Growth of Groups with Finite Sets of Incompressible Elements

The results presented in this paper have several potential applications and implications that extend beyond the specific examples discussed. Firstly, the classification of groups of bounded type and their growth properties can contribute to the broader understanding of group theory, particularly in the study of groups with intermediate growth. This classification can be instrumental in identifying new examples of groups that exhibit similar growth behaviors, thereby enriching the landscape of known groups. Moreover, the methods developed for analyzing the growth functions of these groups, particularly through the lens of tile inflations and automata, can be applied to other mathematical structures, such as dynamical systems and topological groups. The framework of using orbital graphs and traverses can also be adapted to study the growth of other algebraic structures, such as semigroups and rings, where similar notions of incompressibility and growth can be defined. Additionally, the insights gained from the study of incompressible elements may have implications in computational group theory, where understanding the complexity of group elements and their representations can lead to more efficient algorithms for group computations. The results could also inform the study of symbolic dynamics, particularly in the context of shifts and subshifts, where the concepts of boundary points and traverses can be utilized to analyze the structure of symbolic systems.

The paper operates under several assumptions that could be relaxed or generalized in future research. One significant assumption is the requirement for groups to act minimally on the space of infinite paths of Bratteli diagrams. Future work could explore the implications of non-minimal actions and how they affect the growth properties of groups. Another assumption is the focus on stationary finite-state automata. Researchers could investigate the behavior of groups defined by non-stationary or infinite-state automata, potentially leading to a richer class of groups with varied growth behaviors. Furthermore, the notion of incompressible elements is central to the results, but it may be beneficial to explore alternative definitions or relaxations of this concept. For instance, examining groups with a larger set of incompressible elements or those that exhibit incompressibility in a weaker sense could yield new insights into their growth dynamics. Lastly, the paper primarily addresses groups of bounded type derived from tile inflations. Future studies could extend these results to other classes of groups, such as those arising from different combinatorial or geometric constructions, thereby broadening the applicability of the findings.

The notions of "incompressible" elements and "traverses" are closely related to the concept of strong contraction, particularly in the context of groups like the Grigorchuk group, which is known for its intermediate growth properties. Incompressible elements refer to group elements that cannot be represented as a product of shorter elements, indicating a form of complexity or richness in the group's structure. This concept is crucial for establishing bounds on the growth functions of groups, as it implies that there are only finitely many ways to express certain elements, leading to subexponential growth. Traverses, on the other hand, are trajectories of group elements that connect boundary points of tiles in the context of tile inflations. The relationship between traverses and incompressible elements lies in the way traverses can be used to analyze the structure of the group and its growth. If the set of incompressible elements is finite, it suggests that traverses can be mapped injectively between different levels of the Bratteli diagram, which in turn indicates a form of strong contraction. Strong contraction, as applied to the Grigorchuk group, involves showing that the growth function is bounded by an exponential function with a sublinear exponent. The presence of finitely many incompressible elements ensures that the group does not exhibit too much complexity, allowing for the application of strong contraction techniques. Thus, both incompressible elements and traverses serve as tools to establish the growth behavior of groups, linking the abstract properties of group elements to concrete growth functions.