}^{h}, A^{i}, F_{j}^{h}

and

η_{i}

are the local components of a linear connection ∇,

A

, F and

η

, respectively on M.

Proposition 1.

\forall A, B \in ℑ_{0}^{1} (M)

, by using mathematical operators, we have the following

\begin{matrix} A^{H} (f^{V}) & = & {(A (f))}^{V}), \\ A^{(α)} (f^{V}) & = & 0, \\ F^{H} (A^{(α)}) & = & {(F (A))}^{α}, \\ F^{H} (A^{H}) & = & {(F (A))}^{H}, \\ η^{V} (A^{H}) & = & {(F (A))}^{V}, \\ η^{V} (A^{(α)}) & = & 0, \\ η^{H_{α}} (A^{H}) & = & 0, \\ η^{H_{α}} (A^{(β)}) & = & δ_{α}^{β} {(η (A))}^{V}, \end{matrix}

(7)

where

α, β = 1, \dots, m

and

δ_{β}^{α}

denotes the Kronecker delta.

Proposition 2.

Let

\forall A, B \in ℑ_{0}^{1} (M)

. Then, we have the following

\begin{matrix} [A^{(α)}, B^{(β)}] & = & 0, \\ [A^{H}, B^{(α)}] & = & {(\nabla_{X} Y)}^{(α)}, \\ [A^{H}, B^{H}] & = & {[A, B]}^{H} - γ R (A, B), \end{matrix}

(8)

where

R (A, B) = [\nabla_{A}, \nabla_{B}] - \nabla_{[A, B]}

, R is the curvature tensor of ∇.

Let g be a Riemannian metric on a Riemannian manifold M and

g^{D}

its diagonal metric on

F M

, then

\begin{matrix} g^{D} (A^{H}, B^{H}) & = & {g (A, B)}^{V}, \\ g^{D} (A^{H}, B^{(α)}) & = & 0, \\ g^{D} (A^{(α)}, B^{(β)}) & = & δ^{α β} {g (A, B)}^{V}, \forall α, β = 1, \dots, m \end{matrix}

(9)

and

\begin{matrix} 2 g^{D} ({\tilde{\nabla}}_{\tilde{A}} \tilde{B}, \tilde{C}) & = & \tilde{A} (g^{D} (\tilde{B}, \tilde{C})) + \tilde{B} (g^{D} (\tilde{C}, \tilde{A})) - \tilde{C} (g^{D} (\tilde{A}, \tilde{B})) \\ + & g^{D} ([\tilde{A}, \tilde{B}], \tilde{C}) + g^{D} ([\tilde{C}, \tilde{A}], \tilde{B}) + g^{D} (\tilde{A}, [\tilde{C}, \tilde{B}]), \end{matrix}

(10)

\forall \tilde{A}, \tilde{B} \in ℑ_{0}^{1} (F M)

, where ∇ and

\tilde{\nabla}

represent the Levi-Civita connection of

(M, g)

and

(F M, g^{D})

, respectively.

Proposition 3.

\forall A, B \in ℑ_{0}^{1} (M)

, by using mathematical operators, we have the following

\begin{matrix} {\tilde{\nabla}}_{A^{(α)}} B^{(β)} & = & 0, \\ g^{D} ({\tilde{\nabla}}_{A^{(α)}} B^{H}, C^{(β)}) & = & 0, \\ g^{D} ({\tilde{\nabla}}_{A^{(α)}} B^{H}, C^{H}) & = & - \frac{1}{2} g^{D} (γ R (C, B), A^{(α)}), \\ g^{D} ({\tilde{\nabla}}_{A^{H}} B^{(α)}, C^{(β)}) & = & δ^{α β} {g (\nabla_{A} B, C)}^{V}, \\ g^{D} ({\tilde{\nabla}}_{A^{H}} B^{(α)}, C^{H}) & = & - \frac{1}{2} g^{D} (γ R (C, A), B^{(α)}), \\ g^{D} ({\tilde{\nabla}}_{A^{H}} B^{H}, C^{(α)}) & = & - \frac{1}{2} g^{D} (γ R (A, B), C^{(α)}), \\ g^{D} ({\tilde{\nabla}}_{A^{H}} B^{H}, C^{H}) & = & {g (\nabla_{A} B, C)}^{V} . \end{matrix}

(11)

2.1. Metallic Structure

If a (1, 1) tensor field J obeying

J^{2} = p J + q I, p, q \in N,

(12)

where

N

is the set of natural numbers and I is an identity operator, determines a polynomial structure on a manifold M, the structure is referred to as metallic. A metallic manifold is defined as

(M, J)

when a manifold M possesses a metallic structure (MS) J.

The Nijenhuis tensor

N_{J}

of J is expressed as

N_{J} (A, B) = [J A, J B] - J [J A, B] - J [A, J B] + J^{2} [A, B],

(13)

\forall A, B \in ℑ_{0}^{1} (M)

.

