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Article

On Third Hankel Determinant for Certain Subclass of Bi-Univalent Functions

by
Qasim Ali Shakir
and
Waggas Galib Atshan
*
Department of Mathematics, College of Science, University of Al-Qadisiyah, Diwaniyah 58001, Iraq
*
Author to whom correspondence should be addressed.
Symmetry 2024, 16(2), 239; https://doi.org/10.3390/sym16020239
Submission received: 17 January 2024 / Revised: 7 February 2024 / Accepted: 10 February 2024 / Published: 16 February 2024
(This article belongs to the Special Issue Geometric Function Theory and Special Functions II)

Abstract

:
This study presents a subclass S ( β ) of bi-univalent functions within the open unit disk region D . The objective of this class is to determine the bounds of the Hankel determinant of order 3, ( 3 ( 1 ) ). In this study, new constraints for the estimates of the third Hankel determinant for the class S ( β ) are presented, which are of considerable interest in various fields of mathematics, including complex analysis and geometric function theory. Here, we define these bi-univalent functions as S ( β ) and impose constraints on the coefficients a n . Our investigation provides the upper bounds for the bi-univalent functions in this newly developed subclass, specifically for n = 2, 3, 4, and 5. We then derive the third Hankel determinant for this particular class, which reveals several intriguing scenarios. These findings contribute to the broader understanding of bi-univalent functions and their potential applications in diverse mathematical contexts. Notably, the results obtained may serve as a foundation for future investigations into the properties and applications of bi-univalent functions and their subclasses.

1. Introduction

Let A indicate the collection of functions f analytic in the open unit disk D = { : C   a n d < 1 } . An analytic function f A has Taylor series expansion of the form:
f = + n = 2 a n n ,   ( D ) .
The class of all functions in A which are univalent in D is denoted by S . The Koebe-One-Quarter Theorem [1] ensures that the image of D under each f S contains a disk of radius 1 4 . Obviously, for each f S there exists an inverse function f 1 satisfying f 1 f = and f f 1 w = w , w < r ° f , r ° f 1 4 ) , where
g w = 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 + ,   ( w D )
A function f is said to be bi-univalent in D if both f and f 1 ( ) are univalent in D .
In 1967, Lewin [2] obtained a coefficient bound that is given by a 2 < 1.51  for all function f of the form (1), and he looked at the class of bi-univalent functions in D . In 1967, Clunie and Brannan [3] conjectured that a 2 2 for f . After that, Netanyahu [4] proved that a 2 =   4 3 . In 1985, Kedzierawski [5] stated that Brannan–Clunie conjectured for bi-starlike function. Brannan and Taha [6] gained evaluation estimates on the initial coefficients a 2 as well as a 3 for functions in the classes of bi-starlike functions of order ρ denoted by E Ω *   ( ρ ) and bi-convex functions of order ρ symbolled by Y Ω ( ρ ) . For all of the function classes, E Ω *   ( ρ ) and Y Ω ( ρ ) , non-sharp estimates on the first two Taylor–Maclaurin coefficients were found in these subclasses (see [7,8,9,10]). Several authors introduced initial Maclaurin coefficients bounds for subclasses of bi-univalent functions (see [11,12]). Many researchers ([11,13,14]) have studied numerous curious subclasses of the bi-univalent function class Ω and observed non-sharp bounds on the first two Taylor–Maclaurin coefficients. As well as this, the coefficient problem for all of the Taylor–Maclaurin coefficients a n , n = 3,4,... is as yet an open problem ([2]). Also, let P represent the class of analytic functions p that are normalized by the condition:
p = 1 + p 1 + p 2 2 + ,   R e p > 0 , D .
Noonan and Thomas [15] defined the q t h Hankel determinant of f , in 1976 for n 1 and q 1 by
q n = a n a n + 1 a n + q 1 a n + 1 a n + 2 a n + q a n + q 1 a n + q a n + 2 q 2 , a 1 = 1 .
For q = 2 and  n = 1 , we know that the function 2 1 = a 3 a 2 2 . The second Hankel determinant 2 2 is defined as 2 2 = a 2 a 4 a 3 2 for the classes of bi-starlike and bi-convex ([16,17,18,19]). Al-Ameedee et al. [20], studied the second Hankel determinant for certain subclasses of bi-univalent functions. Also Atshan et al. [21], discussed the Hankel determinant of m-fold symmetric bi-univalent functions using a new operator. Fekete and Szegö [22] examined the Hankel determinant of f as
2 1 = a 1 a 2 a 2 a 3 = a 1 a 3 a 2 2 .
They developed an earlier study for estimates of a 3 μ a 2 2 , where a 1 = 1 and μ R . Furthermore, for example, for those of a 3 μ a 2 2 see [23], and third Hankel determinant, these functions are studied by [16,24,25,26] functional, given by
3 1 = a 1 a 2 a 3 a 2 a 3 a 4 a 3 a 4 a 5 , a 1 = 1   and   ( n = 1 , q = 3 ) .
By applying triangle inequality for 3 1 , we have
3 1 a 3 a 2 a 4 a 3 2 a 4 a 4 a 2 a 3 + a 5 a 3 a 2 2 .  
Our paper provides a subclass S ( β ) of bi-univalent functions within the open unit disk region D . The objective of this class is to determine the bounds of the Hankel determinant of order 3, ( 3 ( 1 ) ). In this study, new constraints for the estimates of the third Hankel determinant for the class S ( β ) are presented.
The subsequent lemmas are important for establishing our results:
Lemma 1
 ([1]). Consider the class P , which consists of all analytic functions p ( ) which can be represented as
p z = 1 + n = 1 p n z n ,
with  R e p > 0 for every  D . Then  p n 2 , for every  n = 1 , 2 , .
Lemma 2 
([27]). If a function p P  is given by (4), then
2 p 2 = p 1 2 + 4 p 1 2 x
4 p 3 = p 1 3 + 2 p 1 4 p 1 2 x p 1 4 p 1 2 x 2 + 2 4 p 1 2 1 x 2 ,
for some  x ,  with  x 1  and   1 .

