Open-source parallel implementations of RCCSDT, RCCSDT(Q), RCCSDTQ and UCCSDT in PySCF achieve near-ideal scaling to ~3000 cores and extend canonical high-order CC to systems with ~100 electrons in 450 orbitals.
Intermolecular Interactions of Large Systems: Boron Nitrides, Acenes, and Coronenes
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abstract
In a recent contribution [Fishman, V.; Lesiuk, M.; Martin, J.M.L.; Boese, A.D., J. Chem. Theory Comput. 2025, 21, 2311-2324], we introduced another angle at benchmarking non-covalent interactions by not just benchmarking interaction energies of different species, but by considering the evolution of interaction energies with increasing system size. Here, we extend the benchmark set to more species, such as electrostatically bound borazine dimers as well as the minima structures of parallel displaced acene and coronene dimers. While the minimum structures of the parallel displaced acene dimers yield similar results to previously published sandwich-structured acenes, the borazine dimers behave vastly different, yielding yet a more complete picture on non-covalent interactions and their scalability. In contrast, the polycyclic aromatic hydrocarbon structures -- coronenes sandwich-stacked and coronenes parallel displaced -- give results consistent with those obtained for both types of the polyacene series, resulting in an updated estimate for the coronene dimer energy.
fields
physics.chem-ph 1years
2026 1verdicts
CONDITIONAL 1representative citing papers
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High-performance parallel implementation of high-order coupled-cluster theories
Open-source parallel implementations of RCCSDT, RCCSDT(Q), RCCSDTQ and UCCSDT in PySCF achieve near-ideal scaling to ~3000 cores and extend canonical high-order CC to systems with ~100 electrons in 450 orbitals.