New Applications of Gegenbauer Polynomials on a New Family of Bi-Bazilevič Functions Governed by the q-Srivastava-Attiya Operator

Wanas, Abbas Kareem; Cotîrlǎ, Luminiţa-Ioana

doi:10.3390/math10081309

Open AccessArticle

New Applications of Gegenbauer Polynomials on a New Family of Bi-Bazilevič Functions Governed by the q-Srivastava-Attiya Operator

by

Abbas Kareem Wanas

¹

and

Luminiţa-Ioana Cotîrlǎ

^2,*

¹

Department of Mathematics, College of Science, University of Al-Qadisiyah, Al Diwaniyah 58801, Iraq

²

Department of Mathematics, Technical University of Cluj-Napoca, 400114 Cluj-Napoca, Romania

^*

Author to whom correspondence should be addressed.

Mathematics 2022, 10(8), 1309; https://0-doi-org.brum.beds.ac.uk/10.3390/math10081309

Submission received: 9 March 2022 / Revised: 8 April 2022 / Accepted: 13 April 2022 / Published: 14 April 2022

(This article belongs to the Special Issue New Trends in Complex Analysis Researches)

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Abstract

:

In the present paper, making use of Gegenbauer polynomials, we initiate and explore a new family

J_{Σ} (λ, γ, s, t, q; h)

of holomorphic and bi-univalent functions which were defined in the unit disk

D

associated with the q-Srivastava–Attiya operator. We establish the bounds for

| a_{2} |

and

| a_{3} |

, where

a_{2}

,

a_{3}

are the initial Taylor–Maclaurin coefficients. For the new family of functions

J_{Σ} (λ, γ, s, t, q; h)

we investigate the Fekete-Szegö inequality, special cases and consequences.

Keywords:

holomorphic function; Bazilevič function; bi-univalent function; Fekete–Szegö inequality; q-Srivastava–Attiya operator; upper bounds; Gegenbauer polynomials

MSC:

30C45; 30C50; 11B39; 33C05

1. Introduction

We denote by

A

the family of holomorphic functions of the form

f (z) = z + \sum_{n = 2}^{\infty} a_{n} z^{n},

(1)

in the open unit disk

D = {z \in C : | z | < 1}

.

We indicate by

S

the subfamily of

A

consisting of the functions which are univalent in

D

.

A function

f \in A

is called a Bazilevič function in

D

if (see [1])

ℜ (\frac{z^{1 - γ} f^{'} (z)}{{(f (z))}^{1 - γ}}) > 0, z \in D; γ ≧ 0 .

The famous Koebe one-quarter theorem [2] ensures that the image of

D

under each univalent function

f \in A

contains a disk of radius

\frac{1}{4}

. Furthermore, each function

f \in S

has an inverse

f^{- 1}

defined by

f^{- 1} (f (z)) = z

and

f (f^{- 1} (w)) = w, (| w | < r_{0} (f), r_{0} (f) ≧ \frac{1}{4})

where the inverse of function f has the form

f^{- 1} (w) = w - a_{2} w^{2} + (2 a_{2}^{2} - a_{3}) w^{3} - (5 a_{2}^{3} - 5 a_{2} a_{3} + a_{4}) w^{4} + \dots .

(2)

We say that the function

f \in A

is bi-univalent in the unit disk

D

if the functions f and

f^{- 1}

are univalent in

D

. The family of all bi-univalent functions in

D

is denoted by

Σ

.

In fact, Srivastava et al. [3] have actually revived the study of analytic and bi-univalent functions in recent years. This was followed by such works as those by Ali et al. [4], Bulut et al. [5], Srivastava and et al. [6] and others (see, for example, [7,8,9,10,11,12]).

The examples of functions in the family

Σ

are:

\frac{z}{1 - z}, - log (1 - z) and \frac{1}{2} log (\frac{1 + z}{1 - z});

see [3].

We notice that the family

Σ

is not empty. However, the Koebe function is not a member of

Σ .

