Call for Blog Posts: Submission deadline: Dec. 1st, 2025 23:59 AOE All information is now available: iclr-blogposts.github.io/2026/about/ Please RT!
Organizers:
@schwinnl.bsky.social @busycalibrating.bsky.social @jonkhler.argmin.xyz @n-gao.bsky.social @mhrnz.bsky.social & myself
Blog Posts are a great medium to share ML research. If you have new intuitions on past work, noticed key implementation details for reproducibility, have insights into the societal implications of AI, or an interesting negative result consider writing and submitting a blogpost.
📣 Call for Blog Posts at #ICLR2026 @iclr_conf
Following the success of the past iterations, we are opening the Call for Blog Posts 2026!
iclr-blogposts.github.io/2026/about/#...
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I am very happy to share Orbformer, a foundation model for wavefunctions using deep QMC that offers a route to tackle strongly correlated quantum states!
arxiv.org/abs/2506.19960 (1/n)
Our results show that physical intuitions like the nearsightedness of electronic matter may be useful inductive biases for designing efficient yet accurate machine learning-based electronic structure methods.
Lastly, with the ability to analyze systems of these sizes, we can establish empirical convergence rates/scaling laws for growing system sizes. Consistent across two kinds of structures, we find a power law describing convergence.
Crucially, our method is not limited to biochemical compounds but also extends to computationally challenging organometallic compounds with up to 180 electrons where we - like the previous results - match or surpass the gold-standard CCSD(T)/CBS.
While, for a short cutoff of 5 Bohr radii, our approach matches the 'gold standard' CCSD(T)/CBS in non-covalent binding energies, an even shorter cutoff of 3 yields closer-to-experimental results in well-bonded biochemical compounds.
In the real world, this leads to speedups of up to 10x when scaling to a large number of electrons, as we do in this work. Thanks to VMC's embarrassingly parallel nature, this will enable the study of larger and more challenging systems as hardware progresses.
In this work, we set out to change this and improve the theoretical complexity of both operations by O(N).
We enable efficient wave function updates and efficient Laplacian computations by range-limiting electron-electron interactions within the neural network embedding.
Neural network VMC promises accuracy at scale but has been plagued with prohibitive costs mainly due to two reasons:
1) Densely connected neural wave functions cannot efficiently update if a few electrons' positions are changed.
2) Kinetic energy computations are expensive.
Accurate solutions to the electronic Schrödinger equation are a root problem in studying drugs and materials. As the number of electrons increases, the number of accurate methods grows thin.
I am truly excited to share our latest work with @mscherbela.bsky.social, Philipp Grohs, and @guennemann on "Accurate Ab-initio Neural-network Solutions to Large-Scale Electronic Structure Problems"!
arxiv.org/abs/2504.06087
Super happy & honored that our work on certifying NNs against poisoning won the Best Paper Award at AdvML-Frontiers@ #NeurIPS2024. Come by our poster 10:40am-12&4-5pm (or talk) today :)
Joint work w/ Mahalakshmi Sabanayagam, Debarghya Ghoshdastidar & Stephan Günnemann
L: arxiv.org/pdf/2407.10867
Excited to present our work on Neural Pfaffians at #NeurIPS.
🗣️ Oral: Friday 3:30pm, East Ballroom A, B
📊 Post: Friday 4:30pm - 7:30pm, East Exhibit Hall A-C #3600
📝 Paper: openreview.net/forum?id=HRk...
Happy to chat!
📣🔥Last chance to submit your work for the @iclr-conf.bsky.social 2025 Blogpost Track!
The deadline is November 22, 2024, at 23:59 AOE—don’t miss it!
For any inquiries, feel free to reach out to us at: iclr-blogpost-track@googlegroups.com.
iclr.cc/Conferences/...
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