2.2. Almost Quadratic $ϕ$ -Structure

An

m (= 2 n + 1)

-dimensional differentiable manifold M with a non-null tensor field

ϕ

of type (1,1), a 1-form

η

and a vector field

ζ

on M satisfies

\begin{matrix} ϕ^{2} & = & p ϕ + q I - q η \otimes ζ, p^{2} + 4 q \neq 0, \end{matrix}

(14)

\begin{matrix} η (ζ) & = & 1, η \circ ϕ = 0, ϕ (ζ) = 0, \end{matrix}

(15)

where p is an arbitrary constant and

q \neq 0

. The structure

(ϕ, ζ, η)

is called an almost quadratic

ϕ

-structure on M and the manifold

(M, ϕ, ζ, η)

is called an almost quadratic

ϕ

-manifold [27,28].

Furthermore,

g (ϕ A, B) = g (A, ϕ B)

(16)

and

g (ϕ A, ϕ B) = p g (ϕ A, B) + q g (A, B) - q η (A) η (B)) .

(17)

The structure

(ϕ, ζ, η, g)

is referred to as an almost quadratic metric

ϕ

-structure and

(M, ϕ, ζ, η, g)

is called an almost quadratic metric

ϕ

-manifold.

In addition, the 1-form

η

is associated with g such that

g (A, ζ) = η (A)

and the fundamental 2-Form

Φ

is given by [3]

Φ (A, B) = g (A, ϕ B) .

(18)

The Nijenhuis tensor of

(ϕ, ζ, η)

is denoted by

N_{ϕ}

and is given by

N_{ϕ} (A, B) = [ϕ A, ϕ B] - ϕ [ϕ A, B] - ϕ [A, ϕ B] + ϕ^{2} [A, B],

(19)

\forall A, B \in ℑ_{0}^{1} (M)

.

3. Proposed Theorems on FM Admitting Metallic Structures on Almost Quadratic $ϕ$ -Manifolds

In this section, we construct the complete lifts of an almost quadratic

ϕ

-structure to the metallic structure on

F M

.

Next, we obtain the results on the 2-Form and its derivative on

F M

.

Boname et al. [16] proposed and gave the definition of

\tilde{J}

on

F M

as

\begin{matrix} \tilde{J} & = & ϕ^{H} + \sum_{α = 1}^{n} η^{H_{α}} \otimes ζ^{(α + n)} - \sum_{α = 1}^{n} η^{H_{α + n}} \otimes ζ^{(α)} \\ + & η^{V} \otimes ζ^{(2 n + 1)} - η^{H_{2 n + 1}} \otimes ζ^{H} . \end{matrix}

(20)

Recently, Khan [36] proposed and gave the definition of the tensor field

\tilde{J}

on

F M

as

\begin{matrix} \tilde{J} & = & \frac{p}{2} I - (\frac{2 σ_{p}^{q} - p}{2}) [ϕ^{H} + \sum_{α = 1}^{n} η^{H_{α}} \otimes ζ^{(α + n)} \\ - & \sum_{α = 1}^{n} η^{H_{α + n}} \otimes ζ^{(α)} + η^{V} \otimes ζ^{(2 n + 1)} - η^{H_{2 n + 1}} \otimes ζ^{H}], \end{matrix}

(21)

where

η = η_{i} d x^{i}

,

η^{V} = η_{i} d x^{i}

and

η^{H_{α}} = A_{α}^{j} Γ_{i j}^{h} η_{h} d x^{i} + η_{i} d x_{α}^{i}

.

Motivated by the above definitions, let us introduce a tensor field

\tilde{J}

of type (1,1) on

F M

as

\begin{matrix} \tilde{J} & = & \frac{p}{2} I - A [ϕ^{H} + \sqrt{q} {\sum_{α = 1}^{n} η^{H_{α}} \otimes ζ^{(α + n)} \\ - & \sum_{α = 1}^{n} η^{H_{α + n}} \otimes ζ^{(α)} + η^{V} \otimes ζ^{(2 n + 1)} - η^{H_{2 n + 1}} \otimes ζ^{H}}], \end{matrix}

(22)

where

A = \frac{2 σ_{p}^{q} - p}{2 \sqrt{p ϕ^{H} + q}}

,

η = η_{i} d x^{i}

,

η^{V} = η_{i} d x^{i}

and

η^{H_{α}} = A_{α}^{j} Γ_{i j}^{h} η_{h} d x^{i} + η_{i} d x_{α}^{i}

.

Theorem 1.

Let

\tilde{A}

be a vector field on

F M

. Then

\tilde{J}

given by (22) is a metallic structure on

F M

.

Proof.

