Author
Listed:
- Agam Shayit
(University of Washington, Department of Physics)
- Can Liao
(University of Washington, Department of Chemistry)
- Shiv Upadhyay
(University of Washington, Department of Chemistry)
- Hang Hu
(University of Washington, Molecular Engineering and Sciences Institute)
- Tianyuan Zhang
(University of Washington, Department of Chemistry)
- A. Eugene DePrince III
(Florida State University, Department of Chemistry and Biochemistry)
- Chao Yang
(Lawrence Berkeley National Laboratory, Applied Mathematics and Computational Research Division)
- Xiaosong Li
(University of Washington, Department of Chemistry)
Abstract
The combinatorial growth of configuration interaction (CI) has long limited this formally exact quantum chemistry method to only the smallest molecules. Here, we report a numerically exact CI calculation exceeding one quadrillion (1015) determinants, made possible by a lossless categorical compression strategy within the small-tensor-product distributed active space (STP-DAS) framework. This approach overcomes the traditional memory bottlenecks of CI by a numerically exact compression of the wavefunction representation and reformulating the most computationally demanding matrix–vector operations. Using this method, we performed a fully relativistic CI calculation of the ground state of HBrTe with over 1015 complex-valued determinants in just 34.5 h on 1000 computing nodes—the largest CI calculation ever reported. We further achieved fast computation for systems with hundreds of billions of determinants on only a few compute nodes. Extensive benchmarks confirm that the method retains full numerical exactness while cutting memory and computational cost by orders of magnitude. Compared to previous state-of-the-art CI calculations, this work achieves a 1000 times increase in CI space, a 106-fold increase in floating-point operations performed, and a 106-fold improvement in computational speed.
Suggested Citation
Agam Shayit & Can Liao & Shiv Upadhyay & Hang Hu & Tianyuan Zhang & A. Eugene DePrince III & Chao Yang & Xiaosong Li, 2025.
"Numerically exact configuration interaction at quadrillion-determinant scale,"
Nature Communications, Nature, vol. 16(1), pages 1-12, December.
Handle:
RePEc:nat:natcom:v:16:y:2025:i:1:d:10.1038_s41467-025-65967-7
DOI: 10.1038/s41467-025-65967-7
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