The problem of obtaining the general coefficient bounds on the Taylor–Maclaurin coefficients

| a_{n} | (n \in N; n ≧ 3)

for functions

f \in Σ

is still not completely addressed for many of the subfamilies of

Σ

. The Fekete–Szegö functional

|a_{3} - η a_{2}^{2}|

for

f \in S

is well known for its rich history in the field of geometric function theory. Its origin was in the disproof by Fekete and Szegö [13] of the Littlewood–Paley conjecture that the coefficients of odd univalent functions are bounded by unity. In recent years, many authors have obtained Fekete–Szegö inequalities for different classes of functions (see [14,15,16,17]).

We say that if g is a univalent function in

D

, then

f ≺ g (z \in U) ⟺ f (0) = g (0) and f (D) \subseteq g (D),

see [18].

The q-derivative operator

D_{q}

for a function f is defined as follows:

D_{q} f (z) = \frac{f (z) - f (q z)}{(1 - q) z}, 0 < q < 1, z \neq 0 .

For more details about this operator, see the papers [19,20,21,22,23], and for applications of

q -

calculus associated with various families of analytic, univalent or multivalent functions, see [24,25,26,27].

For a function

f \in A

, we deduce that

D_{q} f (z) = 1 + \sum_{n = 2}^{\infty} {[n]}_{q} a_{n} z^{n - 1},

where

{[n]}_{q}

is given by

{[n]}_{q} = \frac{1 - q^{n}}{1 - q}, f o r n \in N .

{[n]}_{q}

is called q-analogue of n. As

q ⟶ 1^{-}

, then we have

{[n]}_{q} ⟶ n

and

{[0]}_{q} = 0

.

The q-analogue of the Hurwitz–Lerch zeta function found in [28] and defined by the series:

ϕ_{q} (s, t; z) = \sum_{n = 0}^{\infty} \frac{z^{n}}{{[n + t]}_{q}^{s}} .

(3)

where

s \in C,

| z | < 1,

t \in C \ Z_{0}^{-},

ℜ (s) > 1

when

| z | = 1

, and the normalized form of the series given by the relation (3) is defined by:

ψ_{q} (s, t; z) = {[t + 1]}_{q}^{s} \{ϕ_{q} (s, t; z) - {[t]}_{q}^{- s}\} = z + \sum_{n = 2}^{\infty} {(\frac{{[1 + t]}_{q}}{{[n + t]}_{q}})}^{s} z^{n} .

(4)

In [28] the q-Srivastava–Attiya operator

J_{q, t}^{s} f : A ⟶ A

is defined using the relations (1) and (4) as follows:

J_{q, t}^{s} f (z) = ψ_{q} (s, t; z) * f (z) = z + \sum_{n = 2}^{\infty} {(\frac{{[t + 1]}_{q}}{{[t + n]}_{q}})}^{s} a_{n} z^{n},

the symbol * stands for the Hadamard product.

Remark 1.

The q-Srivastava–Attiya operator

J_{q, t}^{s}

is a generalization of several known operators studied in earlier investigations, which are recalled below.

(1): The operator $J_{q, t}^{s},$ for $q ⟶ 1^{-},$ coincides with the Srivastava–Attiya operator; see [29] and for applications of this operator, see [24,30];
(2): The operator $J_{q, t}^{s}$ for $s = 1$ reduces to the q-Bernardi operator; see [31];
(3): The operator $J_{q, t}^{s}$ for $s = t = 1$ reduces to the q-Libera operator; see [31];
(4): The operator $J_{q, t}^{s}$ for $q ⟶ 1^{-}$ and $s = 1$ reduces to the Bernardi operator; see [32];
(5): The operator $J_{q, t}^{s}$ for $q ⟶ 1^{-}$ , $s = 1$ and $t = 0$ reduces to the Alexander operator; see [33].