2. Main Results

Definition 1.
A function f  belonging to the class , as defined by Equation (1) is considered to be in the class S ( β )  if it fulfills the following requirement:
R e f f ( ) + f ( ) > β    
and
R e w g w g w + w g ( w ) > β ,  
where  0 < β 1 ,   ,   w D  and  g = f 1 .
Theorem 1.
Consider the function f ( ) as defined in Equation (1), which is an element of the class S β , where 0 β < 1 . Then, we have
a 2 a 4 a 3 2 1 β 2 208 1215 1 β 2 + 8 90 .
Proof. 
From (5) and (6), we have
f f ( ) + f = β + 1 β q
and
w g w g w + w g w = β + 1 β q w ,    
where 0 β < 1 ; p , q P , , w D and g = f 1 .
Assuming that there exists u , v : D D and u 0 = v 0 = 0 , u ( ) < 1 ,   v ( w ) < 1 and let the functions p , q P , such that
p = 1 + u ( ) 1 u ( ) = 1 + n = 1 r n n
and
q = 1 + v ( w ) 1 v ( w ) = 1 + n = 1 s n w n .
It follows that
β + 1 β p = 1 + n = 1 ( 1 β ) r n n
and
β + 1 β q w = 1 + n = 1 1 β s n w n .
Since f possesses the Maclurian series defined by (1), noticing the fact that simple computation shows that its inverse g = f 1 may be expressed using the expansion given by (2), we have
f f ( ) + f =   1 + 3 a 2 + 8 a 3 a 2 2 2 + 15 a 4 3 a 2 a 3 + a 2 3 3
+ 24 a 5 4 a 2 a 4 + 4 a 3 a 2 2 2 a 3 2 a 2 4 4 +                                        
and
w g w g w + w g ( w ) =
1 3 a 2 w + 15 a 2 2 8 a 3 w 2 70 a 2 3 72 a 2 a 3 + 15 a 4 w 3 +
140 a 2 a 4 + 315 a 2 4 504 a 2 a 3 + 70 a 3 2 + 24 a 3 a 2 2 24 a 5 w 4 + .  
Now comparing (10) and (12) with the coefficients of ,   2 ,   3 and 4 , we get
3 a 2 = 1 β r 1 ,
8 a 3 a 2 2 = 1 β r 2 ,
15 a 4 3 a 2 a 3 + a 2 3 = 1 β r 3
and
24 a 5 4 a 2 a 4 + 4 a 3 a 2 2 2 a 3 2 a 2 4 = 1 β r 4 .
Also comparing (11) and (13) with the coefficients of w , w 2 ,   w 3 and w 4 , we get
3 a 2 = 1 β s 1 ,
15 a 2 2 8 a 3 = 1 β s 2 ,
70 a 2 3 72 a 2 a 3 + 15 a 4 = 1 β s 3
and
140 a 2 a 4 + 315 a 2 4 504 a 2 a 3 + 70 a 3 2 + 24 a 3 a 2 2 24 a 5 = 1 β s 4 .
From (14) and (18), we have
1 β r 1 3 = a 2 = 1 β s 1 3 ,
It follows that its
r 1 = s 1
Subtracting (15) from (19) and (16) from (20), we get
a 3 = 1 β 2 r 1 2 9 + 1 β r 2 s 2 16
and
a 4 = 2 1 β 3 r 1 3 405 + 5 1 β 2 r 1 r 2 s 2 96 + 1 β r 3 s 3 30 .
Thus, using (22), (24) and (25), we get
a 2 a 4 a 3 2 = 1 288 1 β 3 r 1 2 r 2 s 2 13 1215 1 β 4 r 1 4
+ 1 90 1 β 2 r 1 r 3 s 3 1 256 1 β 2 r 2 s 2 2 .  
According to Lemma 2 and r 1 = s 1 , we receive
r 2 s 2 = 4 r 1 2 2 x y
and
r 3 s 3 = r 1 3 2 + 4 r 1 2 r 1 2 x + y 4 r 1 2 r 1 4 x 2 + y 2
+ 4 r 1 2 2 1   x 2 1 y 2 w ,  
for some x , y , and w with x 1 , y 1 and w 1 .
Given that p P , we have r 1 2 . Giving r 1 = r , let us suppose, without loss of generality, that r [ 0 , 2 ] . Therefore, substituting the expressions (27) and (28) in (26), letting τ = x 1 and η = y 1 , we receive
a 2 a 4 a 3 2 E 1 + E 2 τ + η + E 3 τ 2 + η 2 + E 4 τ + η 2 = E τ , η ,
where