To prove that

\tilde{J}

defined in (22) is a metallic structure, we have to prove that

{\tilde{J}}^{2} \tilde{A} = p \tilde{J} (\tilde{A}) + q I; p, q \in N .

(23)

□

Taking the horizontal lift

A^{H}

and

β^{t h}

-vertical lift

A^{(β)}

for each

β = 1, \dots 2 n + 1

on both sides of (22), we infer

\begin{matrix} \tilde{J} (A^{(β)}) & = & \frac{p}{2} A^{(β)} - A [{(ϕ A)}^{(β)} + \sqrt{q} {ε (β) ζ^{(β + ε (β) n)} \\ - & δ_{2 n + 1}^{β} η {(A)}^{V} ξ^{H}}], \end{matrix}

(24)

where

ε (β) = \{\begin{matrix} 1, & β \leq n, \\ - 1, & n < β \leq 2 n, \\ 0, & β = 2 n + 1, \end{matrix}

(25)

and

\tilde{J} (A^{H}) = \frac{p}{2} A^{H} - A [{(ϕ A)}^{H} + \sqrt{q} {η {(A)}^{V} ζ^{(2 n + 1)}}] .

(26)

In view of (22), we provide

\begin{matrix} \tilde{J} (ϕ^{H} \tilde{A}) & = & \frac{p}{2} ϕ^{H} \tilde{A} - A [- \tilde{A} + \sqrt{q} {\sum_{α = 1}^{n} η^{H_{α}} (\tilde{A}) ζ^{(α + n)} \\ - & \sum_{α = 1}^{n} η^{H_{α + n}} (\tilde{A}) ζ^{(α)} + η^{V} (\tilde{A}) ζ^{(2 n + 1)} - η^{H_{2 n + 1}} (\tilde{A}) ζ^{H}}], \end{matrix}

(27)

\begin{matrix} \tilde{J} (ζ^{(α)}) & = & \frac{p}{2} ζ^{(α)} - A \sqrt{q} (ζ^{(α + n)} - ζ^{H}), \end{matrix}

\tilde{J} (ζ^{H}) = \frac{p}{2} ζ^{H} - A \sqrt{q} ζ^{(2 n + 1)},

and

\begin{matrix} {\tilde{J}}^{2} (\tilde{A}) & = & \frac{p}{2} J \tilde{A} - A [\tilde{J} (ϕ^{H} \tilde{A}) + \sqrt{q} {\sum_{α = 1}^{n} η^{H_{α}} (\tilde{A}) \tilde{J} (ζ^{(α + n)}) \\ - & \sum_{α = 1}^{n} η^{H_{α + n}} (\tilde{A}) \tilde{J} (ζ^{(α)}) + η^{V} (\tilde{A}) \tilde{J} (ζ^{(2 n + 1)}) - η^{H_{2 n + 1}} (\tilde{A}) \tilde{J} (ζ^{H})}], \\ {\tilde{J}}^{2} (\tilde{A}) & = & p \tilde{J} (\tilde{A}) + q \tilde{A} . \end{matrix}

(28)

Definition 1.

The 2-Form Ω of

\tilde{J}

is given by

Ω (\tilde{A}, \tilde{B}) = g^{D} (\tilde{A}, \tilde{J} \tilde{B}),

(29)

\forall \tilde{A}, \tilde{B} \in ℑ_{0}^{1} (F M)

.

Theorem 2.

The 2-Form Ω of

(g^{D}, \tilde{J})

on

F M

is given by

\begin{matrix} (i) Ω (A^{H}, B^{H}) & = & \frac{p}{2} g {(A, B)}^{V} - A Φ {(A, B)}^{V}, \\ (i i) Ω (A^{H}, B^{(β)}) & = & A \sqrt{q} δ_{2 n + 1}^{β} η {(A)}^{V} η {(B)}^{V}, \\ (i i i) Ω (A^{(β)}, B^{(μ)}) & = & \frac{p}{2} δ_{μ}^{β} {(g (A, B))}^{V} - A [δ_{μ}^{β} Φ {(A, B)}^{V} \\ + & \sqrt{q} ε (μ) δ_{μ + ε (μ) n}^{β + ε (β) n} η {(A)}^{V} η {(B)}^{V}], \end{matrix}

where

α, β, μ = 1, \dots, 2 n + 1

and

\forall A, B \in ℑ_{0}^{1} (M)

.

Proof.

