Title:The Chemputer and Chemputation: A Universal Chemical Compound Synthesis Machine

Abstract:This work establishes a rigorous proof for the universality of the chemputer as a chemical synthesis machine, capable of constructing any stable and isolable molecule through a finite, expressible process. This process is governed by three key parameters: reagents, process conditions, and catalysts. Additionally, the study introduces dynamic error correction mechanisms integrated into each step of the synthesis pathway, ensuring real-time accuracy and reliability. The role of universally configurable hardware is also highlighted, with the introduction of a 'chempiling' function that translates synthesis pathways into executable hardware configurations. These advancements collectively demonstrate the chemputer's capability to perform any feasible chemical synthesis, thereby establishing it as a universal tool in chemical manufacturing and synthesis. I show that every finitely realizable chemical synthesis process that can exist within the bounds of physical laws can be perfectly instantiated and executed by a universal chemputer, provided that the process can be completed within the finite number of reagent input vessels, reaction vessels, and product output vessels available, and that the error correction mechanisms are sufficiently robust to maintain the accuracy of the synthesis within these constraints. Finally, I show that chemical reactions are not implicit functions, but are an emergent property coming from the combination of the reagents, process conditions, and catalysts.