High-resolution three-dimensional imaging of topological textures in nanoscale single-diamond networks.
D KarpovK DjeghdiMirko HollerS Narjes AbdollahiKarolina KorzebClaire DonnellyT YuasaHiroaki SaiUlrich B WiesnerBodo D WiltsUllrich SteinerM MusyaShunsuke FukamiHideo OhnoIlja GunkelAna DiazJustin LlandroPublished in: Nature nanotechnology (2024)
Topological defects-extended lattice deformations that are robust against local defects and annealing-have been exploited to engineer novel properties in both hard and soft materials. Yet, their formation kinetics and nanoscale three-dimensional structure are poorly understood, impeding their benefits for nanofabrication. We describe the fabrication of a pair of topological defects in the volume of a single-diamond network (space group Fd 3 ¯ m) templated into gold from a triblock terpolymer crystal. Using X-ray nanotomography, we resolve the three-dimensional structure of nearly 70,000 individual single-diamond unit cells with a spatial resolution of 11.2 nm, allowing analysis of the long-range order of the network. The defects observed morphologically resemble the comet and trefoil patterns of equal and opposite half-integer topological charges observed in liquid crystals. Yet our analysis of strain in the network suggests typical hard matter behaviour. Our analysis approach does not require a priori knowledge of the expected positions of the nodes in three-dimensional nanostructured systems, allowing the identification of distorted morphologies and defects in large samples.