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@INPROCEEDINGS{Wasmer:1053929,
author = {Wasmer, Johannes},
collaboration = {Rüssmann, Philipp and Sanvito, Stefano and Cangi, Attila
and Assent, Ira},
othercontributors = {Blügel, Stefan},
title = {{T}owards all-electron treatment in electronic structure
machine learning},
school = {RWTH Aachen},
reportid = {FZJ-2026-01614},
year = {2025},
abstract = {Electronic structure calculations with density functional
theory (DFT) are today the most widely used technique for
computational materials design. As materials design enters
the artificial intelligence (AI) age, large databases of
these calculations, such as the Materials Project, form the
basis for creating foundation models. This can be seen in
leaderboards such as Matbench Discovery [1]. These AI
foundation models mark a paradigm shift in computational
materials design since they accelerate the time to solution
by orders of magnitude. However, the current DFT databases
and AI surrogate models are not accurate enough to design
quantum materials. This problem can be solved by employing
all-electron, full-potential, fully relativistic DFT, that
can reach the required calculation precision. The JuDFT.de
codes are among the few established implementations of such
methods [2]. They are the only all-electron DFT codes
supporting high-throughput data generation that implement
the FAIR data guidelines via their plugin integration with
the AiiDA.net workflow engine.We present our progress on the
open problem of surrogate AI models for all-electron DFT
data for the JuDFT codes. We focus on the JuKKR code, and
materials systems with defects, such as magnetically doped
topological insulators [3]. We predict the converged
electron potential for accelerated DFT, and first-principles
exchange interactions for accelerated spin dynamics.[1]
Riebesell, J. et al. Matbench Discovery – A framework to
evaluate machine learning crystal stability predictions.
Preprint at https://doi.org/10.48550/arXiv.2308.14920
(2024).[2] Bosoni, E. et al. How to verify the precision of
density-functional-theory implementations via reproducible
and universal workflows. Nat Rev Phys 6, 45–58 (2024).[3]
Mozumder, R., Wasmer, J., Antognini Silva, D., Blügel, S.
$\&$ Rüßmann, P. High-throughput magnetic co-doping and
design of exchange interactions in topological insulators.
Phys. Rev. Mater. 8, 104201 (2024).},
month = {May},
date = {2025-05-27},
organization = {FZJ IAS Retreat 2025, Jülich
(Germany), 27 May 2025 - 27 May 2025},
subtyp = {After Call},
cin = {PGI-1},
cid = {I:(DE-Juel1)PGI-1-20110106},
pnm = {5211 - Topological Matter (POF4-521) / HDS LEE - Helmholtz
School for Data Science in Life, Earth and Energy (HDS LEE)
(HDS-LEE-20190612) / AIDAS - Joint Virtual Laboratory for
AI, Data Analytics and Scalable Simulation
$(aidas_20200731)$ / DFG project G:(GEPRIS)491111487 -
Open-Access-Publikationskosten / 2025 - 2027 /
Forschungszentrum Jülich (OAPKFZJ) (491111487)},
pid = {G:(DE-HGF)POF4-5211 / G:(DE-Juel1)HDS-LEE-20190612 /
$G:(DE-Juel-1)aidas_20200731$ / G:(GEPRIS)491111487},
typ = {PUB:(DE-HGF)24},
doi = {10.34734/FZJ-2026-01614},
url = {https://juser.fz-juelich.de/record/1053929},
}
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