Robledo-Moreno Javier, Motta Mario, Haas Holger, Javadi-Abhari Ali, Jurcevic Petar, Kirby William, Martiel Simon, Sharma Kunal, Sharma Sandeep, Shirakawa Tomonori, Sitdikov Iskandar, Sun Rong-Yang, Sung Kevin J, Takita Maika, Tran Minh C, Yunoki Seiji, Mezzacapo Antonio
IBM Quantum, IBM T. J. Watson Research Center, Yorktown Heights, NY 10598, USA.
IBM Quantum, IBM Research Cambridge, Cambridge, MA 02142, USA.
Sci Adv. 2025 Jun 20;11(25):eadu9991. doi: 10.1126/sciadv.adu9991. Epub 2025 Jun 18.
A universal quantum computer can simulate diverse quantum systems, with electronic structure for chemistry offering challenging problems for practical use cases around the hundred-qubit mark. Although current quantum processors have reached this size, deep circuits and a large number of measurements lead to prohibitive runtimes for quantum computers in isolation. Here, we demonstrate the use of classical distributed computing to offload all but an intrinsically quantum component of a workflow for electronic structure simulations. Using a Heron superconducting processor and the supercomputer Fugaku, we simulate the ground-state dissociation of N and the ground state properties of [2Fe-2S] and [4Fe-4S] clusters, with circuits up to 77 qubits and 10,570 gates. The proposed algorithm processes quantum samples to produce upper bounds for the ground-state energy and sparse approximations to the ground-state wave functions. Our results suggest that, for current error rates, a quantum-centric supercomputing architecture can tackle challenging chemistry problems beyond sizes amenable to exact diagonalization.
通用量子计算机可以模拟各种量子系统,化学中的电子结构为大约百量子比特规模的实际应用案例带来了具有挑战性的问题。尽管当前的量子处理器已达到这一规模,但深度电路和大量测量导致孤立的量子计算机运行时间过长,令人望而却步。在此,我们展示了如何使用经典分布式计算来卸载电子结构模拟工作流程中除固有量子组件之外的所有部分。我们使用Heron超导处理器和超级计算机富岳,模拟了N的基态解离以及[2Fe-2S]和[4Fe-4S]簇的基态性质,所使用的电路包含多达77个量子比特和10570个门。所提出的算法处理量子样本以产生基态能量的上限以及基态波函数的稀疏近似。我们的结果表明,对于当前的错误率,以量子为中心的超级计算架构可以解决超出精确对角化适用规模的具有挑战性的化学问题。