Using (9) and (29), we infer

\begin{matrix} (i) Ω (A^{H}, B^{H}) & = & g^{D} (A^{H}, \frac{p}{2} B^{H} - A [{(ϕ B)}^{H} + \sqrt{q} η {(B)}^{V} ζ^{(2 n + 1)}]), \\ = & \frac{p}{2} g {(A, B)}^{V} - A Φ {(A, B)}^{V}, \\ (i i) Ω (A^{H}, B^{(β)}) & = & g^{D} (A^{H}, \frac{p}{2} B^{(β)} - A [{(ϕ B)}^{(β)} \\ + & \sqrt{q} {ε (β) η {(B)}^{V} ζ^{(β + ε (β) n)} - δ_{2 n + 1}^{β} η {(B)}^{V} ζ^{H}])} . \\ = & A \sqrt{q} δ_{2 n + 1}^{β} η {(A)}^{V} η {(B)}^{V}, \\ (i i i) Ω (A^{(β)}, B^{(μ)}) & = & g^{D} (A^{(β)}, \frac{p}{2} B^{(μ)} - A [{(ϕ B)}^{(μ)} \\ + & \sqrt{q} {ε (β) η {(B)}^{V} ζ^{(μ + ε (μ) n)} - δ_{2 n + 1}^{μ} η {(B)}^{V} ζ^{H}])} \\ = & \frac{p}{2} δ_{μ}^{β} {(g (A, B))}^{V} - A [δ_{μ}^{β} Φ {(A, B)}^{V} \\ + & \sqrt{q} ε (μ) δ_{μ + ε (μ) n}^{β + ε (β) n} η {(A)}^{V} η {(B)}^{V}] . \end{matrix}

(30)

□

Theorem 3.

The differential

d Ω

on

F M

is expressed as

\begin{matrix} (i) d Ω (A^{H}, B^{H}, C^{H}) & = & \frac{1}{3} {\frac{p}{2} [{(X g (B, C))}^{V} - g {([A, B], C)}^{V} - {(Y g (B, C))}^{V} \\ + & g {([A, C], B)}^{V} + {(Z g (A, B))}^{V} - g {([B, C], A)}^{V}] \\ - & {A [(A (Φ (B, C))}^{V} {- (B (Φ (A, C))}^{V} \\ + & (C {(Φ (A, B))}^{V} - (Φ {([A, B], C)}^{V}) + (Φ {([A, C], B)}^{V}) \\ - & (Φ {([B, C], A)}^{V}) + Ω (γ R (A, B), C^{H}) \\ - & Ω (γ R (A, C), B^{H}) + Ω (γ R (B, C), A^{H})}, \\ (i i) d Ω (A^{H}, B^{H}, C^{(β)}) & = & \frac{1}{3} {A \sqrt{q} [δ_{2 n + 1}^{β} {(A η (C) η (B))}^{V} \\ - & δ_{2 n + 1}^{β} {(B η (C) η (A))}^{V} \\ - & δ_{2 n + 1}^{β} {(η ([A, B]) η (C))}^{V} + Ω (γ R (A, B), C^{(β)}) \\ + & δ_{2 n + 1}^{β} {(η (\nabla_{X} Z) η (B))}^{V} \\ - & δ_{2 n + 1}^{β} {(η (\nabla_{Y} Z) η (A))}^{V}]}, \\ (i i i) d Ω (A^{H}, B^{(β)}, C^{(μ)}) & = & \frac{1}{3} {\frac{p}{2} δ_{α}^{β} (\nabla_{X} g) {(B, C)}^{V} - A δ_{α}^{β} (\nabla_{A} Φ) {(B, C)}^{V} \\ + & \sqrt{q} ε (α) δ_{α + \sqrt{q} ε (α) n}^{β} η {(B)}^{V} (\nabla_{A} η) C {)^{V} + η {(C)}^{V} (\nabla_{A} η) B)}^{V}}, \\ (i v) d Ω (A^{(α)}, B^{(β)}, C^{(μ)}) & = & 0, \end{matrix}

\forall A, B, C \in ℑ_{0}^{1} (M)

.

Proof.

The differential

d Ω

is given by

\begin{matrix} 3 d Ω (\tilde{A}, \tilde{B}, \tilde{C}) & = & {\tilde{A} (Ω (\tilde{B}, \tilde{C})) - \tilde{B} (Ω (\tilde{A}, \tilde{C})) + \tilde{C} (Ω (\tilde{A}, \tilde{B})) \\ - & Ω ([\tilde{A}, \tilde{B}], \tilde{C}) + Ω ([\tilde{A}, \tilde{C}], \tilde{B}) - Ω ([\tilde{B}, \tilde{C}], \tilde{A})}, \end{matrix}

\forall \tilde{A}, \tilde{B}, \tilde{C} \in ℑ_{0}^{1} (F M)

.

