Statistical Behavior of Complex Systems: Advanced Theoretical Perspectives and Methodological Frameworks

This paper presents novel contributions to the study of complex systems by developing and applying hybrid methods that integrate data-driven approaches with analytical modeling frameworks. Complex systems, inherently characterized by high dimensionality, non-linearity, and emergent phenomena, challenge classical reductionist approaches. This paper highlights novel contributions including the development and application of hybrid methods that integrate data-driven tools with analytical modeling frameworks. By combining non-equilibrium statistical mechanics, information theory, network science and dynamical systems, we investigate the statistical behavior of diverse real-world complex systems. Emphasis is placed on universality classes, scaling theory, critical phenomena, entropy measures, and ergodicity-breaking mechanisms, with special attention to adaptive systems such as evolving networks and biological populations. Illustrative examples and recent empirical studies, especially in neuroscience and socioeconomic systems demonstrate how modern theoretical advances reveal macroscopic order emerging from microscopic complexity. This paper argues that a hybrid methodological framework, integrating data-driven tools with theoretical constructions from nonequilibrium statistical mechanics and network science, is essential for uncovering universal statistical behaviors in complex real-world systems. By focusing on phenomena such as ergodicity breaking, criticality, and adaptive dynamics, the work challenges classical reductionist approaches and provides a unified lens to study disparate systems such as neural populations and financial markets. The proposed framework reveals how macroscopic order emerges from microscopic interactions and offers a pathway to predictive modeling in high-dimensional, nonstationary environments. This section largely summarizes different methodological approaches without critical engagement. The paper should delve deeper into the strengths and weaknesses of each paradigm, discuss their practical implications, and potentially compare and contrast them. For instance, how do the ontological and epistemological assumptions of positivism and interpretivism influence data collection and analysis? What are the challenges and opportunities associated with mixed-methods research? Moving beyond traditional reductionist approaches, we integrate nonequilibrium statistical mechanics, information theory, network science, and dynamical systems theory to examine high-dimensional, nonlinear, and adaptive phenomena. The work critically evaluates the