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Controlling energy delivery with bistable nanostructures

1 Pith paper cite this work. Polarity classification is still indexing.

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abstract

Countless biological processes are fueled by energy-rich molecules like ATP and GTP that supply energy with extreme efficiency. However, designing similar energy-delivery schemes from the bottom up, essential for the development of powered nanostructures and other \emph{de novo} machinery, presents a significant challenge: how can an energy-rich structure be stable in solution yet still deliver this energy at precisely the right time? In this paper, we present a purely physical mechanism that solves this challenge, facilitating energy transfer akin to ATP hydrolysis, yet occurring between synthetic nanostructures without any biochemical interactions. This targeted energy delivery is achieved by exploiting a differentiable state-based model to balance the energy profiles that govern the structural transitions in the two nanostructures, creating a coupled relaxation pathway with minimal barriers that facilitates energy delivery. We verify the effectiveness and robustness of this mechanism through Langevin Dynamics simulations, demonstrating that a bath of the high-energy structures can systematically and repeatedly drive the target structure out of equilibrium, enabling it to perform tasks. As the mechanism operates only through explicit physical forces without any biochemistry or internal state variables, our results present generic and far-reaching design principles, setting the stage for the next generation of synthetic nanomachines.

years

2026 1

verdicts

UNVERDICTED 1

representative citing papers

Designing bistable nanostructures for target behavior

cond-mat.soft · 2026-06-30 · unverdicted · novelty 6.0

Introduces an inverse-design framework showing that energy barriers and binding-site separations in bistable nanostructures are readily programmable while transition-state location and full profile shape require more design freedom.

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  • Designing bistable nanostructures for target behavior cond-mat.soft · 2026-06-30 · unverdicted · none · ref 14 · internal anchor

    Introduces an inverse-design framework showing that energy barriers and binding-site separations in bistable nanostructures are readily programmable while transition-state location and full profile shape require more design freedom.