E 1 = E 1 β , r = ( 1 β ) 2 r 4 13 1 β 2 1215 + 1 180 0 ,
E 2 = E 2 β , r = 1 β 2 4 r 2 r 2 36 1 β 16 + 1 5 0 ,
E 3 = E 3 β , r = 1 β 2 4 r 2 r 180 ( r 2 1 ) 0
and
E 4 = E 4 β , r = 1 β 2 ( 4 r 2 ) 2 1024 0 .      
Now, we need to maximize E τ , η within the closed square 0 , 1 × [ 0,1 ] for r [ 0 , 2 ] . Since E 3 0 and E 3 + 2   E 2 0 , we conclude that r ( 0,2 ) , F τ , τ F η , η F τ , η 2 < 0 . Therefore, the function F cannot have a local maximum in the interior of a closed square. Now, we investigate the maximum of F on the boundary of a closed square. When τ = 0 and 0 η 1 , we have
F 0 , η = θ η =   E 1 +   E 2 η +   E 3 +   E 4 η 2 .
Next, we will address the following two cases:
Case 1.
The inequality E 3 +   E 4 0 holds. For the given conditions of 0 η 1 , with any fixed r and 0 r < 2 , it is evident that
θ η = E 2 + 2 E 3 +   E 4 η > 0 ,
the function θ η is an increasing function. Therefore, for a fixed value of r [ 0,2 ] , the maximum of θ η is found when η = 1 and
max θ η = θ 1 = E 1 +   E 2 + E 3 + E 4 .
Case 2.
Let E 3 + E 4 < 0 . Since 2 E 3 + E 4 + E 2 0 for 0 < η < 1 with 0 < r < 2 , it is clear that 2 E 3 + E 4 + E 2 < 2 E 3 + E 4 η + E 2 < E 2 and so θ η > 0 . Hence the maximum of θ η occurs at η = 1 and 0 η 1 , we obtain
E 1 , η = φ η =   E 3 +   E 4 η 2 + E 2 + 2 E 4 η + E 1 + E 2 + E 3 + E 4 .
so, from the cases of E 3 +   E 4 , we have
max φ η = φ 1 = E 1 + 2 E 2 + 2 E 3 + 4 E 4 .
Since θ 1 φ ( 1 ) , we get  max E τ , η = E ( 1,1 ) on the boundary of square 0,1 × [ 0,1 ] . The real function L on the interval (0,1) is defined as follows:
L r = max ( E τ , η ) = E 1,1 = E 1 + 2 E 2 + 2 E 3 + 4 E 4 .
Now, putting E 1 , E 2 , E 3 and E 4 in the function L , we obtain
L r = 1 β 2 K + M ,
where
K = 13 1 β 2 1215 + 1 180 r 4
and
M = r 2 60 + ( 1 β ) r 2 288 r 90 + ( 4 r 2 ) 256 ( 4 r 2 ) .
By elementary calculations, it is found that L r is an increasing function of r . Hence, the maximum of L r is obtained when r = 2 and
max L r = L 2 = 1 β 2 208 1215 1 β 2 + 8 90 .
This completes the proof. □
Theorem 2.
Let f S β ,   0 β < 1 .Then, we have
a 2 a 3 a 4 8 1 β 13 1 β 2 405 + 1 60 , n r 2 2 15 1 β                                             , 0 r n ,
where
n = m 3 ± m 3 2 12 m 2 m 1 m 2 3 ( m 1 m 2 ) ,
m 1 = 1 β 13 1 β 2 405 + 1 60 ,
m 2 = 1 β 1 β 16 + 1 20
and
m 3 = 1 30 1 β .
Proof. 
From (22), (24) and (25), we obtain
a 2 a 3 a 4 = 13 1 β 3 r 1 3 405 3 1 β 2 r 1 r 2 s 2 96 1 β r 3 s 3 30 .
Lemma 2 implies that we can assume, without any restriction, that r [ 0,2 ] , where r 1 = r , thus for σ = x 1 and ρ = y 1 , we have
a 2 a 3 a 4 D 1 + D 2 σ + ρ + D 3 σ 2 + ρ 2 = D σ , ρ ,
where
D 1 ( β , r ) = 1 β r 3 13 1 β 2 405 + 1 60 0 ,
D 2 ( β , r ) = 1 β 4 r 2 r 1 β 32 + 1 60 0
and
D 3 β , r = 1 β 4 r 2 r 120 + 1 60 0 .
Applying the same approach as Theorem 2, we find that the maximum occur at σ = 1 and ρ = 1 within closed square [ 0,2 ] ,