In [34] the Gegenbauer polynomials

H_{δ} (z, x)

are studied, which are given by the following recurrence relation:

for a nonzero real constant

δ

, a generating function of Gegenbauer polynomials is defined by

H_{δ} (z, x) = \frac{1}{{(1 - 2 x z + z^{2})}^{δ}},

where

x \in [- 1, 1]

and

z \in D

. For a fixed x, the function

H_{δ}

is holomorphic in

D

, so it can be expanded in a Taylor series, with a note that if

x = cos β

, where

β \in (- \frac{π}{3}, \frac{π}{3})

, then

H_{δ} (z, x) = \frac{1}{{(1 - 2 x z + z^{2})}^{δ}} = \sum_{n = 0}^{\infty} G_{n}^{δ} (x) z^{n},

(5)

where

G_{n}^{δ} (x)

is a Gegenbauer polynomial of degree n.

Clearly,

H_{δ}

generates nothing when

δ = 0

. Thus, the generating function of the Gegenbauer polynomial is set to be

H_{0} (z, x) = 1 - log (1 - 2 x z + z^{2}) = \sum_{n = 0}^{\infty} G_{n}^{0} (x) z^{n} .

Furthermore, it is worthwhile to mention that a normalization of

δ

to be greater than

- \frac{1}{2}

is desirable; see [35,36,37,38]. We can also define the Gegenbauer polynomials using the relation of recurrence:

G_{n}^{δ} (x) = \frac{1}{2} [2 x (n + δ - 1) G_{n - 1}^{δ} (x) - (n + 2 δ - 2) G_{n - 1}^{δ} (x)],

with the initial values

G_{0}^{δ} (x) = 1, G_{1}^{δ} (x) = 2 δ x and G_{2}^{δ} (x) = 2 δ (δ + 1) x^{2} - δ .

(6)

Remark 2.

By choosing the particular values of δ, the Gegenbauer polynomial

G_{n}^{δ} (x)

leads to well-known polynomials. These special cases are:

The Chebyshev polynomials, taking $δ = 1$ .
The Legendre polynomials, taking $δ = \frac{1}{2}$ .

2. Main Results

We introduce the family of functions denoted by

J_{Σ} (λ, γ, s, t, q; h)

and defined as follows:

Definition 1.

Assume that

0 < λ ≦ 1

,

γ ≧ 0

and h is analytic in

D

,

h (0) = 1

. The family

J_{Σ} (λ, γ, s, t, q; h)

contains all the functions

f \in Σ

which satisfy the subordinations:

\frac{1}{2} (\frac{z^{1 - γ} {(J_{q, t}^{s} f (z))}^{'}}{{(J_{q, t}^{s} f (z))}^{1 - γ}} + {(\frac{z^{1 - γ} {(J_{q, t}^{s} f (z))}^{'}}{{(J_{q, t}^{s} f (z))}^{1 - γ}})}^{\frac{1}{λ}}) ≺ h (z)

and

\frac{1}{2} (\frac{w^{1 - γ} {(J_{q, t}^{s} f^{- 1} (w))}^{'}}{{(J_{q, t}^{s} f^{- 1} (w))}^{1 - γ}} + {(\frac{w^{1 - γ} {(J_{q, t}^{s} f^{- 1} (w))}^{'}}{{(J_{q, t}^{s} f^{- 1} (w))}^{1 - γ}})}^{\frac{1}{λ}}) ≺ h (w),

where the function

f^{- 1}

is given by (2).

Theorem 1.

Assume that

γ ≧ 0

and

0 < λ ≦ 1

. If the family

J_{Σ} (γ, λ, s, t, q; h)

contains all the functions

f \in Σ

defined by the relation (1), with

h (z) = 1 + e_{1} z + e_{2} z^{2} + \dots

. Then

|a_{2}| ≦ \frac{| 2 λ e_{1} {[2 + t]}_{q}^{s} |}{(λ + 1) {[1 + t]}_{q}^{s} (γ + 1)}

