Litcius/Paper detail

Nonequilibrium design strategies for functional colloidal assemblies

Avishek Das, David T. Limmer

2023Proceedings of the National Academy of Sciences14 citationsDOIOpen Access PDF

Abstract

We use a nonequilibrium variational principle to optimize the steady-state, shear-induced interconversion of self-assembled nanoclusters of DNA-coated colloids. Employing this principle within a stochastic optimization algorithm allows us to identify design strategies for functional materials. We find that far-from-equilibrium shear flow can significantly enhance the flux between specific colloidal states by decoupling trade-offs between stability and reactivity required by systems in equilibrium. For isolated nanoclusters, we find nonequilibrium strategies for amplifying transition rates by coupling a given reaction coordinate to the background shear flow. We also find that shear flow can be made to selectively break detailed balance and maximize probability currents by coupling orientational degrees of freedom to conformational transitions. For a microphase consisting of many nanoclusters, we study the flux of colloids hopping between clusters. We find that a shear flow can amplify the flux without a proportional compromise on the microphase structure. This approach provides a general means of uncovering design principles for nanoscale, autonomous, functional materials driven far from equilibrium.

Topics & Concepts

Non-equilibrium thermodynamicsNanoclustersDecoupling (probability)Statistical physicsShear flowColloidShear (geology)Materials scienceChemical physicsMechanicsNanotechnologyPhysicsThermodynamicsChemistryComposite materialPhysical chemistryControl engineeringEngineeringNanopore and Nanochannel Transport StudiesMaterial Dynamics and PropertiesElectrostatics and Colloid Interactions