Self-assembly Through Programmable Folding

TL;DR

This paper demonstrates how programmable DNA interactions can guide colloidal polymers to fold into specific two-dimensional structures, enabling the design of complex, bio-inspired materials with diverse geometries.

Contribution

Introduces a minimal model system for programmable folding of colloidal polymers, combining experiments, simulations, and theory to create and control foldamers.

Findings

Successfully designed 11 foldamers with simple sequences.

Encoded over half of the possible geometries using sequence design.

Foldamers can assemble into complex supracolloidal architectures.

Abstract

At the cutting edge of materials science, matter is designed to self-organize into structures that perform a wide range of functions. The past two decades have witnessed major innovations in the versatility of building blocks, ranging from DNA on the nanoscale to handshaking materials on the macroscale. Like a jigsaw puzzle, one can reliably self-assemble arbitrary structures if all the pieces are distinct, but systems with fewer flavors of building blocks have so far been limited to the assembly of exotic crystals. Inspired by Nature's strategy of folding biopolymers into specific RNA and protein structures, here we introduce a minimal model system of colloidal polymers with programmable DNA interactions that guide their downhill folding into two-dimensional geometries. Combining experiments, simulations, and theory, we show that designing the order in which interactions are switched on directs folding into unique geometries called foldamers. The simplest alternating sequences ($ABAB$...) of up to 13 droplets yield eleven foldamers, while designing the sequence and adding an extra flavor uniquely encodes more than half of the 619 possible geometries. These foldamers can further interact to make complex supracolloidal architectures, seeding a next generation of bio-inspired materials. Our results are independent of the dynamics and therefore apply to polymeric materials with hierarchical interactions on all length scales, from organic molecules all the way to Rubik's snakes.