(7)

and

\begin{matrix} |a_{3}| ≦ max \{|\frac{2 λ {[3 + t]}_{q}^{s} e_{1}}{(γ + 2) (λ + 1) {[1 + t]}_{q}^{s}}|, |\frac{2 λ {[3 + t]}_{q}^{s} e_{2}}{(γ + 2) (λ + 1) {[1 + t]}_{q}^{s}} - \frac{2 λ Ω (λ, γ) {[3 + t]}_{q}^{s} e_{1}^{2}}{(γ + 2) {(γ + 1)}^{2} {(λ + 1)}^{3} {[1 + t]}_{q}^{s}}|, \\ |\frac{2 λ {[3 + t]}_{q}^{s} e_{1}}{(γ + 2) (λ + 1) {[1 + t]}_{q}^{s}}|, |\frac{2 λ {[3 + t]}_{q}^{s} e_{2}}{(γ + 2) (λ + 1) {[1 + t]}_{q}^{s}} \\ - \frac{(8 λ^{2} (γ + 2) (λ + 1) {[2 + t]}_{q}^{2 s} + 2 λ Ω (λ, γ) {[1 + t]}_{q}^{s} {[3 + t]}_{q}^{s}) e_{1}^{2}}{{(γ + 1)}^{2} (γ + 2) {[{1 + t]}_{q}^{2 s} (λ + 1)}^{3}}|\}, \end{matrix}

(8)

where

Ω (λ, γ) = λ (γ - 1) (γ + 2) (λ + 1) + (1 - λ) {(γ + 1)}^{2} .

(9)

Proof.

Suppose that

f \in J_{Σ} (λ, γ, s, t, q; e_{1}; e_{2})

. Then there exists the functions

φ, χ : D ⟶ D,

holomorphically, where

φ (z) = r_{1} z + r_{2} z^{2} + r_{3} z^{3} + \dots (z \in D)

(10)

and

χ (w) = s_{1} w + s_{2} w^{2} + s_{3} w^{3} + \dots (w \in D),

(11)

with

ϕ (0) = ψ (0) = 0

,

|φ (z)| < 1

,

|χ (w)| < 1

,

z, w \in D

such that

\frac{1}{2} (\frac{z^{1 - γ} {(J_{q, t}^{s} f (z))}^{'}}{{(J_{q, t}^{s} f (z))}^{1 - γ}} + {(\frac{z^{1 - γ} {(J_{q, t}^{s} f (z))}^{'}}{{(J_{q, t}^{s} f (z))}^{1 - γ}})}^{\frac{1}{λ}}) = 1 + e_{1} φ (z) + e_{2} φ^{2} (z) + \dots

(12)

and

\frac{1}{2} (\frac{w^{1 - γ} {(J_{q, t}^{s} f^{- 1} (w))}^{'}}{{(J_{q, t}^{s} f^{- 1} (w))}^{1 - γ}} + {(\frac{w^{1 - γ} {(J_{q, t}^{s} f^{- 1} (w))}^{'}}{{(J_{q, t}^{s} f^{- 1} (w))}^{1 - γ}})}^{\frac{1}{λ}}) = 1 + e_{1} χ (w) + e_{2} χ^{2} (w) + \dots .

(13)

Combining (10)–(13), we yield

\frac{1}{2} (\frac{w^{1 - γ} {(J_{q, t}^{s} f^{- 1} (w))}^{'}}{{(J_{q, t}^{s} f^{- 1} (w))}^{1 - γ}} + {(\frac{w^{1 - γ} {(J_{q, t}^{s} f^{- 1} (w))}^{'}}{{(J_{q, t}^{s} f^{- 1} (w))}^{1 - γ}})}^{\frac{1}{λ}}) = 1 + e_{1} r_{1} z + [e_{1} r_{2} + e_{2} r_{1}^{2}] z^{2} + \dots

(14)

and

\frac{1}{2} (\frac{w^{1 - γ} {(J_{q, t}^{s} f^{- 1} (w))}^{'}}{{(J_{q, t}^{s} f^{- 1} (w))}^{1 - γ}} + {(\frac{w^{1 - γ} {(J_{q, t}^{s} f^{- 1} (w))}^{'}}{{(J_{q, t}^{s} f^{- 1} (w))}^{1 - γ}})}^{\frac{1}{λ}}) = 1 + e_{1} s_{1} w + [e_{1} s_{2} + e_{2} s_{1}^{2}] w^{2} + \dots .

