Battery research powered by LUMI

Using LUMI, Manuel Dillenz and Jose Maria Castillo Robles from DTU Energy combined quantum simulations and machine learning to investigate the atomic scale processes that shape battery performance.

Battery
A
Anne Rahbek-Damm
Journalist and Communications Consultant
07.07.2026 12:27

At the Technical University of Denmarks Department for energy conversion and storage (DTU Energy) postdocs Manuel Dillenz and Jose Maria Castillo Robles work to understand how batteries function at the most fundamental level, which is key to improving their performance. This involves tracking how electrons move through materials and how small structural changes affect that movement. Because these processes take place at the scale of individual atoms and unfold in fractions of a second, they are difficult to observe experimentally. Understanding them through simulations requires both highly accurate calculations and sufficient computing power to study realistic systems over the required nanosecond timescales.

“These processes take place on ultrafast timescales and are tightly linked to distortions in the material structure. To capture them accurately, we need highly precise simulations but also the ability to scale up.”, Manuel Dillenz

Small-Scale Science, Large-Scale Computing

To understand what happens inside the material, Manuel and Jose Maria combined several computational approaches which each addressed a different part of the problem. 

First, highly accurate quantum mechanical calculations were carried out on LUMI's CPU partition to understand how charge moves through the material. These calculations provided the reference data needed for the next stages of the project. They then used molecular dynamics simulations to study how the material behaves over time and how its structure changes under different conditions. Together, these simulations generated the data needed to train a machine learning model. Once trained, the model was deployed on LUMI's GPU partition, where it could reproduce the accuracy of the quantum mechanical calculations at a fraction of the computational cost. 

Making the Workflow LUMI-Ready

Before moving to large-scale computing, Manuel and Jose Maria had developed and tested the workflow on the DTU HPC facility Niflheim. This had allowed them to refine the setup and ensure that each step in the process worked as intended. Moving the machine learning workflow from DTU's Niflheim cluster to LUMI was, however, not entirely straightforward. LUMI-G uses a different GPU architecture which means that software optimised for Niflheim’s NVIDIA GPUs could not simply be transferred and run on LUMI's AMD-based GPU infrastructure. To solve this issue, Manuel and Jose Maria reached out to the LUMI user support team through the DeiC Helpdesk. The team recommended a container-based approach, allowing the software and all its dependencies to be packaged into a portable environment. The setup was first tested in an existing software container and later packaged into a dedicated container for the large-scale simulations.

“Adapting our workflow to a new architecture was challenging, but the LUMI support team made the process straightforward. Communication ran through the DeiC Helpdesk over email, and the responses were prompt and knowledgeable. Their recommendation of a container-based setup was exactly the right approach and saved us considerable time”, Manuel Dillenz

Once the software had been adapted to the LUMI environment, access to LUMIs large-scale computing resources made it possible to carry out the most computationally intensive parts of the workflow from generating reference data to training and deploying the machine learning model in large-scale simulations:

A tool for future battery research

While Manuel and Jose Maria's work focused on a specific type of battery material (lithium manganese oxide), the project has produced tools that can be used beyond this single system. This means that researchers working on similar battery materials can reuse both the computational workflow and the trained machine learning models in their own work. The approach can also help explain experimental observations by revealing what is happening at the atomic level inside a material:

“The approach we have developed in this project is not limited to a single material. The workflows and trained machine learning models will be made openly available, which will allow other researchers to build on the work and apply it to related systems.”, Jose Maria Castillo Robles

Looking ahead, the researchers plan to extend the work to different material compositions and to investigate how imperfections in the material structure and small amounts of added elements influence charge transport. Continued access to large-scale computing resources will be important as the research moves towards increasingly complex battery systems.

“I would absolutely apply for LUMI resources again. The combination of CPU and GPU partitions fits this kind of workflow perfectly, and continued access will be essential as we move towards larger and more complex battery systems”. Manuel Dillenz, 

Without access to LUMI, it would not have been possible to build and apply this framework at the required level of accuracy and scale

Jose Maria Castillo Robles
Postdoc
Technical University of Denmark, Department for energy conversion and storage
About the project

Project name: Probing Ultrafast Dynamics in Battery Cathodes with Automated Workflows

Compute time was granted in the national call H2 2025.

GPU/CPU hours used: 3M CPU-hours / 40K GPU-hours

Period of use: 1st of July 2025 to the 30th of June 2026.

Tools and ressources

ToolPurpose
VASPQuantum mechanical calculations
MACEMachine learning interatomic potential
ASE (Atomic Simulation Environment)Structure setup and manipulation
PerQueueWorkflow automation
PythonAnalysis and workflow development
LUMI-CCPU-based calculations
LUMI-GMachine learning training and large-scale simulations
DTU DeiC Front Office

“DTU DeiC Frontoffice (FO) supports researchers at DTU by providing high-performance computing (HPC), data management, and quantum services. As part of the national initiative, FO manages access to HPC resources, assists with service applications and the grant process overseen by DeiC, and allocates national funds from DeiC to national and international facilities, including DeiC Interactive, DeiC Throughput and LUMI. These activities cover all aspects of HPC utilisation.

Researchers may apply for resources or support by contacting the FO directly or by using the dedicated portal provided by DeiC. The application process requires submission of a service request or grant proposal, which FO reviews and supports throughout each stage. Following evaluation and approval, FO allocates the appropriate resources and assists with user onboarding. For detailed application procedures and guidance, researchers should consult the DTU Deic Front Office deic-frontoffice@dtu.dk.

FO disseminates DeiC information to relevant recipients and organisational levels, maintains direct communication with researchers, and provides guidance and support in HPC, data management, and quantum computing. FO support includes technical troubleshooting, assistance with proposal writing, resource allocation navigation, user onboarding, and advice on best practices in data handling and computational workflows. Each university maintains its chosen level of researcher support in accordance with local and national policy requirements.

FO undertakes a range of activities to support the effective operation of LUMI projects, including user control, information technology (IT), finance, facilities management, customer service, and administrative support. These functions provide essential expertise and resources to ensure operational efficiency. Every FO-granted DTU project is visible within the LUMI DTU organisation, and the Resource Allocator assigns the Principal Investigator (PI) to each project.

For support or questions related to LUMI projects, researchers should contact the FO at DTU Deic Front Office deic-frontoffice@dtu.dk. The FO team provides assistance with inquiries regarding LUMI operations, procedures, or resources.”