📝 SummarXiv

Abstract

Bottom-up fabrication of inorganic nanostructures is emerging as an alternative to classical top-down approaches, offering precise nanometer-scale control at relatively low cost and effort. In particular, DNA nanostructures provide versatile scaffolds for directly templating the growth of metal structures. Previously, a DNA mold-based method for metal nanostructure synthesis has been established that supports a modular structure design and a high control over the structure formation. So far, this method was limited to the growth of gold and palladium nanostructures. Here, we report the successful adaptation of the DNA mold-based fabrication method to produce continuous silver nanowires. By optimizing reagent concentrations and applying gentle thermal annealing, we obtain continuous wire structures of several hundred nanometer length, overcoming limitations in anisotropic growth. Despite the strong interaction of silver ions with DNA, we can control the growth without increasing the complexity of our approach. Our structures are not oxidized yet they did not exhibit conductivity. This work demonstrates the versatility of DNA-templated metallization and opens new opportunities for constructing self-assembled hybrid nanostructures with controlled shape and composition.