(15)

If if the inequalities

|φ (z)| < 1

and

|χ (w)| < 1,

z, w \in D

are true, we know that

|r_{j}| \leq 1, |s_{j}| \leq 1,

(16)

for all

j \in N

. For more details, see [2].

We obtain the next relation

\frac{(λ + 1) (γ + 1) {[t + 1]}_{q}^{s}}{2 {[t + 2]}_{q}^{s} λ} a_{2} = e_{1} r_{1},

(17)

after simplifying in the relations (14) and (15)

\begin{matrix} \frac{(λ + 1) (γ + 2) {[1 + t]}_{q}^{s}}{2 λ {[3 + t]}_{q}^{s}} a_{3} + \frac{[λ (λ + 1) (γ - 1) (γ + 2) - (λ - 1) {(γ + 1)}^{2}] {[1 + t]}_{q}^{2 s}}{4 λ^{2} {[2 + t]}_{q}^{2 s}} a_{2}^{2} \\ = e_{1} r_{2} + e_{2} r_{1}^{2}, \end{matrix}

(18)

- \frac{(1 + γ) {[t + 1]}_{q}^{s} (1 + λ)}{2 {[t + 2]}_{q}^{s} λ} a_{2} = e_{1} s_{1}

(19)

and

\begin{matrix} \frac{(γ + 2) (λ + 1) {[1 + t]}_{q}^{s}}{2 λ {[3 + t]}_{q}^{s}} (2 a_{2}^{2} - a_{3}) + \frac{[λ (γ + 2) (γ - 1) (λ + 1) + {(γ + 1)}^{2} (1 - λ)] {[1 + t]}_{q}^{2 s}}{4 λ^{2} {[2 + t]}_{q}^{2 s}} a_{2}^{2} \\ = e_{1} s_{2} + e_{2} s_{1}^{2} . \end{matrix}

(20)

Inequality (7) follows from (17) and (19). We deduce from the relations (17) and (18) that

\frac{(1 + λ) (2 + γ) {[1 + t]}_{q}^{s}}{2 λ {[3 + t]}_{q}^{s} e_{1}} a_{3} = r_{2} + (\frac{e_{2}}{e_{1}} - \frac{Ω (λ, γ) e_{1}}{{(γ + 1)}^{2} {(λ + 1)}^{2}}) r_{1}^{2},

(21)

where

Ω (λ, γ)

is given by (9). By using the known sharp result (see in [18]):

| r_{2} - μ r_{1}^{2} | ≦ max \{1, | μ |\}

(22)

for all

μ \in C

, we obtain

|\frac{(γ + 2) (λ + 1) {[1 + t]}_{q}^{s}}{2 λ {[3 + t]}_{q}^{s} e_{1}}| | a_{3} | ≦ max \{1, |\frac{e_{2}}{e_{1}} - \frac{Ω (λ, γ) e_{1}}{{(γ + 1)}^{2} {(λ + 1)}^{2}}|\} .

(23)

Following from (19) and (20), we deduce that

\begin{matrix} - \frac{(γ + 2) (λ + 1) {[1 + t]}_{q}^{s}}{2 λ {[3 + t]}_{q}^{s} e_{1}} a_{3} = s_{2} + (\frac{e_{2}}{e_{1}} - \frac{(4 λ (γ + 2) (λ + 1) {[2 + t]}_{q}^{2 s} + Ω (λ, γ) {[1 + t]}_{q}^{s} {[3 + t]}_{q}^{s}) e_{1}}{{(γ + 1)}^{2} {(λ + 1)}^{2} {[1 + t]}_{q}^{s} {[3 + t]}_{q}^{s}}) s_{1}^{2} . \end{matrix}

(24)

