This report summarises the work performed throughout the TSCALE project and outlines the main results achieved over the full duration of the fellowship (April 2022 – March 2025). Despite initial delays related to the Australian visa, which led to the fellowship starting at the University of Genova, the project made substantial progress and largely met its objectives across all work packages.
At its core, TSCALE focused on generating high-fidelity datasets for turbomachinery flows and applying advanced data-driven techniques for flow decomposition and modelling. Over 6 million CPU-hours and 300,000 GPU-hours were secured across HPC platforms in Europe, Australia, and the US, resulting in 52 datasets (18 highly resolved) totalling over 70TB. These included simulations under steady inflow, off-design (Fig. 2a, b), and multi-stage compressor (Fig. 3) conditions.
In parallel, the project successfully developed and implemented multiple post-processing tools. These included analytical double/triple decomposition methods, Fourier and Proper Orthogonal Decomposition (POD) techniques, and a statistical framework for scale separation based on the computation of triadic interactions. This enabled, for the first time, large-scale quantification of triadic energy exchanges in turbomachinery, that may form the basis for two innovative modelling strategies: a multi-scale transport model and a Galerkin-projected low-order model based on data-derived triadic dynamics.
Dissemination was broad and effective: 5 major publications (4 journal, 1 proceedings), 2 best paper nominations (ASME TurboExpo), over 25 presentations, including 11 invited talks, 2 industry collaborations, and multiple outreach activities. A dedicated project website (turbscale.com) supported further engagement.
The TSCALE datasets are being curated for broader reuse, with efforts underway in collaboration with Sorbonne University and the COMPOSE MSCA (Horizon EU, Grant n. 101205669) to establish a standardized, non-proprietary high-fidelity database for the fluid dynamics community.
Overall, TSCALE has advanced the state of the art in turbomachinery modelling, built lasting academic and industrial collaborations, and had a strong impact on the ER’s scientific career.