Assembly Theory Is Not Equivalent to Computational Complexity: A Formal and Empirical Comparison

Assembly Theory (AT) provides a framework for understanding complexity arising from selection acting on an assembly space. While initially developed for molecules, its core principles could be extended to non-physical systems like social networks or economic systems. Here's how: Defining the "Objects" and "Operations": Social Networks: Individuals could be "objects," and actions like forming connections, sharing content, or joining groups could be "operations" within the social network's assembly space. Economic Systems: Companies, goods, or services could be "objects," while operations might include production processes, transactions, or the establishment of trade relationships. Identifying Selection Pressures: Social Networks: Factors like popularity, information spread, or group cohesion could act as selection pressures, favoring certain network structures or dynamics. Economic Systems: Market forces, consumer preferences, or regulatory environments could drive selection, leading to the emergence of specific economic structures. Measuring Assembly Index (AI) and Copy Number: Social Networks: AI could quantify the minimum number of interactions needed to form a specific network structure, while copy number could track the prevalence of similar structures. Economic Systems: AI might measure the minimum number of steps in a supply chain or the complexity of a product, while copy number could reflect market share or the abundance of a particular service. Interpreting Assembly (A): High Assembly in these systems would suggest a strong influence of selection pressures, potentially revealing underlying organizational principles or evolutionary pathways. Challenges and Considerations: Abstracting Interactions: Defining meaningful "operations" and quantifying their complexity in non-physical systems can be challenging and context-dependent. Dynamic Nature: Social and economic systems are highly dynamic, requiring adaptations to the AT framework to account for changing selection pressures and object definitions. Causality vs. Correlation: AT emphasizes causation through selection. Distinguishing causal relationships from mere correlations in complex systems is crucial for accurate interpretation. Despite these challenges, applying AT to non-physical systems offers a novel perspective on how complexity emerges from simple interactions under selective pressures. It could provide valuable insights into the evolution and organization of these systems.

While Assembly Theory (AT) posits that selection is the primary driver behind the correlation between high assembly index and life, alternative explanations merit consideration: Unknown Abiotic Processes: It's conceivable that undiscovered abiotic processes, perhaps operating under extreme conditions or utilizing unique chemistries, could generate molecules with high assembly indices. Further exploration of prebiotic chemistry is crucial to assess this possibility. Statistical Fluctuations: While statistically improbable, chance occurrences within a sufficiently large and diverse chemical space could theoretically produce some high AI molecules. However, AT argues that the observed abundance and diversity of high AI molecules in living systems far exceed what random chance would allow. Constraints Beyond Selection: Factors beyond simple Darwinian selection, such as self-organization or thermodynamically favorable assembly pathways, might contribute to the emergence of complex molecules. These factors could act in concert with selection or independently to shape molecular complexity. Limitations of Current Detection Methods: Our current techniques for detecting and characterizing complex molecules might be biased towards certain structures, potentially leading to an overestimation of the assembly index in some cases. Improved analytical methods are needed to refine our understanding of molecular complexity. Distinguishing AT from Alternatives: Copy Number: AT emphasizes the importance of both high AI and high copy number as indicators of life. Alternative explanations would need to account for the abundance of identical, high AI molecules observed in living systems. Experimental Validation: AT's predictions are testable in laboratory settings. Experiments exploring the abiotic synthesis of complex molecules under various conditions can help assess the plausibility of alternative explanations. While alternative explanations cannot be definitively ruled out, AT's focus on selection as a driving force provides a parsimonious and testable framework for understanding the observed correlation between assembly index and life. Further research is needed to explore the potential contributions of other factors and refine our understanding of the origins of complexity.

Considering the universe as an assembly process, with its vast complexity arising from simpler constituents and operations, has profound implications for our understanding of reality and the search for a unified theory: Emergence of Complexity: It suggests that the complexity we observe at all scales, from subatomic particles to galaxies, could be an emergent property of a relatively small set of fundamental building blocks and interaction rules. This aligns with the reductionist pursuit of a "theory of everything" that elegantly explains the universe's diversity from a few fundamental principles. Information as Fundamental: The concept of an "assembly process" implies an underlying code or blueprint guiding the organization of matter and energy. This elevates the importance of information as a fundamental aspect of reality, potentially even preceding the existence of matter and energy in some models. Selection at the Cosmic Scale: If the universe is an assembly process, it begs the question of whether some form of selection, analogous to natural selection in biology, has shaped its evolution. This could manifest as physical laws and constants "fine-tuned" for the emergence of complexity, or perhaps as a multiverse scenario where our universe is just one outcome of a vast cosmic assembly space. Redefining "Life": Viewing the universe through the lens of AT challenges our definition of "life." If complexity arises from assembly processes, then life as we know it might be just one instance of a broader phenomenon occurring at different scales and with different building blocks. New Avenues for Unification: AT could provide a framework for connecting seemingly disparate fields like physics, cosmology, and biology. By understanding the principles of assembly and selection operating at different levels, we might uncover deeper connections and unifying principles governing the universe's structure and evolution. Challenges and Open Questions: Identifying the "Assembly Space": What are the fundamental building blocks and operations within the universe's assembly space? How do they give rise to the particles, forces, and laws we observe? The Role of Selection: Is there a cosmic equivalent of selection shaping the universe's evolution? If so, what are the selection pressures and how do they operate? The Origin of Information: Where did the information guiding the universe's assembly originate? Was it present from the beginning, or did it emerge through some other process? While speculative, considering the universe as an assembly process offers a compelling and potentially fruitful perspective on the nature of reality. It encourages us to seek unifying principles across disciplines and explore the profound implications of information, complexity, and selection at the grandest scales.