Applying (22), we obtain

\begin{matrix} |\frac{(γ + 2) (λ + 1) {[1 + t]}_{q}^{s}}{2 λ {[3 + t]}_{q}^{s} e_{1}}| | a_{3} | ≦ & max \{1, |\frac{e_{2}}{e_{1}} \\ - \frac{(4 λ (γ + 2) (λ + 1) {[2 + t]}_{q}^{2 s} + Ω (λ, γ) {[1 + t]}_{q}^{s} {[3 + t]}_{q}^{s}) e_{1}}{{(γ + 1)}^{2} {(λ + 1)}^{2} {[1 + t]}_{q}^{s} {[3 + t]}_{q}^{s}}|\} . \end{matrix}

(25)

Inequality (8) follows from (23) and (25). □

If we take the generating function (5) of the Gegenbauer polynomials

G_{n}^{δ} (x)

as

h (z)

, then from (6), we have

e_{1} = 2 δ x

and

e_{2} = 2 δ (δ + 1) x^{2} - δ

, and we obtain the next corollary.

Corollary 1.

If the class

J_{Σ} (λ, γ, s, t, q; H_{δ} (z, x))

contains all the functions

f \in Σ

given by (1), then

|a_{2}| ≦ \frac{{| 4 λ δ x [2 + t]}_{q}^{s} |}{(γ + 1) (λ + 1) {[1 + t]}_{q}^{s}}

and

\begin{matrix} |a_{3}| ≦ max \{|\frac{4 λ δ x {[3 + t]}_{q}^{s}}{(γ + 2) (λ + 1) {[1 + t]}_{q}^{s}}|, \\ |\frac{2 λ (2 δ (δ + 1) x^{2} - δ) {[3 + t]}_{q}^{s}}{(γ + 2) (λ + 1) {[1 + t]}_{q}^{s}} - \frac{8 λ δ^{2} x^{2} Ω (λ, γ) {[3 + t]}_{q}^{s}}{(γ + 2) {(γ + 1)}^{2} {(λ + 1)}^{3} {[1 + t]}_{q}^{s}}|, \\ |\frac{4 λ δ x {[3 + t]}_{q}^{s}}{(γ + 2) (λ + 1) {[1 + t]}_{q}^{s}}|, |\frac{2 (2 δ (δ + 1) x^{2} - δ) λ {[3 + t]}_{q}^{s}}{(γ + 2) (λ + 1) {[1 + t]}_{q}^{s}} \\ - \frac{8 λ δ^{2} x^{2} (4 λ (γ + 2) (λ + 1) {[2 + t]}_{q}^{2 s} + Ω (λ, γ) {[1 + t]}_{q}^{s} {[3 + t]}_{q}^{s})}{{(1 + γ)}^{2} (2 + γ) {(1 + λ)}^{3} {[1 + t]}_{q}^{2 s}}|\}, \end{matrix}

for all

λ, γ, t, s, q, x

such that

0 < λ ≦ 1

,

t \in C \ Z_{0}^{-}

,

γ ≧ 0

,

s \in C

,

x \in R

,

0 < q < 1

, where

H_{δ} (z, x)

is given by (5).

The Fekete–Szegö inequality for the family functions

J_{Σ} (λ, γ, s, t, q; h)

is given in the next theorem.

Theorem 2.

If the class

J_{Σ} (λ, γ, s, t, q; h)

contains all the functions

f \in Σ

given by the relation (1), then

\begin{matrix} |a_{3} - η a_{2}^{2}| ≦ | \frac{2 λ {[3 + t]}_{q}^{s} e_{1}}{(γ + 2) (λ + 1) {[1 + t]}_{q}^{s}} | \times \\ \times max \{1, |\frac{e_{2}}{e_{1}} - \frac{(Ω (λ, γ) {[1 + t]}_{q}^{s} {[3 + t]}_{q}^{s} - 2 η λ (γ + 2) (λ + 1) {[2 + t]}_{q}^{2 s}) e_{1}}{{(1 + λ)}^{2} {(1 + γ)}^{2} {[t + 3]}_{q}^{s} {[t + 1]}_{q}^{s}}|, \\ |\frac{e_{2}}{e_{1}} - \frac{(Ω (λ, γ) {[t + 1]}_{q}^{s} {[t + 3]}_{q}^{s} + 2 (2 - η) λ (γ + 2) (λ + 1) {[2 + t]}_{q}^{2 s}) e_{1}}{{(1 + γ)}^{2} {(1 + λ)}^{2} {[t + 1]}_{q}^{s} {[t + 3]}_{q}^{s}}|\}, \end{matrix}