\begin{matrix} (i) 3 d Ω (A^{H}, B^{H}, C^{H}) & = & \frac{p}{2} [A^{H} (g {(B, C)}^{V}) - B^{H} (g {(A, C)}^{V}) \\ + & C^{H} (g {(A, B)}^{V})] - A [A^{H} (Φ {(B, C)}^{V}) \\ - & B^{H} (Φ {(A, C)}^{V}) + C^{H} (Φ {(A, B)}^{V})] \\ - & \frac{p}{2} g {([A, B], C)}^{V} + A (Φ {([A, B], C)}^{V}) \\ + & Ω (γ R (A, B), C^{H}) + \frac{p}{2} g {([A, C], B)}^{V} \\ + & A (Φ {([A, C], B)}^{V}) - Ω (γ R (A, C), B^{H}) \\ - & \frac{p}{2} g {([B, C], A)}^{V} + A (Φ {([B, C], A)}^{V}) \\ + & Ω (γ R (B, C), A^{H}) \\ = & \frac{p}{2} {[(X g (B, C))}^{V} - g {([A, B], C)}^{V} - {(Y g (B, C))}^{V} \\ + & g {([A, C], B)}^{V} + {(Z g (A, B))}^{V} - g {([B, C], A)}^{V}] \\ - & {A [(A (Φ (B, C))}^{V} {- (B (Φ (A, C))}^{V} \\ + & (C {(Φ (A, B))}^{V} - (Φ {([A, B], C)}^{V}) + (Φ {([A, C], B)}^{V}) \\ - & (Φ {([B, C], A)}^{V}) + Ω (γ R (A, B), C^{H}) \\ - & Ω (γ R (A, C), B^{H}) + Ω (γ R (B, C), A^{H}), \\ (i i) 3 d Ω (A^{H}, B^{H}, C^{(β)}) & = & A \sqrt{q} [A^{H} δ_{2 n + 1}^{β} η {(C)}^{V} η {(B)}^{V} \\ - & B^{H} δ_{2 n + 1}^{β} η {(C)}^{V} η {(A)}^{V} \\ + & C^{(β)} {\frac{p}{2} g {(A, B)}^{V} - Φ {(A, B)}^{V}} \\ - & δ_{2 n + 1}^{β} {(η ([A, B]) η (C))}^{V} + Ω (γ R (A, B), C^{(β)}) \\ + & δ_{2 n + 1}^{β} {(η (\nabla_{X} Z) η (B))}^{V} \\ - & δ_{2 n + 1}^{β} {(η (\nabla_{Y} Z) η (A))}^{V}] \\ = & A \sqrt{q} [δ_{2 n + 1}^{β} {(A η (C) η (B))}^{V} \\ - & δ_{2 n + 1}^{β} {(B η (C) η (A))}^{V} \\ - & δ_{2 n + 1}^{β} {(η ([A, B]) η (C))}^{V} + Ω (γ R (A, B), C^{(β)}) \\ + & δ_{2 n + 1}^{β} {(η (\nabla_{X} Z) η (B))}^{V} \\ - & δ_{2 n + 1}^{β} {(η (\nabla_{Y} Z) η (A))}^{V}] . \end{matrix}

Formulas

(i i i)

and

(i v)

can be easily obtained. □

4. Behavior of the Nijehuis Tensor on FM

The Nijenhuis tensor of

\tilde{J}

is expressed by

N (\tilde{A}, \tilde{B}) = [\tilde{J} \tilde{A}, \tilde{J} \tilde{B}] - \tilde{J} [\tilde{J} \tilde{A}, \tilde{B}] - \tilde{J} [\tilde{A}, \tilde{J} \tilde{B}] + {\tilde{J}}^{2} [\tilde{A}, \tilde{B}] .

Theorem 4.

\forall \tilde{A}, \tilde{B} \in ℑ_{0}^{1} (F M)

