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Characterization of Banach Lattices Whose Biduals Have the Positive Schur Property via Second Adjoints of Operators


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The core message of this article is to characterize Banach lattices whose biduals have the positive Schur property by means of second adjoints of operators on the Banach lattice being almost Dunford-Pettis. The authors also extend known results on conditions for the adjoint and second adjoint of positive almost Dunford-Pettis operators to be almost Dunford-Pettis.
Resumen

The paper addresses the duality problem for almost Dunford-Pettis operators, which has been investigated before. The main focus is to establish conditions on a linear operator T between Banach lattices E and F, and/or on E and/or F, so that the adjoint T* and/or the second adjoint T** are almost Dunford-Pettis.

The key highlights and insights are:

  1. The authors characterize Banach lattices E whose biduals E** have the positive Schur property by means of T** being almost Dunford-Pettis for every operator T: E → ℓ∞.

  2. They extend known results on conditions for the adjoint T* of a positive almost Dunford-Pettis operator T: E → F to be almost Dunford-Pettis. The results show when T* enjoys a property stronger than being almost Dunford-Pettis, and when T** is almost Dunford-Pettis.

  3. The authors investigate when T* or T** is almost Dunford-Pettis even if T is not. They provide conditions for T* to be almost Dunford-Pettis when T is order bounded or regular, and for T** to be almost Dunford-Pettis when T is bounded order weakly compact or weakly compact.

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What are some potential applications of the characterization of Banach lattices whose biduals have the positive Schur property?

The characterization of Banach lattices whose biduals possess the positive Schur property has several significant applications in functional analysis and related fields. Firstly, it provides a framework for understanding the behavior of operators between Banach lattices, particularly in the context of almost Dunford-Pettis operators. This understanding can be crucial in the study of weak convergence and compactness properties in various mathematical settings, such as in the theory of integration and measure. Moreover, this characterization can be applied to the study of duality in optimization problems, where the properties of the underlying Banach lattices can influence the existence and uniqueness of solutions. In particular, the positive Schur property can be leveraged to ensure that certain sequences converge in norm, which is essential in variational methods and fixed-point theorems. Additionally, the results can be utilized in the analysis of nonlinear operators and their adjoints, providing insights into the stability and continuity of solutions to nonlinear equations. This is particularly relevant in applications involving partial differential equations and functional differential equations, where the structure of the underlying space plays a critical role in the behavior of solutions.

How do the conditions for T* or T** to be almost Dunford-Pettis, even when T is not, compare to other known results in the literature?

The conditions under which the adjoint ( T^* ) or the second adjoint ( T^{**} ) of an operator ( T ) can be shown to be almost Dunford-Pettis, even when ( T ) itself is not, represent a significant advancement in the understanding of operator theory within Banach lattices. These conditions extend previous results found in the literature, such as those established by Aqzzouz, Elbour, and Wickstead, which primarily focused on the implications of the properties of ( E^* ) and ( F^* ) on the behavior of ( T^* ). In particular, the results presented in the paper highlight that if ( E^* ) has an order continuous norm or if ( F ) has the dual positive Schur property, then ( T^* ) can be guaranteed to be almost Dunford-Pettis. This contrasts with earlier findings that required more stringent conditions on the spaces involved or the operators themselves. The new results also emphasize the role of regularity and order boundedness in ensuring that the adjoints maintain almost Dunford-Pettis properties, thus broadening the scope of operators that can be analyzed under this framework. Furthermore, the findings contribute to a deeper understanding of the interplay between the properties of Banach lattices and the behavior of their operators, which is a recurring theme in the literature. This can lead to new insights and potential applications in areas such as functional analysis, optimization, and the theory of distributions.

Are there any other classes of operators, beyond the ones considered, for which the adjoint or second adjoint can be shown to be almost Dunford-Pettis?

Yes, beyond the classes of operators already considered in the context of almost Dunford-Pettis properties, there are several other classes of operators where similar results can be established. For instance, one can explore the properties of compact operators, particularly in the context of Banach lattices. Compact operators often exhibit favorable convergence properties, and their adjoints can be shown to inherit almost Dunford-Pettis characteristics under certain conditions. Additionally, the class of weakly compact operators is another area where the adjoint or second adjoint can be analyzed for almost Dunford-Pettis properties. The results in the paper indicate that if the Banach lattice ( E ) has the dual positive Schur property, then the adjoint of every weakly compact operator is almost limited, which implies that it is almost Dunford-Pettis. Moreover, one could investigate the behavior of multilinear operators and their adjoints. Given the increasing interest in multilinear mappings in functional analysis, establishing almost Dunford-Pettis properties for the adjoints of multilinear operators could yield valuable insights, particularly in the study of tensor products and their applications in various mathematical disciplines. Lastly, exploring the properties of operators defined on more general structures, such as Fréchet spaces or locally solid Riesz spaces, could also reveal new classes of operators where the adjoint or second adjoint retains almost Dunford-Pettis characteristics. This line of inquiry could lead to a richer understanding of the relationships between different types of operators and their functional properties.
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