φ r = max D σ , ρ = D 1 + 2 D 2 + D 3 .
Substituting the value of D 1 ,   D 2 and D 3 in φ r , we get
φ r = m 1 r 3 + m 2 r 4 r 2 + m 3 4 r 2 ,
where
m 1 = 1 β 13 1 β 2 405 + 1 60 ,
m 2 = 1 β 1 β 16 + 1 20
and
m 3 = 1 30 1 β .
We have
φ r = 3 m 1 m 2 r 2 2 m 3 r + 4 m 2 ,
φ r = 6 m 1 m 2 r 2 m 3 ,
if m 1 m 2 > 0 , that is m 1 > m 2 . Then we observe that φ r > 0 . Therefore, φ r is an increasing function in the closed interval [ 0,2 ] . Consequently, the function φ r gets the maximum value when r = 2 , meaning when
a 2 a 3 a 4 φ 2 = 8 1 β 13 1 β 2 405 + 1 60 ,
if m 1 m 2 < 0 , let φ r = 0 . Then we receive
r = n = m 3 ± m 3 2 12 m 2 m 1 m 2 3 ( m 1 m 2 ) ,
when n < r 2 . Subsequently, we obtain φ r > 0 , which indicates that the function on the closed interval is [ 0,2 ] . Therefore, the function φ r gets the maximum value at r = 2 , which means the function φ r is an decreasing function on the closed interval [ 0,2 ] . Therefore, φ r obtains the maximum value at r = 0 . We receive
a 2 a 3 a 4 φ 0 = 2 15 1 β .
The proof is complete. □
Theorem 3.
Let f S β ,   0 β < 1 . Then we have
a 3 a 2 2 1 4 1 β ,  
a 3 4 9 1 β 2 + 1 4 1 β .
Proof. 
By using (24) and Lemma 1, we obtain (31).
What follows the Fekete-Szegö functional is defined for μ C and f S ( β ) ,
a 3 μ a 2 2 = 1 β 2 r 1 2 9 1 μ + 1 β r 2 s 2 16 .
By Lemma 1, we receive
a 3 μ a 2 2 4 9 1 β 2 1 μ + 1 4 1 β ,  
for μ = 1 , we obtain (30). □
Theorem 4.
Let f ( ) S ( β ) ,   0 β < 1 . Then, we have
a 4 1 β 16 405 1 β 2 + 5 12 1 β + 2 5 ,                                                
a 5 1 β 2 98 12960 1 β 2 + 545 432 1 β + 36173 122880 + 1 6 1 β .
Proof. 
From (25) and by Lemma 1, we receive (32).
By subtracting (17) from (21), we have
48 a 5 = 144 a 2 a 4 + 20 a 3 a 2 2 + 72 a 3 + 2 316 a 2 4 504 a 2 a 3
+ 1 β r 4 s 4 .
By substituting properly (22), (24) and (25), we have
32 a 5 = 712 135 1 β 4 r 1 4 56 3 r 1 3 21 2 1 β 2 r 1 r 2 s 2 + 131 36 1 β 3 r 1 2 r 2 s 2 + 8 5 1 β 2 r 1 r 3 s 3 + 9 32 1 β 2 r 2 s 2 2 + 1 β r 4 s 4 .
By applying Lemma 1, we obtain (33). □
Theorem 5.
Let   f S β ,   0 β < 1 . Then we have
3 1 M M 1 M 2 8 1 β 13 1 β 2 405 + 1 60 + M 3 M 4 ,     n r 2 M M 1 2 15 1 β M 2 + M 3 M 4 ,                                                                                             0 r n ,                      
where M , M 1 , M 2 , M 3 , M 4 and n are given by (31), (7), (32), (33), and (30), respectively.
Proof. 
Since
3 1 = a 3 a 2 a 4 a 3 2 a 4 a 4 a 2 a 3 + a 5 a 3 a 2 2 ,
By utilizing the triangle inequality, we receive the result (3).
Substituting a 3 4 9 1 β 2 + 1 4 1 β ,
a 2 a 4 a 3 2 1 β 2 208 1215 1 β 2 + 8 90 ,
a 4 1 β 16 405 1 β 2 + 5 12 1 β + 2 5 ,
a 3 a 2 2 1 4 1 β
and
a 3 a 2 2 1 4 1 β
in
3 1 a 3 a 2 a 4 a 3 2 a 4 a 4 a 2 a 3 + a 5 a 3 a 2 2 ,
we obtain (34).
The proof is complete. □

