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Reducing runtimes of ground state calculations on quantum computers by two orders of magnitude

ORAL

Abstract

Quantum chemistry simulations are among the most promising applications of fault-tolerant quantum computers. However, while recent algorithmic advancements, such as qubitization, and improved Hamiltonian representations, like tensor hyper-contraction, have significantly reduced resource requirements, achieving practical runtimes for industrially relevant systems remains challenging. We combine these advancements with a novel active volume (AV) compilation technique that optimizes resource utilization by removing the overhead for idling logical qubits but requires a specialized AV architecture. Paired with modifications to the tensor hyper-contraction method, AV compilation achieves substantial runtime reductions by two orders of magnitude.

This approach is applied to a challenging cytochrome P450 system, a key enzyme in drug metabolism, demonstrating the potential of this combined strategy to bring quantum computing closer to practical applications in pharmaceutical research and other industries.

Publication: Exploiting photonic quantum computing architecture and efficient Hamiltonian compression techniques to reduce ground state calculation time of industrial chemical/pharma systems, Steudtner M. et al manuscript in preparation

Presenters

  • Raffaele Santagati

    Quantum Lab Boehringer-Ingelheim Italia SpA, Boehringer Ingelheim Quantum Lab

Authors

  • Raffaele Santagati

    Quantum Lab Boehringer-Ingelheim Italia SpA, Boehringer Ingelheim Quantum Lab

  • Gianluca Anselmetti

    Boehringer-Ingelheim

  • Matthias Degroote

    Boehringer-Ingelheim

  • Nikolaj Moll

    Boehringer Ingelheim Pharmaceuticals, Inc., Boehringer Ingelheim Quantum Lab

  • Michael Streif

    Boehringer Ingelheim Quantum Lab

  • Mark Steudtner

    PsiQuantum, Corp.

  • William Pol

    PsiQuantum, Corp.

  • Cristian Cortes

    PsiQuantum, Corp.

  • Sukin Sim

    PsiQuantum, Corp