, then

\begin{matrix} (i) N (A^{H}, B^{H}) & = & \frac{p A}{2} {{(\nabla_{ϕ B} A)}^{(β)} - {(\nabla_{ϕ A} B)}^{(β)}} \\ + & A^{2} {[ϕ A, ϕ B]}^{H} - A \tilde{J} {[ϕ A, B]}^{H} \\ - & A \tilde{J} {[A, ϕ B]}^{H} + {\tilde{J}}^{2} {[A, B]}^{H} \\ + & A^{2} {(η (B)}^{V} ({(\nabla_{ϕ A} ζ)}^{(2 n + 1)} - {(\nabla_{ϕ B} ζ)}^{(2 n + 1)}) \\ + & A^{2} ({(\nabla_{ϕ A} ζ)}^{(2 n + 1)} + {(ϕ \nabla_{A} ζ)}^{(2 n + 1)}) (η {(B)}^{V} \\ - & A^{2} ({(\nabla_{ϕ B} ζ)}^{(2 n + 1)} + {(ϕ \nabla_{B} ζ)}^{(2 n + 1)}) (η {(A)}^{V} \\ + & A^{2} (η {(\nabla_{B} ζ)}^{V} η {(A)}^{V} - η {(\nabla_{A} ζ)}^{V} η {(B)}^{V}) ζ^{H} \\ + & \frac{p A}{2} {{(\nabla_{B} A)}^{(2 n + 1)} - {(\nabla_{A} B)}^{(2 n + 1)}} \\ - & A^{2} γ R (ϕ A, ϕ B) + A \tilde{J} γ R (ϕ A, B) \\ + & A \tilde{J} γ R (ϕ A, B) - {\tilde{J}}^{2} γ R (A, B), \\ (i i) N (A^{(α)}, B^{(β)}) & = & \sqrt{q} {A^{2} [(δ_{2 n + 1}^{β} η {(B)}^{V} {(\nabla_{ζ} (ϕ A))}^{α} \\ + & ε (α) η {(A)}^{V} η {(B)}^{V} δ_{2 n + 1}^{β} {(\nabla_{ζ} ζ)}^{(α + ε (α) n)} \\ - & δ_{2 n + 1}^{β} η {(A)}^{V} {(\nabla_{ζ} (ϕ B))}^{α} \\ - & ε (β) η {(A)}^{V} η {(B)}^{V} δ_{2 n + 1}^{α} {(\nabla_{ζ} ζ)}^{(β + ε (β) n)} \\ + & δ_{2 n + 1}^{α} δ_{2 n + 1}^{β} ({[ζ, ζ]}^{H} - γ R (ζ, ζ))] \\ - & \frac{p A}{2} {(\nabla_{ζ} B)}^{(β)} - \frac{p}{2} δ_{2 n + 1}^{β} η {(B)}^{V} {(\nabla_{A} ζ)}^{(α)} \\ - & \frac{p A}{2} A^{(α)} δ_{2 n + 1}^{α} η {(A)}^{V} \\ + & A^{2} X^{(α)} δ_{2 n + 1}^{α} η {(A)}^{V} ({(ϕ \nabla_{ζ} B)}^{(β)} \\ + & ε (β) η {(\nabla_{ζ} B)}^{V} ζ^{(β + ε (β) n)} - δ_{2 n + 1}^{β} η {(\nabla_{ζ} B)}^{V} ζ^{H}) \\ - & \frac{p A}{2} B^{(β)} δ_{2 n + 1}^{α} η {(B)}^{V} \\ + & A^{2} Y^{(α)} δ_{2 n + 1}^{α} η {(B)}^{V} ({(ϕ \nabla_{ζ} A)}^{(β)} \\ + & ε (β) η {(\nabla_{ζ} A)}^{V} ζ^{(β + ε (β) n)} - δ_{2 n + 1}^{β} η {(\nabla_{ζ} A)}^{V} ζ^{H})}, \end{matrix}

\begin{matrix} (i i i) N (A^{H}, B^{(β)}) & = & - \frac{p A}{2} \sqrt{q} δ_{2 n + 1}^{β} η {(B)}^{V} {(\nabla_{ζ} A)}^{(β)} - \frac{p A}{2} {(\nabla_{ϕ A} B)}^{(β)} \\ + & A^{2} {(\nabla_{ϕ A} ϕ B)}^{(β)} + A^{2} \sqrt{q} {ε (β) η {(B)}^{V} {(\nabla_{ϕ A} ζ)}^{(β + ε (β) n)} \\ - & δ_{2 n + 1}^{β} η {(B)}^{V} ([ϕ A, ζ] - γ R (ϕ A, ζ)) \\ + & δ_{2 n + 1}^{β} η {(A)}^{V} η {(B)}^{V} {(\nabla_{ζ} ζ)}^{(2 n + 1)} - ϕ \nabla_{ϕ A} {B)}^{(β)} \\ + & ε (β) η {(\nabla_{ϕ A} B)}^{V} ζ^{(β + ε (β) n)} - δ_{2 n + 1}^{β} η {(\nabla_{ϕ A} B)}^{V} ζ^{H})} \\ + & \frac{p A}{2} {(\nabla_{ϕ A} B)}^{V} - p A ({(ϕ \nabla_{X} Y)}^{(β)} \\ + & p A ({(ϕ \nabla_{A} ϕ B)}^{(β)} \\ + & \sqrt{q} {ε (β) η {(\nabla_{X} Y)}^{V} ζ^{(β + ε (β) n)} - δ_{2 n + 1}^{β} η {(\nabla_{X} Y)}^{V} ζ^{H}) \\ + & + ε (β) η {(\nabla_{A} ϕ B)}^{V} ζ^{(β + ε (β) n)} \\ - & δ_{2 n + 1}^{β} η {(\nabla_{A} ϕ B)}^{V} ζ^{H}) + ε (β) η {(B)}^{V} {(ϕ \nabla_{A} ζ)}^{(β + ε (β) n)} \\ + & ε^{2} (β) η {(B)}^{V} η {(ϕ \nabla_{A} ζ)}^{V} ζ^{(β + ε (β) n)} - δ_{2 n + 1}^{β} ε (β) η {(B)}^{V} η {(ϕ \nabla_{A} ζ)}^{V} ζ^{H}) \\ - & δ_{2 n + 1}^{β} η {(B)}^{V} ({(ϕ [A, ζ])}^{H} + η {[A, ζ]}^{V} ζ^{(2 n + 1)}, - γ \tilde{J} R (A, ζ)))} \end{matrix}

where

α, β = 1, \dots, 2 n + 1

.