3. Conclusions

This article presented a comprehensive investigation of the third Hankel determinant H3(1) for a certain subclass of bi-univalent functions, S ( β ) . This subclass is of significant interest in various mathematical fields, including complex analysis and geometric function theory. We defined the bi-univalent functions S ( β ) and imposed constraints on the coefficients a n . Our findings provided the upper bounds for the bi-univalent functions in this newly developed subclass, specifically for n = 2, 3, 4, and 5. Furthermore, we advanced the understanding of these functions by deriving the third Hankel determinant for this particular class, which revealed several intriguing scenarios. This achievement led to the improvement of the bound of the third Hankel determinant for the class of bi-univalent functions S ( β ) . Our study contributes to the broader understanding of bi-univalent functions, their subclasses, and their potential applications in diverse mathematical contexts. The results obtained may serve as a foundation for future investigations into the properties and applications of bi-univalent functions and their subclasses. Future research endeavors could explore further refinements of the bounds, as well as examine other subclasses of bi-univalent functions to uncover novel insights into their characteristics and potential applications. Ultimately, this study paves the way for a deeper exploration of the fascinating world of bi-univalent functions and their role in the realm of mathematics.

Author Contributions

Conceptualization Q.A.S., methodology W.G.A., validation W.G.A., formal analysis W.G.A., investigation Q.A.S. and W.G.A., resources W.G.A. and Q.A.S., writing—original draft preparation Q.A.S., writing—review and editing W.G.A., visualization Q.A.S., project administration W.G.A., funding acquisition W.G.A. All authors have read and agreed to the published version of the manuscript.

Funding

This research received no external funding.

Data Availability Statement

Data are contained within the article.

Conflicts of Interest

The authors declare no conflict of interest.

