The hidden architecture of equilibrium self-assembly

Experiments have reached a monumental capacity for designing and synthesizing microscopic particles for self-assembly, making it possible to precisely control particle concentrations, shapes, and interactions. However, we lack a comprehensive inverse-design framework for tuning these particle-level attributes to obtain desired system-level assembly outcomes, like the yield of a user-specified target structure. This severely limits our ability to take full advantage of this vast design space to assemble nanomaterials with complex structure and function. Here we show that a hidden mathematical architecture controls equilibrium assembly outcomes and provides a single comprehensive view of the entire design space. This architecture predicts which structures can be assembled at high yield and reveals constraints that govern the coexistence of structures, which we verify through detailed, quantitative assembly experiments of nanoscale particles synthesized using DNA origami. Strong experimental agreement confirms the importance of this underlying architecture and motivates its use as a predictive tool for the rational design of self-assembly. These results uncover a universal core logic underpinning all equilibrium self-assembly that forms the basis for a robust inverse-design framework, applicable to a wide array of systems from biological protein complexes to synthetic nanomachines.