Additive manufacturing (3D printing) technologies are progressively advancing toward the microscale, enabling the fabrication of so-called architectured (meta)materials — materials whose mechanical properties arise not from their chemical composition but from their carefully engineered internal geometric structure. Such materials can be lighter, stronger, and more multifunctional than conventional bulk materials, and hold considerable promise for applications in aerospace, biomedical, and sustainable engineering.
Realising this potential requires moving beyond trial-and-error design toward automated computational methods. Topology optimisation — a technique that automatically determines the optimal material arrangement within a given design domain — is well suited to this task. However, applying it at the microscale is computationally very demanding: a single cubic millimetre of material discretised at micrometre resolution yields billions of computational elements, which exceeds the capacity of even state-of-the-art solvers. Algorithms based on the fast Fourier transform (FFT) offer a practical way forward, as they are well suited to the regular grid structures that arise naturally in additive manufacturing — but further development was needed before they could be applied routinely at the resolutions modern manufacturing now enables.
The µFFTTO project, conducted at the University of Freiburg within the livMatS Cluster of Excellence, set out to address this gap by developing faster and more memory-efficient FFT-based algorithms for the topology optimisation of high-resolution microstructures.