Proof.

Using (22) and Theorem (1), Theorem (4) is proven. □

5. Example

Let

{e_{i}, ϕ e_{i}, ζ}

be a basis in

(M, ϕ, ζ, η, g)

where i denotes 1 to n. The coderivative

δ Ω

with basis

{e_{i}^{H}, {(ϕ e_{i})}^{H}, ζ^{H}, e_{i}^{(α)}, {(ϕ e_{i})}^{(α)}, ζ^{(α)}}

can be expressed as [16]

\begin{matrix} δ Ω (\tilde{A}) & = & - \sum_{i = 1}^{n} {({\tilde{\nabla}}_{e_{i}^{H}} Ω) (e_{i}^{H}, \tilde{A}) + ({\tilde{\nabla}}_{{(ϕ e_{i})}^{H}} Ω) ({(ϕ e_{i})}^{H}, \tilde{A})} \\ + & \sum_{j = 1}^{n} ({\tilde{\nabla}}_{ζ^{(j)}} Ω) (ζ^{(j)}, \tilde{A}) - ({\tilde{\nabla}}_{ζ^{(2 n + 1)}} Ω) (ζ^{(2 n + 1)}, \tilde{A}) \\ - & ({\tilde{\nabla}}_{ζ^{H}} Ω) (ζ^{H}, \tilde{A}) - \sum_{α = 1}^{2 n + 1} \sum_{i = 1}^{n} {{\tilde{\nabla}}_{e_{i}^{(α)}} Ω) (e_{i}^{(α)}, \tilde{A}) \\ + & ({\tilde{\nabla}}_{{(ϕ e_{i})}^{(α)}} F) ({(ϕ e_{i})}^{(α)}, \tilde{A})} . \end{matrix}

(31)

Taking

\tilde{A} = A^{(β)}

in (31), using (11) and (29), we acquire

\begin{matrix} δ Ω (A^{(β)}) & = & - \sum_{i = 1}^{n} {g^{D} (\nabla_{e_{i}^{H}} e_{i}^{H}, \tilde{J} A^{(β)}) + g^{D} (\nabla_{{(ϕ E}_{i})^{H}} {(ϕ e_{i})}^{H}, \tilde{J} A^{(β)})} \\ - & g^{D} (\nabla_{ζ^{H}} ζ^{H}, \tilde{J} A^{(β)}) \\ = & - \sum_{i = 1}^{n} {- g^{D} (γ R (e_{i}, e_{i}), \frac{p}{2} A^{(β)}) - A [- g^{D} (γ R (ϕ e_{i}, e_{i}), A^{(β)}) \\ - & \sqrt{q} δ_{2 n + 1}^{β} η {(A)}^{V} g {(\nabla_{e_{i}} ζ, e_{i})}^{V} - \sqrt{q} δ_{2 n + 1}^{β} η {(A)}^{V} g {(\nabla_{ϕ e_{i}} ζ, ϕ e_{i})}^{V}} \\ + & \sqrt{q} δ_{2 n + 1}^{β} g (\nabla_{ζ^{H}} ζ^{H}, A^{V})] \\ = & \frac{p}{2} \sum_{i = 1}^{n} {g^{D} (γ R (e_{i}, e_{i}), A^{(β)}) - A [- g^{D} (γ R (e_{i}, ϕ e_{i}), A^{(β)}) \\ + & \sqrt{q} δ_{2 n + 1}^{β} {η {(A)}^{V} {(δ η)}^{V}, (\nabla_{ζ} η) A^{V}}], \end{matrix}

where

\begin{matrix} δ η = - \sum_{i = 1}^{n} {(\nabla_{e_{i}} η) ζ_{i} + (\nabla_{ϕ e_{i}} η) ϕ ζ_{i}} \end{matrix}