References

  1. Duren, P.L. Univalent Functions. In Grundlehren der Mathematischen Wissenschaften, Band 259; Springer: New York, NY, USA; Berlin/Hidelberg, Germany; Tokyo, Japan, 1983. [Google Scholar]
  2. Lewin, M. On a coefficient problem for bi-univalent functions. Proc. Am. Math. Soc. 1967, 18, 63–68. [Google Scholar] [CrossRef]
  3. Brannan, D.A.; Clunie, J.G. Aspects of Contemporary Complex Analysis. In Proceedings of the NATO Advanced Study Institute Held at the University of Durham, Durham, UK, 1–20 July 1979; Academic Press: New York, NY, USA; London, UK, 1980. [Google Scholar]
  4. Netanyahu, E. The minimal distance of the image boundary from the origin and the second coefficient of an univalent functions in: |z|<1. Arch. Ration. Mech. Anal. 1969, 32, 100–112. [Google Scholar]
  5. Kedzierawski, A.W. Some remarks on bi-univalent functions. Ann. Univ. Mariae Curie Sklodowska Sect. A 1985, 39, 77–81. [Google Scholar]
  6. Brannan, D.A.; Taha, T.S. On some classes of bi-univalent functions. Stud. Univ. Babes Bolyai Math. 1986, 31, 70–77. [Google Scholar]
  7. Altinkaya, S.; Yalcin, S. Initial coefficient bounds for a general class of bi-univalent functions. Int. J. Anal. 2014, 2014, 867871. [Google Scholar]
  8. Atshan, W.G.; Badawi, E.I. Results on coefficients estimates for subclasses of analytic and bi-univalent functions. J. Phys. Conf. Ser. 2019, 1294, 032025. [Google Scholar] [CrossRef]
  9. Atshan, W.G.; Rahman, I.A.R.; Lupas, A.A. Some results of new subclasses for bi-univalent functions using quasi-subordination. Symmetry 2021, 13, 1653. [Google Scholar] [CrossRef]
  10. Cantor, D.G. Power series with integral coefficients. Bull. Am. Math. Soc. 1963, 69, 362–366. [Google Scholar] [CrossRef]
  11. Frasin, B.A.; Al-Hawary, T. Initial Maclaurin coefficients bounds for new subclasses of bi-univalent functions. Theory Appl. Math. Comput. Sci. 2015, 5, 186–193. [Google Scholar]
  12. Patil, A.B.; Naik, U.H. Estimates on initial coefficients of certain subclasses of bi-univalent functions associated with quasi- subordination. Glob. J. Math. Anal. 2017, 5, 6–10. [Google Scholar] [CrossRef]
  13. Srivastava, H.M.; Mishra, A.K.; Gochhayat, P. Certain subclasses analytic and bi-univalent functions. Appl. Math. Lett. 2010, 23, 1188–1192. [Google Scholar] [CrossRef]
  14. Yalcin, S.; Atshan, W.G.; Hassan, H.Z. Coefficients assessment for certain subclasses of bi-univalent functions related with quasi-subordination. Publ. L’Institut Math. Nouv. Sér. 2020, 108, 155–162. [Google Scholar] [CrossRef]
  15. Noonan, W.; Thomas, D.K. On the second Hankel determinant of a really mean p-valent functions. Trans. Am. Math. Soc. 1976, 223, 337–346. [Google Scholar]
  16. Babalola, K.O. On H3(1) Hankel determinant for some classes of univalent functions. Inequal. Theory Appl. 2010, 6, 1–7. [Google Scholar]