(26)

for all

λ, γ, t, s, q, x

such that

0 < λ ≦ 1

,

γ ≧ 0

,

s \in C

,

t \in C ∖ Z_{0}^{-}

,

η \in C

and

0 < q < 1 .

Proof.

We apply the notations from the proof of Theorem 1. From (17), (18) and (21), we have

\begin{matrix} a_{3} - η a_{2}^{2} = \frac{2 λ {[3 + t]}_{q}^{s} e_{1}}{(γ + 2) (λ + 1) {[1 + t]}_{q}^{s}} \times \\ \times (r_{2} + (\frac{e_{2}}{e_{1}} - \frac{(Ω (λ, γ) {[1 + t]}_{q}^{s} {[3 + t]}_{q}^{s} - 2 η λ (γ + 2) (λ + 1) {[2 + t]}_{q}^{2 s}) e_{1}}{{(γ + 1)}^{2} {(λ + 1)}^{2} {[1 + t]}_{q}^{s} {[3 + t]}_{q}^{s}}) r_{1}^{2}) \end{matrix}

and by using the known sharp result

| r_{2} - μ r_{1}^{2} | ≦ max \{1, | μ |\}

, we get

\begin{matrix} | a_{3} - η a_{2}^{2} | ≦ & | \frac{2 λ {[3 + t]}_{q}^{s} e_{1}}{(γ + 2) (λ + 1) {[1 + t]}_{q}^{s}} | \times \\ \times max \{1, |\frac{e_{2}}{e_{1}} - \frac{(Ω (λ, γ) {[1 + t]}_{q}^{s} {[3 + t]}_{q}^{s} - 2 η λ (γ + 2) (λ + 1) {[2 + t]}_{q}^{2 s}) e_{1}}{{(γ + 1)}^{2} {(λ + 1)}^{2} {[1 + t]}_{q}^{s} {[3 + t]}_{q}^{s}}|\} . \end{matrix}

(27)

In the same way, from (19), (20) and (24), we conclude that

\begin{matrix} a_{3} - η a_{2}^{2} = - \frac{2 λ {[3 + t]}_{q}^{s} e_{1}}{(γ + 2) (λ + 1) {[1 + t]}_{q}^{s}} (s_{2} + (\frac{e_{2}}{e_{1}} \\ - \frac{(Ω (λ, γ) {[1 + t]}_{q}^{s} {[3 + t]}_{q}^{s} - 2 (η - 2) λ (γ + 2) (λ + 1) {[2 + t]}_{q}^{2 s}) e_{1}}{{(γ + 1)}^{2} {(λ + 1)}^{2} {[1 + t]}_{q}^{s} {[3 + t]}_{q}^{s}}) s_{1}^{2}) \end{matrix}

and by using

| s_{2} - μ s_{1}^{2} | ≦ max \{1, | μ |\}

, we get

\begin{matrix} | a_{3} - η a_{2}^{2} | ≦ | \frac{2 λ {[3 + t]}_{q}^{s} e_{1}}{(γ + 2) (λ + 1) {[1 + t]}_{q}^{s}} | max \{1, |\frac{e_{2}}{e_{1}} \\ - \frac{(Ω (λ, γ) {[1 + t]}_{q}^{s} {[3 + t]}_{q}^{s} - 2 e_{1} (η - 2) λ (γ + 2) (λ + 1) {[2 + t]}_{q}^{2 s})}{{(1 + λ)}^{2} {(1 + γ)}^{2} {[t + 1]}_{q}^{s} {[t + 3]}_{q}^{s}}|\} . \end{matrix}

(28)

Inequality (26) follows from (27) and (28). □

Corollary 2.