and

\begin{matrix} (\nabla_{ζ} η) A = g (A, \nabla_{ζ} ζ) . \end{matrix}

Taking

\tilde{A} = A^{H}

in (31), using (11) and (29), we acquire

\begin{matrix} δ Ω (A^{H}) & = & - \sum_{i = 1}^{n} {g^{D} (\nabla_{e_{i}^{H}} e_{i}^{H}, \tilde{J} A^{H}) + g^{D} (\nabla_{{(ϕ E}_{i})^{H}} {(ϕ e_{i})}^{H}, \tilde{J} A^{H}} \\ - & g^{D} (\nabla_{ζ^{(2 n + 1)}} ζ^{(2 n + 1)}, \tilde{J} A^{H}) - g^{D} (\nabla_{ζ^{H}} ζ^{H}, \tilde{J} A^{H}) \\ - & \sum_{α = 1}^{2 n + 1} \sum_{i = 1}^{n} (g^{D} (\nabla_{e_{i}^{(α)}} e_{i}^{(α)}, \tilde{J} A^{H}) + g^{D} (\nabla_{{(ϕ E}_{i})^{(α)}} {(ϕ e_{i})}^{(α)}, \tilde{J} A^{H}) . \\ = & - \frac{p}{2} \sum_{i = 1}^{n} [{(g (\nabla_{e_{i}} e_{i}, A))}^{V} + {(g (\nabla_{ϕ e_{i}} ϕ e_{i}, A))}^{V} + {(g (\nabla_{ζ} ζ, A))}^{V}] \\ - & A [- \sum_{i = 1}^{n} (- g {((\nabla_{e_{i}} ϕ) e_{i}, A)}^{V} - g {((\nabla_{ϕ e_{i}} ϕ) ϕ e_{i}, A)}^{V}) \\ + & g {((\nabla_{ζ} ϕ) ζ, A)}^{V}] . \\ = & - \frac{p}{2} \sum_{i = 1}^{n} [{(g (\nabla_{e_{i}} e_{i}, A))}^{V} + {(g (\nabla_{ϕ e_{i}} ϕ e_{i}, A))}^{V} + {(g (\nabla_{ζ} ζ, A))}^{V}] \\ - & A {(δ Φ (A))}^{V}, \end{matrix}

where

δ Φ (A) = - \sum_{i = 1}^{n} (\nabla_{e_{i}} Φ) (e_{i}, A) + (\nabla_{ϕ e_{i}} Φ) (ϕ e_{i}, A)) - (\nabla_{ζ} Φ) (ζ, A) .

and

(\nabla_{A} Φ) (B, C) = - g ((\nabla_{A} ϕ) (B, C) .

Author Contributions

Conceptualization, T.A., U.C.D. and M.N.I.K.; methodology, T.A., U.C.D. and M.N.I.K.; investigation, T.A., U.C.D. and M.N.I.K.; writing—original draft preparation, T.A., U.C.D. and M.N.I.K.; writing—review and editing, T.A., U.C.D. and M.N.I.K. All authors have read and agreed to the published version of the manuscript.

Funding

Researcher would like to thank the Deanship of Scientific Research, Qassim University, for funding publication of this project.

Data Availability Statement

This manuscript has no associated data.

Acknowledgments

Researcher would like to thank the Deanship of Scientific Research, Qassim University, for funding publication of this project.

Conflicts of Interest

The authors declare no conflict of interest.

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Khan, M.N.I.; De, U.C.; Alam, T. Characterizations of the Frame Bundle Admitting Metallic Structures on Almost Quadratic ϕ-Manifolds. Mathematics 2023, 11, 3097. https://doi.org/10.3390/math11143097

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Khan MNI, De UC, Alam T. Characterizations of the Frame Bundle Admitting Metallic Structures on Almost Quadratic ϕ-Manifolds. Mathematics. 2023; 11(14):3097. https://doi.org/10.3390/math11143097

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Khan, Mohammad Nazrul Islam, Uday Chand De, and Teg Alam. 2023. "Characterizations of the Frame Bundle Admitting Metallic Structures on Almost Quadratic ϕ-Manifolds" Mathematics 11, no. 14: 3097. https://doi.org/10.3390/math11143097

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Characterizations of the Frame Bundle Admitting Metallic Structures on Almost Quadratic ϕ-Manifolds

Abstract

1. Introduction

2. Preliminaries

2.1. Metallic Structure

2.2. Almost Quadratic $ϕ$ -Structure

3. Proposed Theorems on FM Admitting Metallic Structures on Almost Quadratic $ϕ$ -Manifolds

4. Behavior of the Nijehuis Tensor on FM

5. Example

Author Contributions

Funding

Data Availability Statement

Acknowledgments

Conflicts of Interest

References

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Characterizations of the Frame Bundle Admitting Metallic Structures on Almost Quadratic ϕ-Manifolds

Abstract

1. Introduction

2. Preliminaries

2.1. Metallic Structure

2.2. Almost Quadratic ϕ -Structure

3. Proposed Theorems on FM Admitting Metallic Structures on Almost Quadratic ϕ -Manifolds

4. Behavior of the Nijehuis Tensor on FM

5. Example

Author Contributions

Funding

Data Availability Statement

Acknowledgments

Conflicts of Interest

References

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2.2. Almost Quadratic $ϕ$ -Structure

3. Proposed Theorems on FM Admitting Metallic Structures on Almost Quadratic $ϕ$ -Manifolds