  17. Deniz, E.; Cağlar, M.; Orhan, H. Second Hankel determinant for bi-starlike and bi-convex functions of order α. Appl. Math. Comput. 2015, 271, 301–307. [Google Scholar] [CrossRef]
  18. Orhan, H.; Çaglar, M.; Cotirla, L.-I. Third Hankel Determinant for a Subfamily of Holomorphic Functions Related with Lemniscate of Bernoulli. Mathematics 2023, 11, 1147. [Google Scholar] [CrossRef]
  19. Buyankara, M.; Çaglar, M. Hankel and Toeplitz determinants for a subclass of analytic functions. Mat. Stud. 2023, 60, 132–137. [Google Scholar] [CrossRef]
  20. Al-Ameedee, S.A.; Atshan, W.G.; Al-Maamori, F.A. Second Hankel determinant for certain subclasses of bi-univalent functions. J. Phys. Conf. Ser. 2020, 1664, 012044. [Google Scholar] [CrossRef]
  21. Atshan, W.G.; Al-Sajjad, R.A.; Altinkaya, S. On the Hankel determinant of m-fold symmetric bi-univalent functions using a new operator. Gazi Univ. J. Sci. 2023, 36, 349–360. [Google Scholar]
  22. Fekete, M.; Szegö, G. Eine Bemerkung über ungerade Schlichte Funktionen. J. Lond. Math. Soc. 1933, 1, 85–89. [Google Scholar] [CrossRef]
  23. Guney, H.O.; Murugusundaramoorthy, G.; Vijaya, K. Coefficient bounds for subclasses of bi-univalent functions associated with the Chebyshev polynomials. J. Complex Anal. 2017, 2017, 4150210. [Google Scholar]
  24. Darweesh, A.M.; Atshan, W.G.; Battor, A.H.; Mahdi, M.S. On the third Hankel determinant of certain subclass of bi-univalent functions. Math. Model. Eng. Probl. 2023, 10, 1087–1095. [Google Scholar] [CrossRef]
  25. Rahman, I.A.R.; Atshan, W.G.; Oros, G.I. New concept on fourth Hankel determinant of a certain subclass of analytic functions. Afr. Mat. 2022, 33, 7. [Google Scholar] [CrossRef]
  26. Khan, A.; Haq, M.; Cotîrlă, L.I.; Oros, G.I. Bernardi Integral Operator and Its Application to the Fourth Hankel Determinant. J. Funct. Spaces 2022, 2022, 4227493. [Google Scholar] [CrossRef]
  27. Grenander, U.; Szegö, G. Toeplitz Forms and Their Applications, California Monographs in Mathematical Sciences; University California Press: Berkeley, CA, USA, 1958. [Google Scholar]
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Shakir, Q.A.; Atshan, W.G. On Third Hankel Determinant for Certain Subclass of Bi-Univalent Functions. Symmetry 2024, 16, 239. https://doi.org/10.3390/sym16020239

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Shakir QA, Atshan WG. On Third Hankel Determinant for Certain Subclass of Bi-Univalent Functions. Symmetry. 2024; 16(2):239. https://doi.org/10.3390/sym16020239

Chicago/Turabian Style

Shakir, Qasim Ali, and Waggas Galib Atshan. 2024. "On Third Hankel Determinant for Certain Subclass of Bi-Univalent Functions" Symmetry 16, no. 2: 239. https://doi.org/10.3390/sym16020239

APA Style

Shakir, Q. A., & Atshan, W. G. (2024). On Third Hankel Determinant for Certain Subclass of Bi-Univalent Functions. Symmetry, 16(2), 239. https://doi.org/10.3390/sym16020239

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