If the class

J_{Σ} (λ, γ, s, t, q; H_{δ} (z, x))

contains all the functions

f \in Σ

given by the relations (1), then

\begin{matrix} |a_{3} - η a_{2}^{2}| ≦ | \frac{4 λ δ x {[3 + t]}_{q}^{s}}{(γ + 2) (λ + 1) {[1 + t]}_{q}^{s}} | \times \\ \times max \{1, |\frac{2 (δ + 1) x^{2} - 1}{2 x} - \frac{2 δ x (Ω (λ, γ) {[t + 1]}_{q}^{s} {[t + 3]}_{q}^{s} - 2 η λ (γ + 2) (λ + 1) {[2 + t]}_{q}^{2 s})}{{(1 + λ)}^{2} {(1 + γ)}^{2} {[t + 1]}_{q}^{s} {[t + 3]}_{q}^{s}}|, \\ |\frac{2 (1 + δ) x^{2} - 1}{2 x} - \frac{2 δ x (Ω (λ, γ) {[t + 1]}_{q}^{s} {[t + 3]}_{q}^{s} - 2 (η - 2) λ (γ + 2) (λ + 1) {[2 + t]}_{q}^{2 s})}{{[t + 1]}_{q}^{s} {(γ + 1)}^{2} {(λ + 1)}^{2} {[t + 3]}_{q}^{s}}|\}, \end{matrix}

for all

λ, γ, t, s, q, x

such that

0 < λ ≦ 1

,

γ ≧ 0

,

t \in C ∖ Z_{0}^{-}

,

s \in C

,

0 < q < 1

,

η \in C

and

x \in R

, where

H_{δ} (z, x)

is given by (5).

3. Conclusions

We establish in this work a new family

J_{Σ} (λ, γ, s, t, q; h)

of bi-univalent and holomorphic functions defined by the q-Srivastava–Attiya operator and using the Gegenbauer polynomials

G_{n}^{δ} (x)

, which are given by the recurrence relation (6) and generating the function

H_{δ} (z, x)

in (5). We derived initial Taylor–Maclaurin coefficient inequalities for functions belonging to this newly introduced bi-univalent function family

J_{Σ} (λ, γ, s, t, q; h)

and viewed the famous Fekete–Szegö problem.

Author Contributions

The authors contributed equally to this work. All authors have read and agreed to the published version of the manuscript.

Funding

This research received no external funding.

Institutional Review Board Statement

Not applicable.

Informed Consent Statement

Not applicable.

Data Availability Statement

Not applicable.

Conflicts of Interest

The authors declare no conflict of interest.

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Wanas, A.K.; Cotîrlǎ, L.-I. New Applications of Gegenbauer Polynomials on a New Family of Bi-Bazilevič Functions Governed by the q-Srivastava-Attiya Operator. Mathematics 2022, 10, 1309. https://0-doi-org.brum.beds.ac.uk/10.3390/math10081309

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Wanas AK, Cotîrlǎ L-I. New Applications of Gegenbauer Polynomials on a New Family of Bi-Bazilevič Functions Governed by the q-Srivastava-Attiya Operator. Mathematics. 2022; 10(8):1309. https://0-doi-org.brum.beds.ac.uk/10.3390/math10081309

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Wanas, Abbas Kareem, and Luminiţa-Ioana Cotîrlǎ. 2022. "New Applications of Gegenbauer Polynomials on a New Family of Bi-Bazilevič Functions Governed by the q-Srivastava-Attiya Operator" Mathematics 10, no. 8: 1309. https://0-doi-org.brum.beds.ac.uk/10.3390/math10081309

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New Applications of Gegenbauer Polynomials on a New Family of Bi-Bazilevič Functions Governed by the q-Srivastava-Attiya Operator

Abstract

1. Introduction

2. Main Results

3. Conclusions

Author Contributions

Funding

Institutional Review Board Statement

Informed Consent Statement

Data Availability Statement

Conflicts of Interest

References

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